Package evaluation to test LaMEM on Julia 1.10.10 (c8be17dcfd*) started at 2026-02-03T05:18:15.441 ################################################################################ # Set-up # Installing PkgEval dependencies (TestEnv)... Activating project at `~/.julia/environments/v1.10` Set-up completed after 5.11s ################################################################################ # Installation # Installing LaMEM... Resolving package versions... Updating `~/.julia/environments/v1.10/Project.toml` [2e889f3d] + LaMEM v0.4.12 Updating `~/.julia/environments/v1.10/Manifest.toml` [1520ce14] + AbstractTrees v0.4.5 [7d9f7c33] + Accessors v0.1.43 [79e6a3ab] + Adapt v4.4.0 [66dad0bd] + AliasTables v1.1.3 [13072b0f] + AxisAlgorithms v1.1.0 [39de3d68] + AxisArrays v0.4.8 [7b0aa2c9] + BibTeX v0.1.0 [fa961155] + CEnum v0.5.0 [179af706] + CFTime v0.2.5 [d360d2e6] + ChainRulesCore v1.26.0 [0b6fb165] + ChunkCodecCore v1.0.1 [4c0bbee4] + ChunkCodecLibZlib v1.0.0 [55437552] + ChunkCodecLibZstd v1.0.0 [944b1d66] + CodecZlib v0.7.8 [3da002f7] + ColorTypes v0.12.1 [c3611d14] + ColorVectorSpace v0.11.0 [5ae59095] + Colors v0.13.1 [1fbeeb36] + CommonDataModel v0.4.2 [38540f10] + CommonSolve v0.2.6 [bbf7d656] + CommonSubexpressions v0.3.1 [f70d9fcc] + CommonWorldInvalidations v1.0.0 [34da2185] + Compat v4.18.1 [a33af91c] + CompositionsBase v0.1.2 [187b0558] + ConstructionBase v1.6.0 [150eb455] + CoordinateTransformations v0.6.4 [9a962f9c] + DataAPI v1.16.0 [864edb3b] + DataStructures v0.19.3 [8bb1440f] + DelimitedFiles v1.9.1 [163ba53b] + DiffResults v1.1.0 [b552c78f] + DiffRules v1.15.1 [3c3547ce] + DiskArrays v0.4.19 [b4f34e82] + Distances v0.10.12 [ffbed154] + DocStringExtensions v0.9.5 [411431e0] + Extents v0.1.6 [c87230d0] + FFMPEG v0.4.5 [5789e2e9] + FileIO v1.18.0 [1a297f60] + FillArrays v1.16.0 [53c48c17] + FixedPointNumbers v0.8.5 [f6369f11] + ForwardDiff v1.3.2 [e018b62d] + GeoParams v0.7.9 [0ef565a4] + Geodesy v1.2.0 [5c1252a2] + GeometryBasics v0.5.10 [3700c31b] + GeophysicalModelGenerator v0.7.16 ⌅ [c27321d9] + Glob v1.3.1 [076d061b] + HashArrayMappedTries v0.2.0 [34004b35] + HypergeometricFunctions v0.3.28 [615f187c] + IfElse v0.1.1 [2803e5a7] + ImageAxes v0.6.12 [c817782e] + ImageBase v0.1.7 [a09fc81d] + ImageCore v0.10.5 [82e4d734] + ImageIO v0.6.9 [bc367c6b] + ImageMetadata v0.9.10 [9b13fd28] + IndirectArrays v1.0.0 [d25df0c9] + Inflate v0.1.5 [7d512f48] + InternedStrings v0.7.0 [a98d9a8b] + Interpolations v0.16.2 [8197267c] + IntervalSets v0.7.13 [3587e190] + InverseFunctions v0.1.17 [92d709cd] + IrrationalConstants v0.2.6 [c8e1da08] + IterTools v1.10.0 [033835bb] + JLD2 v0.6.3 [692b3bcd] + JLLWrappers v1.7.1 [b835a17e] + JpegTurbo v0.1.6 [49dc5b4e] + KernelDensitySJ v0.2.2 [8ac3fa9e] + LRUCache v1.6.2 [2e889f3d] + LaMEM v0.4.12 [b964fa9f] + LaTeXStrings v1.4.0 [8cdb02fc] + LazyModules v0.3.1 [9c8b4983] + LightXML v0.9.3 [4345ca2d] + Loess v0.6.5 [2ab3a3ac] + LogExpFunctions v0.3.29 [da04e1cc] + MPI v0.20.23 [3da0fdf6] + MPIPreferences v0.1.11 [1914dd2f] + MacroTools v0.5.16 [dbb5928d] + MappedArrays v0.4.3 [7269a6da] + MeshIO v0.5.3 [e1d29d7a] + Missings v1.2.0 [e94cdb99] + MosaicViews v0.3.4 [46d2c3a1] + MuladdMacro v0.2.4 [85f8d34a] + NCDatasets v0.14.11 [77ba4419] + NaNMath v1.1.3 [b8a86587] + NearestNeighbors v0.4.26 [f09324ee] + Netpbm v1.1.1 [6fe1bfb0] + OffsetArrays v1.17.0 [52e1d378] + OpenEXR v0.3.3 [bac558e1] + OrderedCollections v1.8.1 [f57f5aa1] + PNGFiles v0.4.4 [5432bcbf] + PaddedViews v0.5.12 [d96e819e] + Parameters v0.12.3 [eebad327] + PkgVersion v0.3.3 ⌅ [aea7be01] + PrecompileTools v1.2.1 [21216c6a] + Preferences v1.5.1 [92933f4c] + ProgressMeter v1.11.0 [43287f4e] + PtrArrays v1.3.0 [4b34888f] + QOI v1.0.2 [b3c3ace0] + RangeArrays v0.3.2 [c84ed2f1] + Ratios v0.4.5 [dc215faf] + ReadVTK v0.2.5 [189a3867] + Reexport v1.2.2 [ae029012] + Requires v1.3.1 [79098fc4] + Rmath v0.9.0 [f2b01f46] + Roots v2.2.10 [fdea26ae] + SIMD v3.7.2 [431bcebd] + SciMLPublic v1.0.1 [7e506255] + ScopedValues v1.5.0 [efcf1570] + Setfield v1.1.2 [699a6c99] + SimpleTraits v0.9.5 [45858cf5] + Sixel v0.1.5 [a2af1166] + SortingAlgorithms v1.2.2 [276daf66] + SpecialFunctions v2.6.1 [cae243ae] + StackViews v0.1.2 [aedffcd0] + Static v1.3.1 [90137ffa] + StaticArrays v1.9.16 [1e83bf80] + StaticArraysCore v1.4.4 [82ae8749] + StatsAPI v1.8.0 [2913bbd2] + StatsBase v0.34.10 [4c63d2b9] + StatsFuns v1.5.2 [62fd8b95] + TensorCore v0.1.1 [731e570b] + TiffImages v0.11.6 [3bb67fe8] + TranscodingStreams v0.11.3 [3a884ed6] + UnPack v1.0.2 [967fb449] + Unidecode v1.2.0 [1986cc42] + Unitful v1.28.0 [4004b06d] + VTKBase v1.0.1 [e3aaa7dc] + WebP v0.1.3 [ea906314] + WhereTheWaterFlows v0.11.1 [efce3f68] + WoodburyMatrices v1.1.0 [64499a7a] + WriteVTK v1.21.2 ⌅ [8ce61222] + Arrow_jll v10.0.1+0 [0b7ba130] + Blosc_jll v1.21.7+0 [6e34b625] + Bzip2_jll v1.0.9+0 [83423d85] + Cairo_jll v1.18.5+0 [5ae413db] + EarCut_jll v2.2.4+0 [2e619515] + Expat_jll v2.7.3+0 [b22a6f82] + FFMPEG_jll v8.0.1+0 [a3f928ae] + Fontconfig_jll v2.17.1+0 [d7e528f0] + FreeType2_jll v2.13.4+0 [559328eb] + FriBidi_jll v1.0.17+0 ⌃ [a7073274] + GDAL_jll v301.800.400+0 [d604d12d] + GEOS_jll v3.14.1+0 [b0724c58] + GettextRuntime_jll v0.22.4+0 [59f7168a] + Giflib_jll v5.2.3+0 [7746bdde] + Glib_jll v2.86.2+0 [3b182d85] + Graphite2_jll v1.3.15+0 ⌅ [0234f1f7] + HDF5_jll v1.14.2+1 [2e76f6c2] + HarfBuzz_jll v8.5.1+0 [e33a78d0] + Hwloc_jll v2.12.2+0 [a51ab1cf] + ICU_jll v76.2.0+0 [905a6f67] + Imath_jll v3.2.2+0 [aacddb02] + JpegTurbo_jll v3.1.4+0 [b39eb1a6] + Kerberos_krb5_jll v1.21.3+0 [c1c5ebd0] + LAME_jll v3.100.3+0 ⌅ [88015f11] + LERC_jll v3.0.0+1 [1d63c593] + LLVMOpenMP_jll v18.1.8+0 [dd4b983a] + LZO_jll v2.10.3+0 ⌅ [15d6fa20] + LaMEM_jll v2.1.4+0 [08be9ffa] + LibPQ_jll v16.8.0+0 ⌅ [e9f186c6] + Libffi_jll v3.4.7+0 [7e76a0d4] + Libglvnd_jll v1.7.1+1 [94ce4f54] + Libiconv_jll v1.18.0+0 [4b2f31a3] + Libmount_jll v2.41.2+0 ⌅ [89763e89] + Libtiff_jll v4.5.1+1 [38a345b3] + Libuuid_jll v2.41.2+0 ⌃ [d3a379c0] + LittleCMS_jll v2.16.0+0 [5ced341a] + Lz4_jll v1.10.1+0 ⌅ [7cb0a576] + MPICH_jll v4.1.2+1 [f1f71cc9] + MPItrampoline_jll v5.5.4+0 [9237b28f] + MicrosoftMPI_jll v10.1.4+3 ⌅ [7243133f] + NetCDF_jll v400.902.209+0 [e7412a2a] + Ogg_jll v1.3.6+0 ⌅ [656ef2d0] + OpenBLAS32_jll v0.3.24+0 [18a262bb] + OpenEXR_jll v3.4.4+0 [643b3616] + OpenJpeg_jll v2.5.5+0 [fe0851c0] + OpenMPI_jll v5.0.9+0 [458c3c95] + OpenSSL_jll v3.5.5+0 [efe28fd5] + OpenSpecFun_jll v0.5.6+0 [91d4177d] + Opus_jll v1.6.1+0 ⌅ [8fa3689e] + PETSc_jll v3.19.6+0 ⌅ [58948b4f] + PROJ_jll v901.300.0+1 ⌅ [30392449] + Pixman_jll v0.44.2+0 [f50d1b31] + Rmath_jll v0.5.1+0 ⌃ [aabda75e] + SCALAPACK32_jll v2.2.1+1 [76ed43ae] + SQLite_jll v3.51.2+0 ⌅ [e0b8ae26] + Thrift_jll v0.16.0+0 ⌅ [02c8fc9c] + XML2_jll v2.13.9+0 [ffd25f8a] + XZ_jll v5.8.2+0 [4f6342f7] + Xorg_libX11_jll v1.8.12+0 [0c0b7dd1] + Xorg_libXau_jll v1.0.13+0 [a3789734] + Xorg_libXdmcp_jll v1.1.6+0 [1082639a] + Xorg_libXext_jll v1.3.7+0 [ea2f1a96] + Xorg_libXrender_jll v0.9.12+0 [a65dc6b1] + Xorg_libpciaccess_jll v0.18.1+0 [c7cfdc94] + Xorg_libxcb_jll v1.17.1+0 [c5fb5394] + Xorg_xtrans_jll v1.6.0+0 [3161d3a3] + Zstd_jll v1.5.7+1 ⌅ [28df3c45] + boost_jll v1.76.0+1 [c4b69c83] + dlfcn_win32_jll v1.4.2+0 [477f73a3] + libaec_jll v1.1.5+0 [a4ae2306] + libaom_jll v3.13.1+0 [0ac62f75] + libass_jll v0.17.4+0 [f638f0a6] + libfdk_aac_jll v2.0.4+0 ⌃ [06c338fa] + libgeotiff_jll v100.701.300+0 [b53b4c65] + libpng_jll v1.6.54+0 [075b6546] + libsixel_jll v1.10.5+0 [f27f6e37] + libvorbis_jll v1.3.8+0 ⌃ [c5f90fcd] + libwebp_jll v1.4.0+0 [337d8026] + libzip_jll v1.11.3+0 [fe1e1685] + snappy_jll v1.2.3+0 ⌅ [1270edf5] + x264_jll v10164.0.1+0 [dfaa095f] + x265_jll v4.1.0+0 [0dad84c5] + ArgTools v1.1.1 [56f22d72] + Artifacts [2a0f44e3] + Base64 [ade2ca70] + Dates [8ba89e20] + Distributed [f43a241f] + Downloads v1.6.0 [7b1f6079] + FileWatching [9fa8497b] + Future [b77e0a4c] + InteractiveUtils [4af54fe1] + LazyArtifacts [b27032c2] + LibCURL v0.6.4 [76f85450] + LibGit2 [8f399da3] + Libdl [37e2e46d] + LinearAlgebra [56ddb016] + Logging [d6f4376e] + Markdown [a63ad114] + Mmap [ca575930] + NetworkOptions v1.2.0 [44cfe95a] + Pkg v1.10.0 [de0858da] + Printf [3fa0cd96] + REPL [9a3f8284] + Random [ea8e919c] + SHA v0.7.0 [9e88b42a] + Serialization [1a1011a3] + SharedArrays [6462fe0b] + Sockets [2f01184e] + SparseArrays v1.10.0 [10745b16] + Statistics v1.10.0 [fa267f1f] + TOML v1.0.3 [a4e569a6] + Tar v1.10.0 [8dfed614] + Test [cf7118a7] + UUIDs [4ec0a83e] + Unicode [e66e0078] + CompilerSupportLibraries_jll v1.1.1+0 [deac9b47] + LibCURL_jll v8.4.0+0 [e37daf67] + LibGit2_jll v1.6.4+0 [29816b5a] + LibSSH2_jll v1.11.0+1 [c8ffd9c3] + MbedTLS_jll v2.28.1010+0 [14a3606d] + MozillaCACerts_jll v2025.12.2 [4536629a] + OpenBLAS_jll v0.3.23+5 [05823500] + OpenLibm_jll v0.8.5+0 [efcefdf7] + PCRE2_jll v10.42.0+1 [bea87d4a] + SuiteSparse_jll v7.2.1+1 [83775a58] + Zlib_jll v1.2.13+1 [8e850b90] + libblastrampoline_jll v5.11.0+0 [8e850ede] + nghttp2_jll v1.52.0+1 [3f19e933] + p7zip_jll v17.4.0+2 Info Packages marked with ⌃ and ⌅ have new versions available. Those with ⌃ may be upgradable, but those with ⌅ are restricted by compatibility constraints from upgrading. To see why use `status --outdated -m` Installation completed after 20.88s ################################################################################ # Precompilation # Precompiling PkgEval dependencies... ┌ Warning: Could not use exact versions of packages in manifest, re-resolving └ @ TestEnv ~/.julia/packages/TestEnv/h9a3r/src/julia-1.9/activate_set.jl:63 Precompiling package dependencies... Precompiling packages... 3453.3 ms ✓ Thrift_jll 933.1 ms ✓ MPICH_jll 3250.4 ms ✓ WhereTheWaterFlows 736.1 ms ✓ FilePaths → FilePathsGlobExt 957.0 ms ✓ PROJ_jll 907.9 ms ✓ LittleCMS_jll 1015.6 ms ✓ libwebp_jll 2637.3 ms ✓ Qt6ShaderTools_jll 1175.5 ms ✓ GR_jll 2022.0 ms ✓ Arrow_jll 6065.5 ms ✓ MPI 955.3 ms ✓ SCALAPACK32_jll 1072.4 ms ✓ HDF5_jll ✗ libgeotiff_jll 942.7 ms ✓ OpenJpeg_jll 5757.9 ms ✓ WebP 1583.4 ms ✓ Qt6Declarative_jll 1166.6 ms ✓ PETSc_jll 951.0 ms ✓ NetCDF_jll ✗ Makie 1028.9 ms ✓ Qt6Wayland_jll 1001.7 ms ✓ LaMEM_jll 9807.2 ms ✓ NCDatasets ✗ GDAL_jll ✗ GeoParams → GeoParamsMakieExt ✗ CairoMakie 8738.0 ms ✓ GR 45805.8 ms ✓ NCDatasets → NCDatasetsMPIExt 41109.8 ms ✓ GeophysicalModelGenerator 86817.3 ms ✓ Plots 34986.7 ms ✓ LaMEM 13198.3 ms ✓ Plots → UnitfulExt 12923.7 ms ✓ Plots → GeometryBasicsExt 9769.9 ms ✓ Plots → FileIOExt 88975.5 ms ? LaMEM → PlotsExt 29 dependencies successfully precompiled in 1037 seconds. 375 already precompiled. 1 dependencies failed but may be precompilable after restarting julia 1 dependency had output during precompilation: ┌ LaMEM → PlotsExt │ ┌ Warning: `Myrs` as a unit is deprecated. Use `Myr` instead. │ └ @ GeoParams.Units ~/.julia/packages/GeoParams/FuV4T/src/Units.jl:21 │ ┌ Warning: The call to compilecache failed to create a usable precompiled cache file for GeophysicalModelGenerator [3700c31b-fa53-48a6-808a-ef22d5a84742] │ │ exception = Required dependency CommonSubexpressions [bbf7d656-a473-5ed7-a52c-81e309532950] failed to load from a cache file. │ └ @ Base loading.jl:2065 └ ERROR: LoadError: The following 2 direct dependencies failed to precompile: CairoMakie Failed to precompile CairoMakie [13f3f980-e62b-5c42-98c6-ff1f3baf88f0] to "/home/pkgeval/.julia/compiled/v1.10/CairoMakie/jl_DiTBJJ". julia: /source/src/subtype.c:4817: sub_msp: Assertion `obvious_sub == 3 || obvious_sub == subtype || ijl_has_free_typevars(x) || ijl_has_free_typevars(y)' failed. [254] signal (6.-6): Aborted in expression starting at /home/pkgeval/.julia/packages/Makie/Vn16E/precompile/shared-precompile.jl:98 unknown function (ip: 0x71c6fe85febc) gsignal at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) abort at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) unknown function (ip: 0x71c6fe7fb394) __assert_fail at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) sub_msp at /source/src/subtype.c:4817 type_morespecific_ at /source/src/subtype.c:5075 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5185 type_morespecific_ at /source/src/subtype.c:5143 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5237 tuple_morespecific at /source/src/subtype.c:4879 [inlined] type_morespecific_ at /source/src/subtype.c:5061 ml_matches at /source/src/gf.c:3702 ml_matches at /source/src/gf.c:3589 [inlined] _gf_invoke_lookup at /source/src/gf.c:3093 [inlined] jl_mt_assoc_by_type at /source/src/gf.c:1463 jl_lookup_generic_ at /source/src/gf.c:3050 [inlined] ijl_apply_generic at /source/src/gf.c:3075 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 _register_argument_conversions! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:496 register_arguments! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:382 [inlined] Plot at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:769 unknown function (ip: 0x71c6d81500bc) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _create_plot! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/figureplotting.jl:416 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 #poly!#78 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/recipes.jl:534 poly! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/recipes.jl:532 [inlined] initialize_block! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks/toggle.jl:38 unknown function (ip: 0x71c6d8142c75) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 #_block#1911 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:405 _block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:321 [inlined] #_block#1910 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:266 [inlined] _block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:265 [inlined] #_#1908 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:242 [inlined] Block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:241 unknown function (ip: 0x71c6d813d1f5) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 jfptr_include_46673.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] jl_f__call_latest at /source/src/builtins.c:812 include at /home/pkgeval/.julia/packages/Makie/Vn16E/src/Makie.jl:1 [inlined] macro expansion at /home/pkgeval/.julia/packages/Makie/Vn16E/src/precompiles.jl:31 [inlined] macro expansion at /home/pkgeval/.julia/packages/PrecompileTools/L8A3n/src/workloads.jl:78 [inlined] top-level scope at /home/pkgeval/.julia/packages/Makie/Vn16E/src/precompiles.jl:23 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_invoke at /source/src/gf.c:2904 jl_toplevel_eval_flex at /source/src/toplevel.c:925 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 jfptr_include_46673.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] jl_f__call_latest at /source/src/builtins.c:812 include at /home/pkgeval/.julia/packages/Makie/Vn16E/src/Makie.jl:1 unknown function (ip: 0x71c6fd721a15) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_eval_module_expr at /source/src/toplevel.c:215 [inlined] jl_toplevel_eval_flex at /source/src/toplevel.c:736 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 [inlined] include_package_for_output at ./loading.jl:2295 jfptr_include_package_for_output_81425.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 include_string at ./loading.jl:2159 [inlined] exec_options at ./client.jl:314 _start at ./client.jl:550 jfptr__start_83133.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] true_main at /source/src/jlapi.c:582 jl_repl_entrypoint at /source/src/jlapi.c:731 main at /source/cli/loader_exe.c:58 unknown function (ip: 0x71c6fe7fc249) __libc_start_main at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) unknown function (ip: 0x4010b8) Allocations: 130626718 (Pool: 130519985; Big: 106733); GC: 130 ERROR: LoadError: Failed to precompile Makie [ee78f7c6-11fb-53f2-987a-cfe4a2b5a57a] to "/home/pkgeval/.julia/compiled/v1.10/Makie/jl_6I8Tfo". Stacktrace: [1] error(s::String) @ Base ./error.jl:35 [2] compilecache(pkg::Base.PkgId, path::String, internal_stderr::IO, internal_stdout::IO, keep_loaded_modules::Bool) @ Base ./loading.jl:2542 [3] compilecache @ ./loading.jl:2414 [inlined] [4] (::Base.var"#971#972"{Base.PkgId})() @ Base ./loading.jl:2047 [5] mkpidlock(f::Base.var"#971#972"{Base.PkgId}, at::String, pid::Int32; kwopts::@Kwargs{stale_age::Int64, wait::Bool}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:93 [6] #mkpidlock#6 @ /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:88 [inlined] [7] trymkpidlock(::Function, ::Vararg{Any}; kwargs::@Kwargs{stale_age::Int64}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:111 [8] #invokelatest#2 @ ./essentials.jl:894 [inlined] [9] invokelatest @ ./essentials.jl:889 [inlined] [10] maybe_cachefile_lock(f::Base.var"#971#972"{Base.PkgId}, pkg::Base.PkgId, srcpath::String; stale_age::Int64) @ Base ./loading.jl:3057 [11] maybe_cachefile_lock @ ./loading.jl:3054 [inlined] [12] _require(pkg::Base.PkgId, env::String) @ Base ./loading.jl:2043 [13] __require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1885 [14] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [15] invoke_in_world @ ./essentials.jl:923 [inlined] [16] _require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1876 [17] macro expansion @ ./loading.jl:1863 [inlined] [18] macro expansion @ ./lock.jl:270 [inlined] [19] __require(into::Module, mod::Symbol) @ Base ./loading.jl:1826 [20] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [21] invoke_in_world @ ./essentials.jl:923 [inlined] [22] require(into::Module, mod::Symbol) @ Base ./loading.jl:1819 [23] include @ ./Base.jl:495 [inlined] [24] include_package_for_output(pkg::Base.PkgId, input::String, depot_path::Vector{String}, dl_load_path::Vector{String}, load_path::Vector{String}, concrete_deps::Vector{Pair{Base.PkgId, UInt128}}, source::Nothing) @ Base ./loading.jl:2295 [25] top-level scope @ stdin:4 in expression starting at /home/pkgeval/.julia/packages/CairoMakie/h1BHQ/src/CairoMakie.jl:1 in expression starting at stdin:4 GeoParamsMakieExt Failed to precompile GeoParamsMakieExt [08ff5148-a89c-5d9b-bdc3-c94c1eeba2a3] to "/home/pkgeval/.julia/compiled/v1.10/GeoParamsMakieExt/jl_fSUfGv". julia: /source/src/subtype.c:4817: sub_msp: Assertion `obvious_sub == 3 || obvious_sub == subtype || ijl_has_free_typevars(x) || ijl_has_free_typevars(y)' failed. [218] signal (6.-6): Aborted in expression starting at /home/pkgeval/.julia/packages/Makie/Vn16E/precompile/shared-precompile.jl:98 unknown function (ip: 0x7141c89b8ebc) gsignal at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) abort at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) unknown function (ip: 0x7141c8954394) __assert_fail at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) sub_msp at /source/src/subtype.c:4817 type_morespecific_ at /source/src/subtype.c:5075 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5185 type_morespecific_ at /source/src/subtype.c:5143 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5237 tuple_morespecific at /source/src/subtype.c:4879 [inlined] type_morespecific_ at /source/src/subtype.c:5061 ml_matches at /source/src/gf.c:3702 ml_matches at /source/src/gf.c:3589 [inlined] _gf_invoke_lookup at /source/src/gf.c:3093 [inlined] jl_mt_assoc_by_type at /source/src/gf.c:1463 jl_lookup_generic_ at /source/src/gf.c:3050 [inlined] ijl_apply_generic at /source/src/gf.c:3075 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 _register_argument_conversions! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:496 register_arguments! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:382 [inlined] Plot at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:769 unknown function (ip: 0x7141a550712c) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _create_plot! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/figureplotting.jl:416 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 #poly!#78 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/recipes.jl:534 poly! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/recipes.jl:532 [inlined] initialize_block! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks/toggle.jl:38 unknown function (ip: 0x7141a54f9ce5) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 #_block#1911 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:405 _block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:321 [inlined] #_block#1910 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:266 [inlined] _block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:265 [inlined] #_#1908 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:242 [inlined] Block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:241 unknown function (ip: 0x7141a54f4265) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 jfptr_include_46673.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] jl_f__call_latest at /source/src/builtins.c:812 include at /home/pkgeval/.julia/packages/Makie/Vn16E/src/Makie.jl:1 [inlined] macro expansion at /home/pkgeval/.julia/packages/Makie/Vn16E/src/precompiles.jl:31 [inlined] macro expansion at /home/pkgeval/.julia/packages/PrecompileTools/L8A3n/src/workloads.jl:78 [inlined] top-level scope at /home/pkgeval/.julia/packages/Makie/Vn16E/src/precompiles.jl:23 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_invoke at /source/src/gf.c:2904 jl_toplevel_eval_flex at /source/src/toplevel.c:925 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 jfptr_include_46673.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] jl_f__call_latest at /source/src/builtins.c:812 include at /home/pkgeval/.julia/packages/Makie/Vn16E/src/Makie.jl:1 unknown function (ip: 0x7141c7b48e45) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_eval_module_expr at /source/src/toplevel.c:215 [inlined] jl_toplevel_eval_flex at /source/src/toplevel.c:736 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 [inlined] include_package_for_output at ./loading.jl:2295 jfptr_include_package_for_output_81425.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 include_string at ./loading.jl:2159 [inlined] exec_options at ./client.jl:314 _start at ./client.jl:550 jfptr__start_83133.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] true_main at /source/src/jlapi.c:582 jl_repl_entrypoint at /source/src/jlapi.c:731 main at /source/cli/loader_exe.c:58 unknown function (ip: 0x7141c8955249) __libc_start_main at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) unknown function (ip: 0x4010b8) Allocations: 133212043 (Pool: 133092765; Big: 119278); GC: 121 ERROR: LoadError: Failed to precompile Makie [ee78f7c6-11fb-53f2-987a-cfe4a2b5a57a] to "/home/pkgeval/.julia/compiled/v1.10/Makie/jl_atEoKq". Stacktrace: [1] error(s::String) @ Base ./error.jl:35 [2] compilecache(pkg::Base.PkgId, path::String, internal_stderr::IO, internal_stdout::IO, keep_loaded_modules::Bool) @ Base ./loading.jl:2542 [3] compilecache @ ./loading.jl:2414 [inlined] [4] (::Base.var"#971#972"{Base.PkgId})() @ Base ./loading.jl:2047 [5] mkpidlock(f::Base.var"#971#972"{Base.PkgId}, at::String, pid::Int32; kwopts::@Kwargs{stale_age::Int64, wait::Bool}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:93 [6] #mkpidlock#6 @ /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:88 [inlined] [7] trymkpidlock(::Function, ::Vararg{Any}; kwargs::@Kwargs{stale_age::Int64}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:111 [8] #invokelatest#2 @ ./essentials.jl:894 [inlined] [9] invokelatest @ ./essentials.jl:889 [inlined] [10] maybe_cachefile_lock(f::Base.var"#971#972"{Base.PkgId}, pkg::Base.PkgId, srcpath::String; stale_age::Int64) @ Base ./loading.jl:3057 [11] maybe_cachefile_lock @ ./loading.jl:3054 [inlined] [12] _require(pkg::Base.PkgId, env::String) @ Base ./loading.jl:2043 [13] __require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1885 [14] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [15] invoke_in_world @ ./essentials.jl:923 [inlined] [16] _require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1876 [17] macro expansion @ ./loading.jl:1863 [inlined] [18] macro expansion @ ./lock.jl:270 [inlined] [19] __require(into::Module, mod::Symbol) @ Base ./loading.jl:1826 [20] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [21] invoke_in_world @ ./essentials.jl:923 [inlined] [22] require(into::Module, mod::Symbol) @ Base ./loading.jl:1819 [23] top-level scope @ ~/.julia/packages/GeoParams/FuV4T/ext/GeoParamsMakieExt.jl:10 [24] include @ ./Base.jl:495 [inlined] [25] include_package_for_output(pkg::Base.PkgId, input::String, depot_path::Vector{String}, dl_load_path::Vector{String}, load_path::Vector{String}, concrete_deps::Vector{Pair{Base.PkgId, UInt128}}, source::Nothing) @ Base ./loading.jl:2295 [26] top-level scope @ stdin:4 in expression starting at /home/pkgeval/.julia/packages/GeoParams/FuV4T/ext/GeoParamsMakieExt.jl:2 in expression starting at stdin:4 in expression starting at /PkgEval.jl/scripts/precompile.jl:34 Precompilation failed after 1037.61s ################################################################################ # Testing # Testing LaMEM ┌ Warning: Could not use exact versions of packages in manifest, re-resolving └ @ Pkg.Operations /opt/julia/share/julia/stdlib/v1.10/Pkg/src/Operations.jl:1829 Status `/tmp/jl_3C6QyW/Project.toml` [13f3f980] CairoMakie v0.15.8 [8bb1440f] DelimitedFiles v1.9.1 [ffbed154] DocStringExtensions v0.9.5 [e018b62d] GeoParams v0.7.9 [3700c31b] GeophysicalModelGenerator v0.7.16 ⌅ [c27321d9] Glob v1.3.1 [a98d9a8b] Interpolations v0.16.2 [2e889f3d] LaMEM v0.4.12 [9c8b4983] LightXML v0.9.3 [da04e1cc] MPI v0.20.23 [3da0fdf6] MPIPreferences v0.1.11 [91a5bcdd] Plots v1.41.4 [dc215faf] ReadVTK v0.2.5 [64499a7a] WriteVTK v1.21.2 ⌅ [15d6fa20] LaMEM_jll v2.1.4+0 ⌅ [7cb0a576] MPICH_jll v4.1.2+1 [10745b16] Statistics v1.10.0 [8dfed614] Test Status `/tmp/jl_3C6QyW/Manifest.toml` [621f4979] AbstractFFTs v1.5.0 [1520ce14] AbstractTrees v0.4.5 [7d9f7c33] Accessors v0.1.43 [79e6a3ab] Adapt v4.4.0 [35492f91] AdaptivePredicates v1.2.0 [66dad0bd] AliasTables v1.1.3 [27a7e980] Animations v0.4.2 [67c07d97] Automa v1.1.0 [13072b0f] AxisAlgorithms v1.1.0 [39de3d68] AxisArrays v0.4.8 [18cc8868] BaseDirs v1.3.2 [7b0aa2c9] BibTeX v0.1.0 [d1d4a3ce] BitFlags v0.1.9 [fa961155] CEnum v0.5.0 [179af706] CFTime v0.2.5 [96374032] CRlibm v1.0.2 [159f3aea] Cairo v1.1.1 [13f3f980] CairoMakie v0.15.8 [d360d2e6] ChainRulesCore v1.26.0 [0b6fb165] ChunkCodecCore v1.0.1 [4c0bbee4] ChunkCodecLibZlib v1.0.0 [55437552] ChunkCodecLibZstd v1.0.0 [944b1d66] CodecZlib v0.7.8 [a2cac450] ColorBrewer v0.4.2 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Those with ⌃ may be upgradable, but those with ⌅ are restricted by compatibility constraints from upgrading. Testing Running tests... Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 2 Time step : 1. [Myr] Minimum time step : 0.2 [Myr] Maximum time step : 10. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [16, 16, 16] Number of cells : 4096 Number of faces : 13056 Maximum cell aspect ratio : 2.00000 Lower coordinate bounds [bx, by, bz] : [-2., -1., -1.] Upper coordinate bounds [ex, ey, ez] : [2., 1., 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 1 -- sphere (dens) : rho = 3200. [kg/m^3] (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.0293257 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress tensor @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Preconditioner type : coupled Galerkin geometric multigrid Global coarse grid [nx,ny,nz] : [8, 8, 8] Local coarse grid [nx,ny,nz] : [8, 8, 8] Number of multigrid levels : 2 -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : multigrid Multigrid smoother levels KSP : chebyshev Multigrid smoother levels PC : sor Number of smoothening steps : 10 Coarse level KSP : preonly Coarse level PC : lu Coarse level solver package : (null) -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 3.656395025301e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 5 1 SNES Function norm 9.765816215863e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.629574 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.291310889682e-05 |Div|_2 = 2.886140529488e-04 Momentum: |mRes|_2 = 9.761550506474e-03 -------------------------------------------------------------------------- Saving output ... done (0.00404368 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 1.00000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.685113961409e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 15 1 SNES Function norm 4.489500644001e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.777628 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.406409583179e-06 |Div|_2 = 5.437966746000e-06 Momentum: |mRes|_2 = 4.489497350596e-03 -------------------------------------------------------------------------- Actual time step : 1.10000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.1356e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00379729 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 1.63356 (sec) -------------------------------------------------------------------------- Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 3 Time step : 1. [Myr] Minimum time step : 1e-05 [Myr] Maximum time step : 10. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [16, 16, 16] Number of cells : 4096 Number of faces : 13056 Maximum cell aspect ratio : 2.00000 Lower coordinate bounds [bx, by, bz] : [-2., -1., -1.] Upper coordinate bounds [ex, ey, ez] : [2., 1., 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 1 -- sphere (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of velocity boxes : 1 Velocity box # : 0 Box center : 0., 0., 0. [km] Box width : 1., 1., 1. [km] X-velocity : 1. [cm/yr] Top boundary temperature : 0. [C] Bottom boundary temperature : 20. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.0282665 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Preconditioner type : coupled Galerkin geometric multigrid Global coarse grid [nx,ny,nz] : [8, 8, 8] Local coarse grid [nx,ny,nz] : [8, 8, 8] Number of multigrid levels : 2 -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : multigrid Multigrid smoother levels KSP : chebyshev Multigrid smoother levels PC : sor Number of smoothening steps : 10 Coarse level KSP : preonly Coarse level PC : lu Coarse level solver package : (null) -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 3.647420796124e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 4 1 SNES Function norm 7.297937424597e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.634061 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.461331555372e-06 |Div|_2 = 2.127815511859e-04 Momentum: |mRes|_2 = 7.294834793524e-03 -------------------------------------------------------------------------- Saving output ... done (0.00337111 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 1.00000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.382901817483e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 10 1 SNES Function norm 3.188552971360e-02 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.65362 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.448585401899e-05 |Div|_2 = 1.340409029960e-03 Momentum: |mRes|_2 = 3.185734308993e-02 -------------------------------------------------------------------------- Actual time step : 0.01250 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 4692 markers and merged 24 markers in 1.5977e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00292326 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.01250000 [Myr] Tentative time step : 0.01250000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.188552971358e-02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 11 1 SNES Function norm 1.891353888714e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.712235 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.163910967605e-09 |Div|_2 = 1.007415909660e-08 Momentum: |mRes|_2 = 1.888669019231e-07 -------------------------------------------------------------------------- Actual time step : 0.01250 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 8386 markers and merged 136 markers in 2.4808e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00316521 sec) -------------------------------------------------------------------------- ================================= STEP 3 ================================= -------------------------------------------------------------------------- Current time : 0.02500000 [Myr] Tentative time step : 0.01250000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.891353882404e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 13 1 SNES Function norm 3.806690487543e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.760528 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.732544348338e-15 |Div|_2 = 6.229370514023e-14 Momentum: |mRes|_2 = 3.806180757958e-12 -------------------------------------------------------------------------- Actual time step : 0.01250 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 9921 markers and merged 252 markers in 2.9578e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00285659 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 3.26897 (sec) -------------------------------------------------------------------------- Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 100000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 30 Time step : 0.01 [Myr] Minimum time step : 1e-05 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 5 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [64, 1, 64] Number of cells : 4096 Number of faces : 16512 Maximum cell aspect ratio : 1.28000 Lower coordinate bounds [bx, by, bz] : [-500., -10., -1000.] Upper coordinate bounds [ex, ey, ez] : [500., 10., 50.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- Air (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+22 [Pa*s] Bd = 5e-23 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1e+06 [J/kg/K] k = 100. [W/m/k] Phase ID : 1 -- OCrust (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+24 [Pa*s] Bd = 5e-25 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1050. [J/kg/K] k = 3. [W/m/k] Phase ID : 2 -- Omantle (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1050. [J/kg/K] k = 3. [W/m/k] Phase ID : 3 -- Umantle (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1050. [J/kg/K] k = 3. [W/m/k] Phase ID : 4 -- Plume (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1050. [J/kg/K] k = 3. [W/m/k] Phase ID : 5 -- Lmantle (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+21 [Pa*s] Bd = 5e-22 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1050. [J/kg/K] k = 3. [W/m/k] Phase ID : 6 -- Plume2 (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1050. [J/kg/K] k = 3. [W/m/k] Phase ID : 7 -- Umantle2 (dens) : rho = 3300. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] (temp) : alpha = 3e-05 [1/K] Cp = 1050. [J/kg/K] k = 3. [W/m/k] -------------------------------------------------------------------------- Phase Transition laws: -------------------------------------------------------------------------- Phase Transition [0] : Constant Parameter : T Transition Value : 1200.000 Phase Above : 3 Phase Below : 2 Direction : BothWays Phase Transition [1] : Constant Parameter : Depth Transition Value : -400.000 Phase Above : 6 Phase Below : 4 Direction : BelowToAbove Reset Parameter : APS Phase Transition [2] : Clapeyron Transition law : Mantle_Transition_660km # Equations : 1 [ P = P0 + gamma*(T-T0) ] eq[0] : gamma = -2.50e+00 [MPa/C], P0 = 2.30e+10 [Pa], T0 = 1667.0 [deg C] Phase Above : 5 Phase Below : 3 Direction : BothWays Phase Transition [3] : Box Box Bounds : [200.0; 400.0; -100.0; 100.0; -1000.0; -500.0] [km] Box Vicinity : Use all particles to check inside/outside Linear Temp; bot T : 1300.0 [C] Linear Temp; top T : 20.0 [C] Phase Outside : 3 Phase Inside : 7 Direction : BothWays Reset Parameter : APS Adjusting density values due to phase transitions: -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 1 0 Open top boundary @ Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.0303256 sec) -------------------------------------------------------------------------- Output parameters: Output file name : Plume_PhaseTransitions_new Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- Initializing pressure with lithostatic pressure ... done (0.00191353 sec) -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 1.985087139977e+04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.594719909526e-02 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.251664 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.736320446684e-03 |Div|_2 = 6.379041312826e-02 Momentum: |mRes|_2 = 1.672770938997e-02 -------------------------------------------------------------------------- Saving output ... done (0.00455177 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.01000000 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0254451 sec) -------------------------------------------------------------------------- 0 SNES Function norm 8.903947944260e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.024649811614e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.144603 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.935922950757e-06 |Div|_2 = 6.296964037381e-05 Momentum: |mRes|_2 = 6.024320723283e-03 -------------------------------------------------------------------------- Actual time step : 0.01100 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 441 markers and merged 0 markers in 1.3573e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00378018 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.01100000 [Myr] Tentative time step : 0.01100000 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0303 sec) -------------------------------------------------------------------------- 0 SNES Function norm 8.034506122548e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.042794808280e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.147959 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.100791055896e-06 |Div|_2 = 2.663022244943e-05 Momentum: |mRes|_2 = 3.042678273585e-03 -------------------------------------------------------------------------- Actual time step : 0.01210 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1089 markers and merged 0 markers in 1.2445e-02 s -------------------------------------------------------------------------- ================================= STEP 3 ================================= -------------------------------------------------------------------------- Current time : 0.02310000 [Myr] Tentative time step : 0.01210000 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0308506 sec) -------------------------------------------------------------------------- 0 SNES Function norm 5.318612913611e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.512638742054e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.1488 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.382602357380e-06 |Div|_2 = 8.871198692501e-06 Momentum: |mRes|_2 = 4.512630022295e-03 -------------------------------------------------------------------------- Actual time step : 0.01271 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1648 markers and merged 0 markers in 1.4133e-02 s -------------------------------------------------------------------------- ================================= STEP 4 ================================= -------------------------------------------------------------------------- Current time : 0.03580813 [Myr] Tentative time step : 0.01270813 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0261456 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.935573222169e+04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.347072227143e-02 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.141062 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.247047888856e-06 |Div|_2 = 7.447201618764e-06 Momentum: |mRes|_2 = 2.347072108994e-02 -------------------------------------------------------------------------- Actual time step : 0.01317 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2283 markers and merged 0 markers in 1.6953e-02 s -------------------------------------------------------------------------- ================================= STEP 5 ================================= -------------------------------------------------------------------------- Current time : 0.04898011 [Myr] Tentative time step : 0.01317198 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0320451 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.589238590905e+04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.013070382147e-02 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.149438 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.805947853928e-06 |Div|_2 = 3.560205426322e-06 Momentum: |mRes|_2 = 1.013070319589e-02 -------------------------------------------------------------------------- Actual time step : 0.01348 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2457 markers and merged 3 markers in 1.5387e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00369111 sec) -------------------------------------------------------------------------- ================================= STEP 6 ================================= -------------------------------------------------------------------------- Current time : 0.06246502 [Myr] Tentative time step : 0.01348490 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.027191 sec) -------------------------------------------------------------------------- 0 SNES Function norm 7.105193382543e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.154888385840e-02 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.151655 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.625893629040e-06 |Div|_2 = 7.876091187835e-06 Momentum: |mRes|_2 = 1.154888117274e-02 -------------------------------------------------------------------------- Actual time step : 0.01377 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2718 markers and merged 21 markers in 1.7384e-02 s -------------------------------------------------------------------------- ================================= STEP 7 ================================= -------------------------------------------------------------------------- Current time : 0.07623411 [Myr] Tentative time step : 0.01376910 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0297237 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.042373659728e+04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.510094877904e-02 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.142424 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.794971457089e-06 |Div|_2 = 6.312594508142e-06 Momentum: |mRes|_2 = 1.510094745962e-02 -------------------------------------------------------------------------- Actual time step : 0.01399 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3179 markers and merged 33 markers in 1.8771e-02 s -------------------------------------------------------------------------- ================================= STEP 8 ================================= -------------------------------------------------------------------------- Current time : 0.09022767 [Myr] Tentative time step : 0.01399356 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0327984 sec) -------------------------------------------------------------------------- 0 SNES Function norm 2.871444769587e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.658430341970e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.144501 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.403254490275e-06 |Div|_2 = 5.498127413823e-06 Momentum: |mRes|_2 = 1.658421228085e-03 -------------------------------------------------------------------------- Actual time step : 0.01398 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3119 markers and merged 57 markers in 2.1159e-02 s -------------------------------------------------------------------------- ================================= STEP 9 ================================= -------------------------------------------------------------------------- Current time : 0.10421032 [Myr] Tentative time step : 0.01398265 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0374573 sec) -------------------------------------------------------------------------- 0 SNES Function norm 4.449583974129e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.322063249770e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.145079 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.449661887811e-06 |Div|_2 = 5.875773877495e-06 Momentum: |mRes|_2 = 5.322060006223e-03 -------------------------------------------------------------------------- Actual time step : 0.01428 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3466 markers and merged 90 markers in 2.0596e-02 s -------------------------------------------------------------------------- ================================ STEP 10 ================================= -------------------------------------------------------------------------- Current time : 0.11849403 [Myr] Tentative time step : 0.01428371 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0284918 sec) -------------------------------------------------------------------------- 0 SNES Function norm 4.706865316454e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.788517436845e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.140956 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.971033394610e-06 |Div|_2 = 3.839433186097e-06 Momentum: |mRes|_2 = 2.788514793639e-03 -------------------------------------------------------------------------- Actual time step : 0.01439 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3661 markers and merged 117 markers in 2.3317e-02 s -------------------------------------------------------------------------- Saving output ... done (0.0041526 sec) -------------------------------------------------------------------------- ================================ STEP 11 ================================= -------------------------------------------------------------------------- Current time : 0.13288211 [Myr] Tentative time step : 0.01438807 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0379368 sec) -------------------------------------------------------------------------- 0 SNES Function norm 8.991485040991e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.694136165734e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.137654 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.383957079883e-06 |Div|_2 = 5.825431414762e-06 Momentum: |mRes|_2 = 8.694134214094e-03 -------------------------------------------------------------------------- Actual time step : 0.01458 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3219 markers and merged 150 markers in 2.4343e-02 s -------------------------------------------------------------------------- ================================ STEP 12 ================================= -------------------------------------------------------------------------- Current time : 0.14746103 [Myr] Tentative time step : 0.01457892 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0338086 sec) -------------------------------------------------------------------------- 0 SNES Function norm 5.473879258981e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.560793671473e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.140294 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.258375541324e-06 |Div|_2 = 2.992576486504e-06 Momentum: |mRes|_2 = 3.560792413957e-03 -------------------------------------------------------------------------- Actual time step : 0.01463 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3311 markers and merged 161 markers in 2.2327e-02 s -------------------------------------------------------------------------- ================================ STEP 13 ================================= -------------------------------------------------------------------------- Current time : 0.16209081 [Myr] Tentative time step : 0.01462979 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0331066 sec) -------------------------------------------------------------------------- 0 SNES Function norm 4.275685042272e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.103768241593e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.140261 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.613569589706e-06 |Div|_2 = 3.362504229368e-06 Momentum: |mRes|_2 = 5.103767133937e-03 -------------------------------------------------------------------------- Actual time step : 0.01468 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3513 markers and merged 249 markers in 2.3800e-02 s -------------------------------------------------------------------------- ================================ STEP 14 ================================= -------------------------------------------------------------------------- Current time : 0.17677097 [Myr] Tentative time step : 0.01468015 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0347354 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.350290833178e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.726032134112e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.14148 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.747924524954e-06 |Div|_2 = 6.606745373525e-06 Momentum: |mRes|_2 = 1.726019489723e-03 -------------------------------------------------------------------------- Actual time step : 0.01480 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3237 markers and merged 241 markers in 2.6550e-02 s -------------------------------------------------------------------------- ================================ STEP 15 ================================= -------------------------------------------------------------------------- Current time : 0.19157476 [Myr] Tentative time step : 0.01480379 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0365271 sec) -------------------------------------------------------------------------- 0 SNES Function norm 2.674533097998e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.036490753468e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.141498 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.276829055403e-06 |Div|_2 = 5.026127715309e-06 Momentum: |mRes|_2 = 3.036486593736e-03 -------------------------------------------------------------------------- Actual time step : 0.01474 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3166 markers and merged 301 markers in 2.6806e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00383731 sec) -------------------------------------------------------------------------- ================================ STEP 16 ================================= -------------------------------------------------------------------------- Current time : 0.20631027 [Myr] Tentative time step : 0.01473551 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0390335 sec) -------------------------------------------------------------------------- 0 SNES Function norm 3.214195749760e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.255579919968e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.138408 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 7.215428179386e-07 |Div|_2 = 1.542132189085e-06 Momentum: |mRes|_2 = 1.255578972927e-03 -------------------------------------------------------------------------- Actual time step : 0.01494 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2829 markers and merged 348 markers in 2.6610e-02 s -------------------------------------------------------------------------- ================================ STEP 17 ================================= -------------------------------------------------------------------------- Current time : 0.22125036 [Myr] Tentative time step : 0.01494009 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0357569 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.415360965464e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.397087471237e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.138674 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.282432859018e-06 |Div|_2 = 2.980539196763e-06 Momentum: |mRes|_2 = 1.397084291900e-03 -------------------------------------------------------------------------- Actual time step : 0.01505 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 3076 markers and merged 366 markers in 2.9573e-02 s -------------------------------------------------------------------------- ================================ STEP 18 ================================= -------------------------------------------------------------------------- Current time : 0.23629778 [Myr] Tentative time step : 0.01504742 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0432226 sec) -------------------------------------------------------------------------- 0 SNES Function norm 3.271567359873e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.069485309642e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.13941 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.690801147980e-06 |Div|_2 = 4.153467007522e-06 Momentum: |mRes|_2 = 3.069482499514e-03 -------------------------------------------------------------------------- Actual time step : 0.01518 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2831 markers and merged 351 markers in 2.7992e-02 s -------------------------------------------------------------------------- ================================ STEP 19 ================================= -------------------------------------------------------------------------- Current time : 0.25147556 [Myr] Tentative time step : 0.01517778 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0355103 sec) -------------------------------------------------------------------------- 0 SNES Function norm 8.407677792888e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.478870555625e-04 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.135359 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.034064185168e-06 |Div|_2 = 1.427767384948e-06 Momentum: |mRes|_2 = 3.478841256917e-04 -------------------------------------------------------------------------- Actual time step : 0.01517 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2958 markers and merged 373 markers in 2.9229e-02 s -------------------------------------------------------------------------- ================================ STEP 20 ================================= -------------------------------------------------------------------------- Current time : 0.26665036 [Myr] Tentative time step : 0.01517480 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0397412 sec) -------------------------------------------------------------------------- 0 SNES Function norm 3.454633636616e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.597346615330e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.142395 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.757287793226e-06 |Div|_2 = 4.633531387496e-06 Momentum: |mRes|_2 = 4.597344280328e-03 -------------------------------------------------------------------------- Actual time step : 0.01529 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2615 markers and merged 348 markers in 2.8585e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00449383 sec) -------------------------------------------------------------------------- ================================ STEP 21 ================================= -------------------------------------------------------------------------- Current time : 0.28194393 [Myr] Tentative time step : 0.01529357 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0351535 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.662243615071e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.457572792318e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.13682 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.549740517276e-06 |Div|_2 = 2.356606806332e-06 Momentum: |mRes|_2 = 1.457570887233e-03 -------------------------------------------------------------------------- Actual time step : 0.01530 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2223 markers and merged 464 markers in 3.0329e-02 s -------------------------------------------------------------------------- ================================ STEP 22 ================================= -------------------------------------------------------------------------- Current time : 0.29723979 [Myr] Tentative time step : 0.01529587 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.038284 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.666098628745e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.181579776420e-04 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.139517 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.105071822966e-07 |Div|_2 = 4.345251602430e-07 Momentum: |mRes|_2 = 2.181575448998e-04 -------------------------------------------------------------------------- Actual time step : 0.01536 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2358 markers and merged 388 markers in 3.1120e-02 s -------------------------------------------------------------------------- ================================ STEP 23 ================================= -------------------------------------------------------------------------- Current time : 0.31259987 [Myr] Tentative time step : 0.01536008 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0391481 sec) -------------------------------------------------------------------------- 0 SNES Function norm 6.520633752479e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.585323132561e-04 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.144772 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.074607750498e-07 |Div|_2 = 1.241583485338e-06 Momentum: |mRes|_2 = 3.585301634720e-04 -------------------------------------------------------------------------- Actual time step : 0.01533 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2052 markers and merged 489 markers in 3.0990e-02 s -------------------------------------------------------------------------- ================================ STEP 24 ================================= -------------------------------------------------------------------------- Current time : 0.32792814 [Myr] Tentative time step : 0.01532827 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.040874 sec) -------------------------------------------------------------------------- 0 SNES Function norm 7.544791942376e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.645518857154e-04 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.145247 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.963381580539e-06 |Div|_2 = 3.578799441957e-06 Momentum: |mRes|_2 = 6.645422492230e-04 -------------------------------------------------------------------------- Actual time step : 0.01533 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1961 markers and merged 581 markers in 2.9912e-02 s -------------------------------------------------------------------------- ================================ STEP 25 ================================= -------------------------------------------------------------------------- Current time : 0.34326050 [Myr] Tentative time step : 0.01533236 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.036258 sec) -------------------------------------------------------------------------- 0 SNES Function norm 2.428135768392e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.940813617477e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.141175 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.323266839596e-06 |Div|_2 = 2.195414288975e-06 Momentum: |mRes|_2 = 1.940812375769e-03 -------------------------------------------------------------------------- Actual time step : 0.01535 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 2019 markers and merged 548 markers in 3.0847e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00391901 sec) -------------------------------------------------------------------------- ================================ STEP 26 ================================= -------------------------------------------------------------------------- Current time : 0.35861463 [Myr] Tentative time step : 0.01535414 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0403029 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.789866730496e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.615523047067e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.142269 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.855295772624e-06 |Div|_2 = 3.281914795005e-06 Momentum: |mRes|_2 = 1.615519713479e-03 -------------------------------------------------------------------------- Actual time step : 0.01538 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1918 markers and merged 626 markers in 3.3064e-02 s -------------------------------------------------------------------------- ================================ STEP 27 ================================= -------------------------------------------------------------------------- Current time : 0.37399938 [Myr] Tentative time step : 0.01538475 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0425674 sec) -------------------------------------------------------------------------- 0 SNES Function norm 5.889560968213e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.610205639529e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.142919 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.735301883940e-07 |Div|_2 = 1.052907877585e-06 Momentum: |mRes|_2 = 1.610205295283e-03 -------------------------------------------------------------------------- Actual time step : 0.01541 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1756 markers and merged 594 markers in 3.8061e-02 s -------------------------------------------------------------------------- ================================ STEP 28 ================================= -------------------------------------------------------------------------- Current time : 0.38940579 [Myr] Tentative time step : 0.01540641 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0427653 sec) -------------------------------------------------------------------------- 0 SNES Function norm 6.172228468350e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.191147607294e-04 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.138606 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.224928623258e-06 |Div|_2 = 5.311699400284e-06 Momentum: |mRes|_2 = 5.190875847645e-04 -------------------------------------------------------------------------- Actual time step : 0.01550 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1699 markers and merged 628 markers in 3.4189e-02 s -------------------------------------------------------------------------- ================================ STEP 29 ================================= -------------------------------------------------------------------------- Current time : 0.40491046 [Myr] Tentative time step : 0.01550467 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0395214 sec) -------------------------------------------------------------------------- 0 SNES Function norm 2.295216675739e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.561757840034e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.140702 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.107123301842e-06 |Div|_2 = 4.128857669323e-06 Momentum: |mRes|_2 = 1.561752382243e-03 -------------------------------------------------------------------------- Actual time step : 0.01561 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1661 markers and merged 673 markers in 3.7806e-02 s -------------------------------------------------------------------------- ================================ STEP 30 ================================= -------------------------------------------------------------------------- Current time : 0.42052352 [Myr] Tentative time step : 0.01561306 [Myr] -------------------------------------------------------------------------- Phase_Transition ... done (0.0448403 sec) -------------------------------------------------------------------------- 0 SNES Function norm 1.803452452713e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.966698890739e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.160644 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.558964615428e-06 |Div|_2 = 3.788307440217e-06 Momentum: |mRes|_2 = 1.966695242167e-03 -------------------------------------------------------------------------- Actual time step : 0.01574 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 1519 markers and merged 607 markers in 3.2548e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00409831 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 11.0595 (sec) -------------------------------------------------------------------------- pwd() = "/home/pkgeval/.julia/packages/LaMEM/qcV9I/test" readdir() = ["CreateMarkers_Subduction_Linear_FreeSlip_parallel.jl", "Rhyolite.in", "input_files", "markers", "mesh_refinement_test.jl", "read_logfile.jl", "read_timestep.jl", "runLaMEM.jl", "run_lamem_save_grid_test.jl", "runtests.jl", "test_GeoParams_integration.jl", "test_compression.jl", "test_erosion.jl", "test_examples.jl", "test_julia_setup_phase_diagrams.jl", "test_julia_setups.jl", "test_sedimentation.jl"] Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 100000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 4 Time step : 0.04 [Myr] Minimum time step : 0.004 [Myr] Maximum time step : 0.2 [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [16, 1, 16] Number of cells : 256 Number of faces : 1056 Maximum cell aspect ratio : 6.25000 Lower coordinate bounds [bx, by, bz] : [-100., -1., -100.] Upper coordinate bounds [ex, ey, ez] : [100., 1., 0.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 1 -- heter - Employing phase diagram: /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/Rhyolite (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] Phase ID : 0 -- matrix - Employing phase diagram: /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/Rhyolite (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 989.583 [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.00219256 sec) -------------------------------------------------------------------------- Phase Diagrams: Diagrams employed for phases : 0: P range=[0.2-20.2] kbar, T range = [386.4-2086.4] K 1: -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ Melt fraction @ Fluid density @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 3.934530286730e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.581262562749e+02 1 PICARD ||F||/||F0||=4.018936e-02 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.117627025004e+01 2 MMFD ||F||/||F0||=2.840560e-03 Linear js_ solve converged due to CONVERGED_RTOL iterations 3 3 SNES Function norm 1.432330149671e-01 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 3 SNES solution time : 0.0155765 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.002321873040e-09 |Div|_2 = 5.644441176775e-08 Momentum: |mRes|_2 = 1.432330149671e-01 -------------------------------------------------------------------------- Saving output ... done (0.0011535 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.04000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.050235816760e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.039676666126e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.00568533 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.069414583551e-18 |Div|_2 = 3.162302608719e-17 Momentum: |mRes|_2 = 3.039676666126e-03 -------------------------------------------------------------------------- Actual time step : 0.04400 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 5.5149e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000895121 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.04400000 [Myr] Tentative time step : 0.04400000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.040264438959e-03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 6.434728602950e-05 1 PICARD ||F||/||F0||=2.116503e-02 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 2 SNES Function norm 1.391731242115e-06 2 MMFD ||F||/||F0||=4.577665e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 3 3 SNES Function norm 3.775960634440e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 3 SNES solution time : 0.020217 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 7.030373462211e-20 |Div|_2 = 2.243793518119e-19 Momentum: |mRes|_2 = 3.775960634440e-12 -------------------------------------------------------------------------- Actual time step : 0.04840 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.4818e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000899651 sec) -------------------------------------------------------------------------- ================================= STEP 3 ================================= -------------------------------------------------------------------------- Current time : 0.09240000 [Myr] Tentative time step : 0.04840000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.883181848925e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 7.210941128243e-07 1 PICARD ||F||/||F0||=2.501036e-02 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 2 SNES Function norm 1.472232176353e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0104484 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.343431206158e-15 |Div|_2 = 7.266627062028e-15 Momentum: |mRes|_2 = 1.472232176353e-08 -------------------------------------------------------------------------- Actual time step : 0.05324 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 5.4269e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00134828 sec) -------------------------------------------------------------------------- ================================= STEP 4 ================================= -------------------------------------------------------------------------- Current time : 0.14564000 [Myr] Tentative time step : 0.05324000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.170864950966e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 7.927997956283e-07 1 PICARD ||F||/||F0||=2.500264e-02 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 2 SNES Function norm 1.618712375651e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0104992 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.477117569190e-15 |Div|_2 = 7.988983672080e-15 Momentum: |mRes|_2 = 1.618712375651e-08 -------------------------------------------------------------------------- Actual time step : 0.05856 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 5.5840e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00127455 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.298301 (sec) -------------------------------------------------------------------------- Saved file: Model3D.vts cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 2 Time step : 1. [Myr] Minimum time step : 0.2 [Myr] Maximum time step : 10. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [16, 1, 16] Number of cells : 256 Number of faces : 1056 Maximum cell aspect ratio : 2.00000 Lower coordinate bounds [bx, by, bz] : [-2., -0.09375, -1.] Upper coordinate bounds [ex, ey, ez] : [2., 0.09375, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 1 -- sphere (dens) : rho = 3200. [kg/m^3] (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : geometric primitives Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise Background phase ID : 0 -------------------------------------------------------------------------- Reading geometric primitives ... done (0.000218348 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 9.118551990311e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.116028797339e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00784762 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.174184490476e-18 |Div|_2 = 5.984135402956e-18 Momentum: |mRes|_2 = 1.116028797323e-12 -------------------------------------------------------------------------- Saving output ... done (0.00101251 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 1.00000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.116028797339e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.979851535660e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00456291 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.877881017396e-30 |Div|_2 = 3.192494526470e-29 Momentum: |mRes|_2 = 4.979851535660e-14 -------------------------------------------------------------------------- Actual time step : 1.10000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 5.7013e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000888041 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0370225 (sec) -------------------------------------------------------------------------- Saved file: Model3D.vts cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 2 Time step : 1. [Myr] Minimum time step : 0.2 [Myr] Maximum time step : 10. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [16, 1, 16] Number of cells : 256 Number of faces : 1056 Maximum cell aspect ratio : 2.00000 Lower coordinate bounds [bx, by, bz] : [-2., -0.09375, -1.] Upper coordinate bounds [ex, ey, ez] : [2., 0.09375, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 1 -- sphere (dens) : rho = 3200. [kg/m^3] (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : geometric primitives Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise Background phase ID : 0 -------------------------------------------------------------------------- Reading geometric primitives ... done (0.000674274 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 9.118551990311e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.116028797339e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00773702 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.174184490476e-18 |Div|_2 = 5.984135402956e-18 Momentum: |mRes|_2 = 1.116028797323e-12 -------------------------------------------------------------------------- Saving output ... done (0.00102598 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 1.00000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.116028797339e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.979851535660e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00460912 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.877881017396e-30 |Div|_2 = 3.192494526470e-29 Momentum: |mRes|_2 = 4.979851535660e-14 -------------------------------------------------------------------------- Actual time step : 1.10000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 5.5074e-04 s -------------------------------------------------------------------------- Saving output ... done (0.0010103 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0378901 (sec) -------------------------------------------------------------------------- cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/input_files/FallingBlock_Multigrid.dat Adding PETSc option: -snes_type ksponly Adding PETSc option: -js_ksp_monitor Adding PETSc option: -crs_pc_type bjacobi Finished parsing input file -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [ ] Maximum number of steps : 1 Time step : 10. [ ] Minimum time step : 1e-05 [ ] Maximum time step : 100. [ ] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.5 Output time step : 0.2 [ ] Output every [n] steps : 1 Output [n] initial steps : 1 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [32, 32, 32] Number of cells : 32768 Number of faces : 101376 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [0., 0., 0.] Upper coordinate bounds [ex, ey, ez] : [1., 1., 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 (dens) : rho = 1. [ ] (diff) : eta = 1. [ ] Bd = 0.5 [ ] Phase ID : 1 (dens) : rho = 2. [ ] (diff) : eta = 100. [ ] Bd = 0.005 [ ] Phase ID : 2 (dens) : rho = 2. [ ] (diff) : eta = 1000. [ ] Bd = 0.0005 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -1.] [ ] Surface stabilization (FSSA) : 1. Use lithostatic pressure for creep @ Minimum viscosity : 0.001 [ ] Maximum viscosity : 1e+12 [ ] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : geometric primitives Velocity interpolation scheme : empirical STAGP (STAG + pressure points) Marker control type : pure AVD for all control volumes Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise Background phase ID : 0 Interpolation constant : 0.7 -------------------------------------------------------------------------- Reading geometric primitives ... done (0.0203215 sec) -------------------------------------------------------------------------- Output parameters: Output file name : FB_multigrid Write .pvd file : yes Phase @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Deviatoric stress second invariant @ Deviatoric strain rate tensor @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- AVD output parameters: Write .pvd file : yes AVD refinement factor : 3 -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Preconditioner type : coupled Galerkin geometric multigrid Global coarse grid [nx,ny,nz] : [4, 4, 4] Local coarse grid [nx,ny,nz] : [4, 4, 4] Number of multigrid levels : 4 -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : multigrid Multigrid smoother levels KSP : chebyshev Multigrid smoother levels PC : sor Number of smoothening steps : 10 Coarse level KSP : preonly Coarse level PC : bjacobi -------------------------------------------------------------------------- Saving output ... done (0.947085 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [ ] Tentative time step : 10.00000000 [ ] -------------------------------------------------------------------------- 0 SNES Function norm 1.832203177398e+02 0 PICARD ||F||/||F0||=1.000000e+00 Residual norms for js_ solve. 0 KSP Residual norm 2.121468833494e+01 1 KSP Residual norm 2.007312746141e+01 2 KSP Residual norm 1.436721786209e+01 3 KSP Residual norm 7.031413261028e+00 4 KSP Residual norm 2.361866279194e+00 5 KSP Residual norm 1.011785314253e+00 6 KSP Residual norm 4.700182839567e-01 7 KSP Residual norm 3.431392417306e-01 8 KSP Residual norm 1.759675422301e-01 9 KSP Residual norm 1.053716068647e-01 10 KSP Residual norm 9.342460424411e-02 11 KSP Residual norm 7.749792924243e-02 12 KSP Residual norm 5.192767141878e-02 13 KSP Residual norm 3.842800827033e-02 14 KSP Residual norm 1.589386132911e-02 15 KSP Residual norm 8.851034636242e-03 16 KSP Residual norm 4.554700539865e-03 17 KSP Residual norm 2.632601842348e-03 18 KSP Residual norm 1.311043982030e-03 19 KSP Residual norm 6.462411319589e-04 20 KSP Residual norm 3.583024905386e-04 21 KSP Residual norm 1.510300556884e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 21 1 SNES Function norm 1.371165827605e-02 -------------------------------------------------------------------------- SNES Convergence Reason : maximum iterations reached Number of iterations : 1 SNES solution time : 7.89396 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.351162529297e-05 |Div|_2 = 1.404433474462e-04 Momentum: |mRes|_2 = 1.371093900305e-02 -------------------------------------------------------------------------- Actual time step : 6.73129 [ ] -------------------------------------------------------------------------- Marker control [0]: (AVD YZED) injected 5 markers and deleted 0 markers in 1.3165e-03 s Marker control [0]: (AVD XZED) injected 7 markers and deleted 0 markers in 1.4567e-03 s Marker control [0]: (AVD XYED) injected 10 markers and deleted 0 markers in 2.0164e-03 s -------------------------------------------------------------------------- Saving output ... done (1.26479 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 12.2814 (sec) -------------------------------------------------------------------------- cores_compute = 4 Fatal error in internal_Init_thread: Other MPI error, error stack: internal_Init_thread(67)...........: MPI_Init_thread(argc=0x7ffd2c22b4ac, argv=0x7ffd2c22b4a0, required=1, provided=0x7ffd2c22b06c) failed MPII_Init_thread(234)..............: MPID_Init(67)......................: init_world(171)....................: channel initialization failed MPIDI_CH3_Init(84).................: MPID_nem_init(314).................: MPID_nem_tcp_init(175).............: MPID_nem_tcp_get_business_card(397): GetSockInterfaceAddr(370)..........: gethostbyname failed, LaMEM-primary-i6RGmhki (errno 1) Falling Block test on 4 cores failed cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/input_files/FallingBlock_DirectSolver.dat Adding PETSc option: -snes_type ksponly Adding PETSc option: -js_ksp_monitor Finished parsing input file -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [ ] Maximum number of steps : 2 Time step : 10. [ ] Minimum time step : 1e-05 [ ] Maximum time step : 100. [ ] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.5 Output time step : 0.2 [ ] Output every [n] steps : 1000 Output [n] initial steps : 1 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [16, 16, 16] Number of cells : 4096 Number of faces : 13056 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [0., 0., 0.] Upper coordinate bounds [ex, ey, ez] : [1., 1., 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 (dens) : rho = 1. [ ] (diff) : eta = 1. [ ] Bd = 0.5 [ ] Phase ID : 1 (dens) : rho = 2. [ ] (diff) : eta = 100. [ ] Bd = 0.005 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -1.] [ ] Surface stabilization (FSSA) : 1. Use lithostatic pressure for creep @ Minimum viscosity : 0.001 [ ] Maximum viscosity : 1e+12 [ ] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : geometric primitives Velocity interpolation scheme : empirical STAGP (STAG + pressure points) Marker control type : pure AVD for all control volumes Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise Background phase ID : 0 Interpolation constant : 0.7 -------------------------------------------------------------------------- Reading geometric primitives ... done (0.00385519 sec) -------------------------------------------------------------------------- Output parameters: Output file name : FB_direct Write .pvd file : yes Phase @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ -------------------------------------------------------------------------- AVD output parameters: Write .pvd file : yes AVD refinement factor : 3 -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+03 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- Saving output ... done (0.126905 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [ ] Tentative time step : 10.00000000 [ ] -------------------------------------------------------------------------- 0 SNES Function norm 7.310266752999e+01 0 PICARD ||F||/||F0||=1.000000e+00 Residual norms for js_ solve. 0 KSP Residual norm 2.133540043787e+01 1 KSP Residual norm 1.859427686320e-02 2 KSP Residual norm 2.899733401244e-05 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.649877042896e-04 -------------------------------------------------------------------------- SNES Convergence Reason : maximum iterations reached Number of iterations : 1 SNES solution time : 2.6101 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.056315829386e-06 |Div|_2 = 3.650679845667e-05 Momentum: |mRes|_2 = 1.608980926960e-04 -------------------------------------------------------------------------- Actual time step : 7.69851 [ ] -------------------------------------------------------------------------- Marker control [0]: (AVD CELL) injected 1 markers and deleted 0 markers in 3.0668e-04 s Marker control [0]: (AVD YZED) injected 6 markers and deleted 0 markers in 9.8950e-04 s Marker control [0]: (AVD XZED) injected 8 markers and deleted 0 markers in 1.5710e-03 s Marker control [0]: (AVD XYED) injected 2 markers and deleted 0 markers in 4.4397e-04 s -------------------------------------------------------------------------- Saving output ... done (0.142047 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 7.69851107 [ ] Tentative time step : 7.69851107 [ ] -------------------------------------------------------------------------- 0 SNES Function norm 1.307661178463e+02 0 PICARD ||F||/||F0||=1.000000e+00 Residual norms for js_ solve. 0 KSP Residual norm 1.189285812726e+00 1 KSP Residual norm 1.071718651319e-03 2 KSP Residual norm 2.121756434235e-06 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.789132168326e-04 -------------------------------------------------------------------------- SNES Convergence Reason : maximum iterations reached Number of iterations : 1 SNES solution time : 2.27311 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.594135843254e-08 |Div|_2 = 7.340971818893e-07 Momentum: |mRes|_2 = 5.789127513924e-04 -------------------------------------------------------------------------- Actual time step : 8.25319 [ ] -------------------------------------------------------------------------- Marker control [0]: (AVD YZED) injected 5 markers and deleted 0 markers in 8.5795e-04 s Marker control [0]: (AVD XZED) injected 4 markers and deleted 0 markers in 7.0987e-04 s Marker control [0]: (AVD XYED) injected 7 markers and deleted 0 markers in 1.2476e-03 s -------------------------------------------------------------------------- Saving output ... done (0.125276 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 5.70969 (sec) -------------------------------------------------------------------------- cores_compute = 2 Fatal error in internal_Init_thread: Other MPI error, error stack: internal_Init_thread(67)...........: MPI_Init_thread(argc=0x7ffc392c9b8c, argv=0x7ffc392c9b80, required=1, provided=0x7ffc392c974c) failed MPII_Init_thread(234)..............: MPID_Init(67)......................: init_world(171)....................: channel initialization failed MPIDI_CH3_Init(84).................: MPID_nem_init(314).................: MPID_nem_tcp_init(175).............: MPID_nem_tcp_get_business_card(397): GetSockInterfaceAddr(370)..........: gethostbyname failed, LaMEM-primary-i6RGmhki (errno 1) run LaMEM: Error During Test at /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/runLaMEM.jl:4 Got exception outside of a @test failed process: Process(setenv(`/home/pkgeval/.julia/artifacts/0ed4137b58af5c5e3797cb0c400e60ed7c308bae/bin/mpiexec -n 2 /home/pkgeval/.julia/artifacts/cd461744844630cc33fbd2e7a8e795b56651d039/bin/LaMEM -ParamFile /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/input_files/FallingBlock_DirectSolver.dat '-nstep_max 5'`,["PYTHON=", "PATH=/home/pkgeval/.julia/artifacts/0ed4137b58af5c5e3797cb0c400e60ed7c308bae/bin:/usr/local/bin:/usr/local/sbin:/usr/bin:/usr/sbin:/bin:/sbin:/opt/julia/bin", "ZES_ENABLE_SYSMAN=1", "DISPLAY=:1", "LD_LIBRARY_PATH=/opt/julia/bin/../lib/julia:/home/pkgeval/.julia/artifacts/93ddb84060b49f38ec59d4b04a3109fedc4577d2/lib:/home/pkgeval/.julia/artifacts/0ed4137b58af5c5e3797cb0c400e60ed7c308bae/lib:/home/pkgeval/.julia/artifacts/0a6a41be79ef85f32aa7d8529d4aebf9ef8ab030/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/double_real_Int64/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/single_complex_Int32/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/single_complex_Int64/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/single_real_Int32/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/single_real_Int64/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/double_complex_Int32/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/double_complex_Int64/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/double_real_Int32/lib:/home/pkgeval/.julia/artifacts/3f1a00f1080275e347bfbcf5d11aac546fc87017/lib/petsc/double_real_Int64_deb/lib:/home/pkgeval/.julia/artifacts/cd461744844630cc33fbd2e7a8e795b56651d039/lib:/opt/julia/bin/../lib/julia:/opt/julia/bin/../lib:/opt/julia/bin/../lib/julia:/home/pkgeval/.julia/artifacts/0ed4137b58af5c5e3797cb0c400e60ed7c308bae/lib:/opt/julia/bin/../lib/julia:/opt/julia/bin/../lib", "OPENBLAS_NUM_THREADS=1", "OMP_NUM_THREADS=1", "CI=true", "R_HOME=*", "FONTCONFIG_PATH=/home/pkgeval/.julia/artifacts/258f7271ca555a7634c0fe8b8508f69334673a89/etc/fonts", "LANG=C.UTF-8", "VECLIB_MAXIMUM_THREADS=1", "JULIA_CPU_THREADS=1", "JULIA_NUM_PRECOMPILE_TASKS=1", "FONTCONFIG_FILE=/home/pkgeval/.julia/artifacts/258f7271ca555a7634c0fe8b8508f69334673a89/etc/fonts/fonts.conf", "JULIA_LOAD_PATH=/tmp/jl_3C6QyW/Project.toml", "UCX_MEMTYPE_CACHE=no", "PKGEVAL=true", "UCX_ERROR_SIGNALS=SIGILL,SIGBUS,SIGFPE", "HOME=/home/pkgeval", "JULIA_PKG_PRECOMPILE_AUTO=0", "JULIA_PKGEVAL=true", "OPENBLAS_MAIN_FREE=1", "JULIA_DEPOT_PATH=/home/pkgeval/.julia:/usr/local/share/julia:", "JULIA_NUM_THREADS=1"]), ProcessExited(15)) [15] Stacktrace: [1] pipeline_error @ ./process.jl:565 [inlined] [2] run(::Cmd; wait::Bool) @ Base ./process.jl:480 [3] run @ ./process.jl:477 [inlined] [4] run_lamem(ParamFile::String, cores::Int64, args::String; wait::Bool, deactivate_multithreads::Bool) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem.jl:79 [5] run_lamem(ParamFile::String, cores::Int64, args::String) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem.jl:50 [6] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runLaMEM.jl:36 [inlined] [7] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [8] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runLaMEM.jl:7 [9] include(fname::String) @ Base.MainInclude ./client.jl:487 [10] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:7 [inlined] [11] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [12] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [13] include(fname::String) @ Base.MainInclude ./client.jl:487 [14] top-level scope @ none:6 Saved file: test_data.vts Saved file: test_data_phase.vts read LaMEM output: Error During Test at /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/read_timestep.jl:5 Got exception outside of a @test SystemError: opening file "/home/pkgeval/.julia/packages/LaMEM/qcV9I/test/PlumeLithosphereInteraction_passive_tracers.pvd": No such file or directory Stacktrace: [1] systemerror(p::String, errno::Int32; extrainfo::Nothing) @ Base ./error.jl:176 [2] systemerror @ ./error.jl:175 [inlined] [3] open(fname::String; lock::Bool, read::Nothing, write::Nothing, create::Nothing, truncate::Nothing, append::Nothing) @ Base ./iostream.jl:293 [4] open @ ./iostream.jl:275 [inlined] [5] open(f::Base.var"#447#448"{@Kwargs{}}, args::String; kwargs::@Kwargs{}) @ Base ./io.jl:394 [6] open @ ./io.jl:393 [inlined] [7] #readlines#446 @ ./io.jl:599 [inlined] [8] readlines @ ./io.jl:598 [inlined] [9] readPVD(FileName::String) @ LaMEM.IO_functions ~/.julia/packages/LaMEM/qcV9I/src/read_timestep.jl:381 [10] read_LaMEM_simulation(FileName::String, DirName::String; phase::Bool, surf::Bool, passive_tracers::Bool) @ LaMEM.IO_functions ~/.julia/packages/LaMEM/qcV9I/src/read_timestep.jl:591 [11] read_LaMEM_simulation @ ~/.julia/packages/LaMEM/qcV9I/src/read_timestep.jl:579 [inlined] [12] read_LaMEM_timestep(FileName::String, TimeStep::Int64, DirName::String; fields::Nothing, phase::Bool, surf::Bool, passive_tracers::Bool, last::Bool) @ LaMEM.IO_functions ~/.julia/packages/LaMEM/qcV9I/src/read_timestep.jl:548 [13] read_LaMEM_timestep @ ~/.julia/packages/LaMEM/qcV9I/src/read_timestep.jl:546 [inlined] [14] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/read_timestep.jl:51 [inlined] [15] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [16] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/read_timestep.jl:8 [17] include(fname::String) @ Base.MainInclude ./client.jl:487 [18] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:8 [inlined] [19] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [20] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [21] include(fname::String) @ Base.MainInclude ./client.jl:487 [22] top-level scope @ none:6 No partitioning file required for 1 core model setup run lamem mode save grid test: Error During Test at /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/run_lamem_save_grid_test.jl:3 Got exception outside of a @test MethodError: no method matching length(::Nothing) Closest candidates are: length(!Matched::Base.AsyncGenerator) @ Base asyncmap.jl:390 length(!Matched::Markdown.MD) @ Markdown /opt/julia/share/julia/stdlib/v1.10/Markdown/src/parse/parse.jl:28 length(!Matched::ReadVTK.PVTKData) @ ReadVTK ~/.julia/packages/ReadVTK/cMvIT/src/ReadVTK.jl:556 ... Stacktrace: [1] run_lamem_save_grid(ParamFile::String, cores::Int64; verbose::Bool, directory::String) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:92 [2] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/run_lamem_save_grid_test.jl:11 [inlined] [3] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [4] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/run_lamem_save_grid_test.jl:5 [5] include(fname::String) @ Base.MainInclude ./client.jl:487 [6] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:9 [inlined] [7] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [8] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [9] include(fname::String) @ Base.MainInclude ./client.jl:487 [10] top-level scope @ none:6 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 1000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 2 Time step : 1. [Myr] Minimum time step : 0.2 [Myr] Maximum time step : 10. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [24, 24, 24] Number of cells : 13824 Number of faces : 43200 Maximum cell aspect ratio : 2.00000 Lower coordinate bounds [bx, by, bz] : [-1., -1., -1.] Upper coordinate bounds [ex, ey, ez] : [1., 1., 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 1 -- sphere (dens) : rho = 3200. [kg/m^3] (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.125674 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Preconditioner type : coupled Galerkin geometric multigrid Global coarse grid [nx,ny,nz] : [12, 12, 12] Local coarse grid [nx,ny,nz] : [12, 12, 12] Number of multigrid levels : 2 -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : multigrid Multigrid smoother levels KSP : chebyshev Multigrid smoother levels PC : sor Number of smoothening steps : 10 Coarse level KSP : preonly Coarse level PC : lu Coarse level solver package : (null) -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 3.403291317974e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 6 1 SNES Function norm 1.464986509563e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 22.4467 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.270115706137e-06 |Div|_2 = 6.060118300339e-05 Momentum: |mRes|_2 = 1.463732547230e-03 -------------------------------------------------------------------------- Saving output ... done (0.00902698 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 1.00000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.788630241324e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 16 1 SNES Function norm 3.498272686734e-03 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 22.2118 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.403141994493e-05 |Div|_2 = 9.116365292802e-05 Momentum: |mRes|_2 = 3.497084639973e-03 -------------------------------------------------------------------------- Actual time step : 1.10000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 5.6598e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00718616 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 45.6181 (sec) -------------------------------------------------------------------------- | FineGrid | Cores | Nodes | CoarseGrid | CoaCores | Levels | SNES | KSP | TotalTime | CoarseTime | MemNode_Gb | Filename | | --------------- | ----- | ----- | ------------ | -------- | ------ | ---- | --- | --------- | ---------- | ---------- | -------------------------------- | | [512, 256, 256] | 512 | - | [32, 16, 16] | 512 | 5 | 1 | 72 | 26.26 | 9.9174 | - | input_files/128_cores_104812.txt | Saved file: Model3D.vts filesize compression: Error During Test at /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/test_compression.jl:6 Got exception outside of a @test MethodError: no method matching length(::Nothing) Closest candidates are: length(!Matched::Base.AsyncGenerator) @ Base asyncmap.jl:390 length(!Matched::Markdown.MD) @ Markdown /opt/julia/share/julia/stdlib/v1.10/Markdown/src/parse/parse.jl:28 length(!Matched::ReadVTK.PVTKData) @ ReadVTK ~/.julia/packages/ReadVTK/cMvIT/src/ReadVTK.jl:556 ... Stacktrace: [1] run_lamem_save_grid(ParamFile::String, cores::Int64; verbose::Bool, directory::String) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:92 [2] run_lamem_save_grid @ ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:76 [inlined] [3] create_initialsetup(model::Model, cores::Int64, args::String; verbose::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:296 [4] create_initialsetup @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:273 [inlined] [5] run_lamem(model::Model, cores::Int64, args::String; wait::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:200 [6] run_lamem @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [inlined] [7] run_lamem(model::Model, cores::Int64) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [8] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_compression.jl:23 [inlined] [9] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [10] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/test_compression.jl:7 [11] include(fname::String) @ Base.MainInclude ./client.jl:487 [12] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:12 [inlined] [13] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [14] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [15] include(fname::String) @ Base.MainInclude ./client.jl:487 [16] top-level scope @ none:6 rheology = Phase 0 (matrix): rho = 3000.0 eta = 1.0e20 ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000694194 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00218413 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.000879801 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.855164213029e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.268605661839e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00146425 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.368738149400e-19 Momentum: |mRes|_2 = 1.268605661765e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5228e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000628024 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012823718e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.590416869505e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00112328 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.533293416683e-19 Momentum: |mRes|_2 = 1.590416869431e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4380e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000846072 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0233747 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.002f0, 0.002f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000876861 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00223278 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.000661483 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.192074820223e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve did not converge due to DIVERGED_BREAKDOWN iterations 30 1 SNES Function norm 1.996269872508e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00240118 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.385244779468e-17 |Div|_2 = 6.076331735643e-17 Momentum: |mRes|_2 = 1.996269780031e-13 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5609e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000868742 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529035026473e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.131007585929e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00110343 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.533293416683e-18 Momentum: |mRes|_2 = 2.131007580413e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3172e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000573344 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.024486 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.02f0, 0.02f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000744962 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00183807 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.000703813 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.900625156863e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.193054234538e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00104102 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 9.501471788263e-18 Momentum: |mRes|_2 = 1.193053856190e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.6028e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00110876 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.531321061608e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.505745134977e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00100047 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.201851678990e-17 Momentum: |mRes|_2 = 1.505744655332e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3708e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000533325 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0189154 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.2f0, 0.2f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000731874 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00180102 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000759173 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.408582653022e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.331272599822e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00100877 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.468687011488e-16 Momentum: |mRes|_2 = 2.331226336186e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4823e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000710723 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.744843946556e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.645921959749e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00110156 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.642041997679e-16 Momentum: |mRes|_2 = 1.645840049152e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5271e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000976391 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.019002 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (2.0f0, 2.0f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000762213 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00183921 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.000735693 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.007037800205e-09 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve did not converge due to DIVERGED_BREAKDOWN iterations 60 1 SNES Function norm 1.382743448093e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00331911 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 7.771561172376e-15 |Div|_2 = 1.956356625210e-14 Momentum: |mRes|_2 = 1.382743434253e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5708e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000781533 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.543884777184e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.658946166339e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0011383 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.285176065878e-15 Momentum: |mRes|_2 = 1.658896384666e-13 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4134e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000655574 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0213194 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (20.0f0, 20.0f0) τ_linear = [0.0020000000949949026, 0.019999999552965164, 0.20000000298023224, 2.0, 20.0] τ_anal = [0.002, 0.02, 0.20000000000000004, 2.0, 20.0] ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Tumut_Pond_Serpentinite-Raleigh_Paterson_1965 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000991491 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00182743 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.000894312 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.732070997253e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.676863757548e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00138196 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.065758146821e-20 |Div|_2 = 1.355252715607e-19 Momentum: |mRes|_2 = 1.676863757493e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4727e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000674894 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012298712e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.344047801612e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00128838 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.714274154578e-19 Momentum: |mRes|_2 = 1.344047801612e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3838e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000680914 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0225031 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00066601264f0, 0.00066601264f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Tumut_Pond_Serpentinite-Raleigh_Paterson_1965 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000961941 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00179712 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.001 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.538538587820e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 4 1 SNES Function norm 1.914610129611e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00150844 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.673617379884e-19 |Div|_2 = 2.395080882144e-18 Momentum: |mRes|_2 = 1.914610114630e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.6803e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000710873 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012236651e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.060973992895e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00120927 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.761620017532e-18 Momentum: |mRes|_2 = 3.060973992895e-11 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4037e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000739533 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.023084 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.001515742f0, 0.001515742f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Tumut_Pond_Serpentinite-Raleigh_Paterson_1965 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000924221 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00229066 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.00135325 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.574877395261e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.864620915674e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0011418 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.201851678990e-17 Momentum: |mRes|_2 = 1.864620528344e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5466e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000638594 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529027476038e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.967399903915e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00117429 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.321126039445e-17 Momentum: |mRes|_2 = 6.967399903915e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5291e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00126605 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0233089 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0034495955f0, 0.0034495955f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Tumut_Pond_Serpentinite-Raleigh_Paterson_1965 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000785902 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00236351 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000738353 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.757947606630e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.193302093907e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00102503 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.163336342344e-17 |Div|_2 = 1.455514664586e-16 Momentum: |mRes|_2 = 3.193268922383e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5080e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000824962 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.530525989706e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.585686169509e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00147274 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.163336342344e-17 |Div|_2 = 1.594436429147e-16 Momentum: |mRes|_2 = 1.585686169509e-08 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4133e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000764133 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0228724 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.007850748f0, 0.007850748f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Tumut_Pond_Serpentinite-Raleigh_Paterson_1965 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000751043 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00192417 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.000893711 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.721068317499e-10 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.327026433622e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00170787 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.514142333402e-15 Momentum: |mRes|_2 = 6.325214401243e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4446e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000893591 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.673510065039e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.608776481627e-07 1 MMFD ||F||/||F0||=2.156412e-03 Linear js_ solve converged due to CONVERGED_RTOL iterations 3 2 SNES Function norm 7.337506294466e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00331546 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.881784197001e-16 |Div|_2 = 2.717212732710e-15 Momentum: |mRes|_2 = 7.332473400632e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.6243e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000707353 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0253478 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.017867092f0, 0.017867092f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000742403 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00183743 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.00104416 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.732070997253e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.676863757548e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00122903 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.065758146821e-20 |Div|_2 = 1.355252715607e-19 Momentum: |mRes|_2 = 1.676863757493e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4251e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000824032 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012298712e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.344047801612e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00145939 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.714274154578e-19 Momentum: |mRes|_2 = 1.344047801612e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3954e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000736523 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0216878 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00066601264f0, 0.00066601264f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000692583 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00203486 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.000642934 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.536173268120e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve did not converge due to DIVERGED_BREAKDOWN iterations 60 1 SNES Function norm 1.558141012496e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00350542 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.531965080989e-17 |Div|_2 = 1.438840450765e-16 Momentum: |mRes|_2 = 1.558140348159e-13 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5474e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000581305 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012312017e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.061084525594e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00110915 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.505213034913e-19 |Div|_2 = 1.707403288634e-18 Momentum: |mRes|_2 = 3.061084525594e-11 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.9607e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000786822 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.023444 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.001515742f0, 0.001515742f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000685023 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00184088 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.000913431 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.575177734083e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.883753867839e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00144836 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.250926888277e-17 Momentum: |mRes|_2 = 1.883753452494e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.6277e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000616125 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529027475860e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.967410109455e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00141507 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.409296014026e-17 Momentum: |mRes|_2 = 6.967410109455e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3727e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000792232 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.021965 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0034495955f0, 0.0034495955f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000735853 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00211726 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000630974 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.757910772242e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.290919515336e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00118999 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.163336342344e-17 |Div|_2 = 1.455514664586e-16 Momentum: |mRes|_2 = 3.290887327778e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4585e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000643234 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.530525989717e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.585686263715e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00116478 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.594436429147e-16 Momentum: |mRes|_2 = 1.585686263715e-08 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3934e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000610935 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0216429 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.007850748f0, 0.007850748f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 4.0257e-23 [1/Pa^n/s] En = 66000. [J/mol] n = 2.8 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000873342 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00169166 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.000937931 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.721073818982e-10 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.206221377386e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00110725 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.489520491948e-15 Momentum: |mRes|_2 = 6.204433662484e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4581e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000791922 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.673510065031e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.608776465926e-07 1 MMFD ||F||/||F0||=2.156412e-03 Linear js_ solve converged due to CONVERGED_RTOL iterations 3 2 SNES Function norm 7.323744093763e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00279594 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.881784197001e-16 |Div|_2 = 2.717212732710e-15 Momentum: |mRes|_2 = 7.318701736004e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3814e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000720483 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0230539 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.017867092f0, 0.017867092f0) τ_num1 = [0.0006660126382485032, 0.0015157420421019197, 0.003449595533311367, 0.007850747555494308, 0.017867092043161392] τ_num2 = [0.0006660126382485032, 0.0015157420421019197, 0.003449595533311367, 0.007850747555494308, 0.017867092043161392] ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Dry_Olivine-Ranalli_1995 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000839942 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00201499 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.000827532 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.999601326924e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.245639208773e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00101627 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 2.019281067463e-19 Momentum: |mRes|_2 = 2.245639208773e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3975e-04 s -------------------------------------------------------------------------- Saving output ... done (0.0010802 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529983614622e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 4 1 SNES Function norm 6.355036424707e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00127152 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.151964808266e-18 |Div|_2 = 3.319788279835e-18 Momentum: |mRes|_2 = 6.355036424707e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5985e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000903481 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0224222 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.28025904f0, 0.28025904f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Dry_Olivine-Ranalli_1995 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000663034 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00198732 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.000712734 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.166485402623e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve did not converge due to DIVERGED_BREAKDOWN iterations 30 1 SNES Function norm 2.672158256062e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00241932 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.035766082959e-18 |Div|_2 = 7.132699033577e-18 Momentum: |mRes|_2 = 2.672158256062e-11 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.6797e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000574285 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.532640059961e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.214267533388e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00153713 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.433061127045e-14 |Div|_2 = 1.730949475871e-13 Momentum: |mRes|_2 = 1.214267533264e-08 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5947e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000543455 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0221709 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.5410955f0, 0.5410955f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Dry_Olivine-Ranalli_1995 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000664014 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00180285 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.000830112 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.042474277838e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 3.155075594917e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.000982501 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.717288626685e-17 Momentum: |mRes|_2 = 3.155075594871e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4734e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000714503 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.542469102073e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.344382818817e-07 1 PICARD ||F||/||F0||=1.519890e-01 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 2 SNES Function norm 1.130031258622e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00182519 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.488670298144e-13 |Div|_2 = 4.858601896386e-13 Momentum: |mRes|_2 = 1.130020813724e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4299e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00119329 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0196605 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (1.0446918f0, 1.0446918f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Dry_Olivine-Ranalli_1995 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000697553 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00192616 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000655134 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.784431980867e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.724013332527e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00124257 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.163336342344e-17 |Div|_2 = 1.481742263891e-16 Momentum: |mRes|_2 = 7.724013331105e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4731e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000480586 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.580001929353e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.526537046699e-06 1 PICARD ||F||/||F0||=2.864893e-01 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.764898326264e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00218135 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.163336342344e-17 |Div|_2 = 1.594436429147e-16 Momentum: |mRes|_2 = 2.764898321667e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3774e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000566404 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0211446 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (2.0169842f0, 2.0169842f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix dislocation creep profile: Dry_Olivine-Ranalli_1995 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000730153 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0017747 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.00171772 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.729160028127e-10 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 4 1 SNES Function norm 1.853669481181e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00129397 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.534358746845e-15 Momentum: |mRes|_2 = 1.853669474831e-11 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4430e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000644334 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.836925303655e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.739374791909e-05 1 PICARD ||F||/||F0||=4.757610e-01 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.216630214054e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00205314 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.294731409828e-15 Momentum: |mRes|_2 = 1.216630213985e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4011e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000685113 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0229887 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (3.8941867f0, 3.8941867f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000764683 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00184205 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.000787932 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.999796133868e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.245866084546e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00106618 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.131516293641e-20 |Div|_2 = 2.235140038341e-19 Momentum: |mRes|_2 = 2.245866084546e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4738e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000623144 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529983701625e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 4 1 SNES Function norm 6.293315848640e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00134797 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.065758146821e-19 |Div|_2 = 1.078767540907e-18 Momentum: |mRes|_2 = 6.293315848640e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4001e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000600755 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.019575 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.28025904f0, 0.28025904f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000656333 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00180934 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.000627744 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.166894085041e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve did not converge due to DIVERGED_BREAKDOWN iterations 30 1 SNES Function norm 2.774742659001e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00243924 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.100818213309e-17 |Div|_2 = 7.866915976262e-17 Momentum: |mRes|_2 = 2.774742657886e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4863e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000725053 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.532629675324e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.214267305153e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00161957 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.433017758958e-14 |Div|_2 = 1.730935003775e-13 Momentum: |mRes|_2 = 1.214267305030e-08 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4916e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000467425 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0207947 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.5410955f0, 0.5410955f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000740963 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00180559 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.000642924 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.042468515420e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 3.155420570896e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00098331 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.938893903907e-18 |Div|_2 = 1.734723475977e-17 Momentum: |mRes|_2 = 3.155420570848e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5502e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000694364 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.542469101177e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.344382790545e-07 1 PICARD ||F||/||F0||=1.519890e-01 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 2 SNES Function norm 1.130046859846e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00203465 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.488670298144e-13 |Div|_2 = 4.858573569975e-13 Momentum: |mRes|_2 = 1.130036415214e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4614e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000636384 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.020429 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (1.0446918f0, 1.0446918f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000745393 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00180864 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000724643 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.784306707115e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.724377954918e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0010711 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.653729276826e-16 Momentum: |mRes|_2 = 7.724377953147e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4808e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000542445 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.580001929359e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.526537050781e-06 1 PICARD ||F||/||F0||=2.864893e-01 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.765021558113e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00185812 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.766354016019e-16 Momentum: |mRes|_2 = 2.765021552471e-12 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4351e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000540505 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0190809 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (2.0169842f0, 2.0169842f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.48058e-16 [1/Pa^n/s] En = 532000. [J/mol] n = 3.5 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000727523 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00203867 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.000750013 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.729169044886e-10 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 6 1 SNES Function norm 3.928326031489e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00154196 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.221245327088e-15 |Div|_2 = 3.265263874808e-15 Momentum: |mRes|_2 = 3.928326017919e-11 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3868e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000751513 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.836925357109e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.739374791572e-05 1 PICARD ||F||/||F0||=4.757610e-01 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.222911451447e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00251207 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.701939668836e-15 Momentum: |mRes|_2 = 1.222911451328e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3634e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000895481 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0224435 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (3.8941867f0, 3.8941867f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology dislocation creep profile: Wet_Quarzite-Ueda_et_al_2008 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000952481 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0020729 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.000865302 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.733398697939e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.470853950173e-15 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00105323 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.196926789768e-19 Momentum: |mRes|_2 = 8.470853949328e-15 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4795e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000757313 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012429987e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.141630061900e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00138734 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.735570302230e-19 Momentum: |mRes|_2 = 5.141630061900e-13 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4087e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000783422 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0214254 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00029242327f0, 0.00029242327f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology dislocation creep profile: Wet_Quarzite-Ueda_et_al_2008 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000624294 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00195042 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.00105657 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.537125835156e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 4 1 SNES Function norm 1.773537767839e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00126588 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.915082863629e-18 Momentum: |mRes|_2 = 1.773537757500e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4390e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000923401 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012259639e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.412456206055e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0011307 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.622685226975e-18 Momentum: |mRes|_2 = 1.412456206055e-11 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4104e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000792553 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0201607 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00079578283f0, 0.00079578283f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology dislocation creep profile: Wet_Quarzite-Ueda_et_al_2008 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000738153 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00196099 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.00104201 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.575355648999e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.497363577973e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0010475 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.365922630907e-17 Momentum: |mRes|_2 = 1.497362954963e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4601e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000940601 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529027377354e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.845756209644e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00112774 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.226634733347e-17 Momentum: |mRes|_2 = 3.845756209644e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3607e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000595294 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0197359 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0021655946f0, 0.0021655946f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology dislocation creep profile: Wet_Quarzite-Ueda_et_al_2008 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000683963 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00179939 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.00146498 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.758143280721e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.557709372943e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0011463 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.775557561563e-17 |Div|_2 = 1.316562550716e-16 Momentum: |mRes|_2 = 2.557675488163e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5192e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000438116 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.530525703377e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.046566607204e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00132267 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.455514664586e-16 Momentum: |mRes|_2 = 1.046566607204e-08 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3969e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000713304 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0200452 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0058933166f0, 0.0058933166f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology dislocation creep profile: Wet_Quarzite-Ueda_et_al_2008 (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000766943 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00196094 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.00222645 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.721067804689e-10 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.655639651614e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00104905 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.336885555458e-15 Momentum: |mRes|_2 = 5.654059359348e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4190e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000563024 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.673510051971e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.848062535603e-07 1 MMFD ||F||/||F0||=1.701850e-03 Linear js_ solve converged due to CONVERGED_RTOL iterations 3 2 SNES Function norm 4.525074343373e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.00275131 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.881784197001e-16 |Div|_2 = 2.383749925626e-15 Momentum: |mRes|_2 = 4.518791340168e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3597e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000793383 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0228247 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.016037712f0, 0.016037712f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000745753 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00174667 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.0011513 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.733398697939e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.470853950173e-15 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00132548 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.196926789768e-19 Momentum: |mRes|_2 = 8.470853949328e-15 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4728e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000678213 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012429987e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.141630061900e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00111341 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.735570302230e-19 Momentum: |mRes|_2 = 5.141630061900e-13 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3896e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000704014 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0213953 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00029242327f0, 0.00029242327f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000767593 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00180541 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.00104053 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.537750739444e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 5 1 SNES Function norm 2.281739069316e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00119014 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.301042606983e-18 |Div|_2 = 4.215859886717e-18 Momentum: |mRes|_2 = 2.281739030369e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4487e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000759732 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012268549e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.412613368437e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00123309 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.502314598737e-18 Momentum: |mRes|_2 = 1.412613368437e-11 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3678e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000791943 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0218198 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00079578283f0, 0.00079578283f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.00101372 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00221252 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.000793772 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.575355648999e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.497363577973e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00100337 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.365922630907e-17 Momentum: |mRes|_2 = 1.497362954963e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4438e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000799792 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529027377354e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.845756209644e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00123907 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.226634733347e-17 Momentum: |mRes|_2 = 3.845756209644e-10 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3887e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000765453 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.021291 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0021655946f0, 0.0021655946f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000784832 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00328324 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000767823 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.758143280721e-11 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.557709372943e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00107667 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.775557561563e-17 |Div|_2 = 1.316562550716e-16 Momentum: |mRes|_2 = 2.557675488163e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.6942e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000598944 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.530525703371e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.046566599353e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00115435 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.468687011488e-16 Momentum: |mRes|_2 = 1.046566599353e-08 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 8.5667e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000673153 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0237711 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0058933166f0, 0.0058933166f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (disl) : Bn = 1.53539e-17 [1/Pa^n/s] En = 154000. [J/mol] n = 2.3 [ ] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000757152 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00255792 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.000851992 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.721067804689e-10 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.613639044842e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00108658 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.336885555458e-15 Momentum: |mRes|_2 = 5.612046925667e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3953e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000672513 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.673510051970e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.848062534818e-07 1 MMFD ||F||/||F0||=1.701850e-03 Linear js_ solve converged due to CONVERGED_RTOL iterations 3 2 SNES Function norm 4.645808098495e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0029892 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.790180836525e-15 Momentum: |mRes|_2 = 4.642357742975e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4154e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000709094 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0229738 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.016037712f0, 0.016037712f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology diffusion creep profile : Dry_Plagioclase_RybackiDresen_2000 (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88835 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000749412 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00215162 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.000692963 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643776193159e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.468632384106e-15 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00106725 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.496925551340e-19 Momentum: |mRes|_2 = 1.468632376477e-15 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5132e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000667314 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012493598e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.741239287980e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00109647 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.509145554517e-19 Momentum: |mRes|_2 = 1.741239287915e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3949e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000692404 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.02119 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (1.6801193f-6, 1.8722288f-6) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology diffusion creep profile : Dry_Plagioclase_RybackiDresen_2000 (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88835 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000762313 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00196372 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.00103302 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643775949684e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.290700433835e-15 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00105104 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.651407549307e-18 Momentum: |mRes|_2 = 6.290700217074e-15 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4997e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000878402 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012083211e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.049795325108e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00146069 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.707403288634e-18 Momentum: |mRes|_2 = 2.049795317997e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 3.0136e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000801072 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0210438 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (1.6801194f-5, 1.8722289f-5) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology diffusion creep profile : Dry_Plagioclase_RybackiDresen_2000 (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88835 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000699893 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0018087 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.000832912 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643775888174e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.509971681121e-15 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.000944711 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.387778780781e-17 Momentum: |mRes|_2 = 4.509950329163e-15 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.9756e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000770333 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529025548536e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.248139529364e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00114534 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.250926888277e-17 Momentum: |mRes|_2 = 1.248138902504e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3939e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00112391 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.470815 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00016801193f0, 0.00018722289f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology diffusion creep profile : Dry_Plagioclase_RybackiDresen_2000 (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88835 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000857431 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00213217 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000885662 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643775926557e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.453753162213e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.000956991 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.241267076624e-16 Momentum: |mRes|_2 = 1.453700169309e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4522e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00147148 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.530507771875e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.935424250481e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00144579 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.551115123126e-17 |Div|_2 = 1.699674944388e-16 Momentum: |mRes|_2 = 1.935349616958e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3849e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00524596 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0298827 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0016801193f0, 0.0018722288f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology diffusion creep profile : Dry_Plagioclase_RybackiDresen_2000 (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88835 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000721633 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00188113 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.00137048 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643775934397e-03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.487533228243e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00133393 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.373270039557e-15 Momentum: |mRes|_2 = 1.481180744917e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.6153e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000985341 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.673362537378e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.370876409381e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00116884 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.505979781574e-15 Momentum: |mRes|_2 = 2.366088586156e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5426e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000866282 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0225369 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.016801193f0, 0.01872228f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88839 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000771022 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404679741346e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.855164213029e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00210945 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.219727444046e-18 |Div|_2 = 4.351986372410e-18 Momentum: |mRes|_2 = 1.855164212518e-13 -------------------------------------------------------------------------- Saving output ... done (0.000989601 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643742963921e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.318548988781e-15 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00107463 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.421010862428e-20 |Div|_2 = 1.580482678012e-19 Momentum: |mRes|_2 = 4.318548985889e-15 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4817e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000714213 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529013223529e-08 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.854501415834e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00108636 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.065758146821e-20 |Div|_2 = 1.484604966916e-19 Momentum: |mRes|_2 = 1.854501415775e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.6722e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000801643 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0205305 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (1.6800853f-6, 1.8721911f-6) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88839 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000721123 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.404745638765e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.192074820223e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00182807 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.107298248878e-18 |Div|_2 = 3.680670766906e-17 Momentum: |mRes|_2 = 8.192074811954e-13 -------------------------------------------------------------------------- Saving output ... done (0.000911202 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643742768540e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.768238622152e-15 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00105151 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.505213034913e-19 |Div|_2 = 1.761620017532e-18 Momentum: |mRes|_2 = 4.768238296738e-15 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4719e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000709743 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529012070155e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.494164679288e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0011367 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.336808689942e-19 |Div|_2 = 1.707403288634e-18 Momentum: |mRes|_2 = 1.494164669533e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5392e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000666484 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0192602 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (1.6800854f-5, 1.872191f-5) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88839 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000789372 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 4.411330409550e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.900625156863e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00187461 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.367506770275e-17 |Div|_2 = 3.652489012102e-16 Momentum: |mRes|_2 = 7.900625148420e-12 -------------------------------------------------------------------------- Saving output ... done (0.000970171 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643742707915e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.303083294658e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00108336 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.097135458930e-17 Momentum: |mRes|_2 = 1.303082832789e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5864e-04 s -------------------------------------------------------------------------- Saving output ... done (0.00129948 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.529025552216e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.737093484513e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00111072 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.469446951954e-18 |Div|_2 = 1.430489624538e-17 Momentum: |mRes|_2 = 1.737092895512e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3944e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000846292 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0272169 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.00016800854f0, 0.0001872191f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88839 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000811662 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 5.026432132460e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.408582653022e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00204765 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.992007221626e-16 |Div|_2 = 4.055212130474e-15 Momentum: |mRes|_2 = 7.408582641923e-11 -------------------------------------------------------------------------- Saving output ... done (0.000927201 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643742746428e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.276251701487e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00119946 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.163336342344e-17 |Div|_2 = 1.401587864986e-16 Momentum: |mRes|_2 = 1.276174737524e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.7406e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000833783 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.530507773124e-05 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.728004276619e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0012738 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.163336342344e-17 |Div|_2 = 1.455514664586e-16 Momentum: |mRes|_2 = 1.727942975830e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3675e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000640243 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0209952 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.0016800853f0, 0.001872191f0) ┌ Warning: Your initial `Temp` grid is constant, as is your initial `Phases` grid. │ Is that intended? │ In most cases, you would want to set some variability in the initial conditions, │ for example with the `GeophysicalModelGenerator` function `add_sphere!(model,cen=(0.0,0.0,0.0), radius=(0.15, ))` └ @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/ErrorChecking.jl:22 Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 100. [Myr] Maximum number of steps : 2 Time step : 1e-06 [Myr] Minimum time step : 1e-10 [Myr] Maximum time step : 1. [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [8, 1, 8] Number of cells : 64 Number of faces : 272 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -0.125, -1.] Upper coordinate bounds [ex, ey, ez] : [1., 0.125, 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- rheology (dens) : rho = 3000. [kg/m^3] (diff) : Bd = 1.88839 [1/Pa/s] Ed = 460000. [J/mol] Vd = 2.4e-05 [m^3/mol] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Number of x-background strain rate periods : 1 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Universal gas constant : 8.31446 [J/mol/K] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.000703594 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 2.461266787616e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.007037800205e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00189056 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.043609643148e-14 |Div|_2 = 3.386489617389e-14 Momentum: |mRes|_2 = 1.007037799635e-09 -------------------------------------------------------------------------- Saving output ... done (0.000799092 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.00000100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.643742754277e-03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.380948806640e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00105756 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.368774871884e-15 Momentum: |mRes|_2 = 1.374148521835e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.5060e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000679544 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.00000110 [Myr] Tentative time step : 0.00000110 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.673362539976e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.931460429801e-14 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.00116725 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.440892098501e-16 |Div|_2 = 1.382216518796e-15 Momentum: |mRes|_2 = 2.928199963534e-14 -------------------------------------------------------------------------- Actual time step : 0.00000 [Myr] -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4306e-04 s -------------------------------------------------------------------------- Saving output ... done (0.000735183 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 0.0186799 (sec) -------------------------------------------------------------------------- extrema(data.fields.j2_dev_stress) = (0.016800852f0, 0.018721903f0) Saved file: Model3D.vts Saved file: Model3D.vts Subduction3D: Error During Test at /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:13 Got exception outside of a @test LoadError: MethodError: no method matching length(::Nothing) Closest candidates are: length(!Matched::Base.AsyncGenerator) @ Base asyncmap.jl:390 length(!Matched::Markdown.MD) @ Markdown /opt/julia/share/julia/stdlib/v1.10/Markdown/src/parse/parse.jl:28 length(!Matched::ReadVTK.PVTKData) @ ReadVTK ~/.julia/packages/ReadVTK/cMvIT/src/ReadVTK.jl:556 ... Stacktrace: [1] run_lamem_save_grid(ParamFile::String, cores::Int64; verbose::Bool, directory::String) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:92 [2] run_lamem_save_grid @ ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:76 [inlined] [3] create_initialsetup(model::Model, cores::Int64, args::String; verbose::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:296 [4] create_initialsetup @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:273 [inlined] [5] run_lamem(model::Model, cores::Int64, args::String; wait::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:200 [6] run_lamem @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [inlined] [7] run_lamem(model::Model, cores::Int64) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [8] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/example_scripts/Subduction3D.jl:99 [9] include(fname::String) @ Base.MainInclude ./client.jl:487 [10] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:15 [inlined] [11] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [12] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:14 [inlined] [13] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [14] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:6 [15] include(fname::String) @ Base.MainInclude ./client.jl:487 [16] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:14 [inlined] [17] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [18] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [19] include(fname::String) @ Base.MainInclude ./client.jl:487 [20] top-level scope @ none:6 in expression starting at /home/pkgeval/.julia/packages/LaMEM/qcV9I/example_scripts/Subduction3D.jl:91 caused by: MethodError: no method matching length(::Nothing) Closest candidates are: length(!Matched::Base.AsyncGenerator) @ Base asyncmap.jl:390 length(!Matched::Markdown.MD) @ Markdown /opt/julia/share/julia/stdlib/v1.10/Markdown/src/parse/parse.jl:28 length(!Matched::ReadVTK.PVTKData) @ ReadVTK ~/.julia/packages/ReadVTK/cMvIT/src/ReadVTK.jl:556 ... Stacktrace: [1] run_lamem_save_grid(ParamFile::String, cores::Int64; verbose::Bool, directory::String) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:92 [2] run_lamem_save_grid @ ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:76 [inlined] [3] create_initialsetup(model::Model, cores::Int64, args::String; verbose::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:296 [4] create_initialsetup @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:273 [inlined] [5] run_lamem(model::Model, cores::Int64, args::String; wait::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:200 [6] run_lamem(model::Model, cores::Int64, args::String) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [7] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/example_scripts/Subduction3D.jl:94 [8] include(fname::String) @ Base.MainInclude ./client.jl:487 [9] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:15 [inlined] [10] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [11] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:14 [inlined] [12] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [13] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:6 [14] include(fname::String) @ Base.MainInclude ./client.jl:487 [15] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:14 [inlined] [16] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [17] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [18] include(fname::String) @ Base.MainInclude ./client.jl:487 [19] top-level scope @ none:6 julia: /source/src/subtype.c:4817: sub_msp: Assertion `obvious_sub == 3 || obvious_sub == subtype || ijl_has_free_typevars(x) || ijl_has_free_typevars(y)' failed. [553] signal (6.-6): Aborted in expression starting at /home/pkgeval/.julia/packages/Makie/Vn16E/precompile/shared-precompile.jl:98 unknown function (ip: 0x73c3c62daebc) gsignal at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) abort at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) unknown function (ip: 0x73c3c6276394) __assert_fail at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) sub_msp at /source/src/subtype.c:4817 type_morespecific_ at /source/src/subtype.c:5075 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5185 type_morespecific_ at /source/src/subtype.c:5143 type_morespecific_ at /source/src/subtype.c:5240 type_morespecific_ at /source/src/subtype.c:5237 tuple_morespecific at /source/src/subtype.c:4879 [inlined] type_morespecific_ at /source/src/subtype.c:5061 ml_matches at /source/src/gf.c:3702 ml_matches at /source/src/gf.c:3589 [inlined] _gf_invoke_lookup at /source/src/gf.c:3093 [inlined] jl_mt_assoc_by_type at /source/src/gf.c:1463 jl_lookup_generic_ at /source/src/gf.c:3050 [inlined] ijl_apply_generic at /source/src/gf.c:3075 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 _register_argument_conversions! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:496 register_arguments! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:382 [inlined] Plot at /home/pkgeval/.julia/packages/Makie/Vn16E/src/compute-plots.jl:769 unknown function (ip: 0x73c3a377b12c) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _create_plot! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/figureplotting.jl:416 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 #poly!#78 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/recipes.jl:534 poly! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/recipes.jl:532 [inlined] initialize_block! at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks/toggle.jl:38 unknown function (ip: 0x73c3a376dce5) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_apply at /source/src/builtins.c:768 #_block#1911 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:405 _block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:321 [inlined] #_block#1910 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:266 [inlined] _block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:265 [inlined] #_#1908 at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:242 [inlined] Block at /home/pkgeval/.julia/packages/Makie/Vn16E/src/makielayout/blocks.jl:241 unknown function (ip: 0x73c3a3768265) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 jfptr_include_46673.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] jl_f__call_latest at /source/src/builtins.c:812 include at /home/pkgeval/.julia/packages/Makie/Vn16E/src/Makie.jl:1 [inlined] macro expansion at /home/pkgeval/.julia/packages/Makie/Vn16E/src/precompiles.jl:31 [inlined] macro expansion at /home/pkgeval/.julia/packages/PrecompileTools/L8A3n/src/workloads.jl:78 [inlined] top-level scope at /home/pkgeval/.julia/packages/Makie/Vn16E/src/precompiles.jl:23 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_invoke at /source/src/gf.c:2904 jl_toplevel_eval_flex at /source/src/toplevel.c:925 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 jfptr_include_46673.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] jl_f__call_latest at /source/src/builtins.c:812 include at /home/pkgeval/.julia/packages/Makie/Vn16E/src/Makie.jl:1 unknown function (ip: 0x73c3c5149725) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_eval_module_expr at /source/src/toplevel.c:215 [inlined] jl_toplevel_eval_flex at /source/src/toplevel.c:736 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 _include at ./loading.jl:2209 include at ./Base.jl:495 [inlined] include_package_for_output at ./loading.jl:2295 jfptr_include_package_for_output_81425.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] do_call at /source/src/interpreter.c:126 eval_value at /source/src/interpreter.c:223 eval_stmt_value at /source/src/interpreter.c:174 [inlined] eval_body at /source/src/interpreter.c:635 jl_interpret_toplevel_thunk at /source/src/interpreter.c:775 jl_toplevel_eval_flex at /source/src/toplevel.c:934 jl_toplevel_eval_flex at /source/src/toplevel.c:877 ijl_toplevel_eval_in at /source/src/toplevel.c:985 eval at ./boot.jl:385 [inlined] include_string at ./loading.jl:2149 include_string at ./loading.jl:2159 [inlined] exec_options at ./client.jl:314 _start at ./client.jl:550 jfptr__start_83133.1 at /opt/julia/lib/julia/sys.so (unknown line) _jl_invoke at /source/src/gf.c:2878 [inlined] ijl_apply_generic at /source/src/gf.c:3079 jl_apply at /source/src/julia.h:1982 [inlined] true_main at /source/src/jlapi.c:582 jl_repl_entrypoint at /source/src/jlapi.c:731 main at /source/cli/loader_exe.c:58 unknown function (ip: 0x73c3c6277249) __libc_start_main at /lib/x86_64-linux-gnu/libc.so.6 (unknown line) unknown function (ip: 0x4010b8) Allocations: 134377443 (Pool: 134260108; Big: 117335); GC: 120 ERROR: LoadError: Failed to precompile Makie [ee78f7c6-11fb-53f2-987a-cfe4a2b5a57a] to "/home/pkgeval/.julia/compiled/v1.10/Makie/jl_26FafP". Stacktrace: [1] error(s::String) @ Base ./error.jl:35 [2] compilecache(pkg::Base.PkgId, path::String, internal_stderr::IO, internal_stdout::IO, keep_loaded_modules::Bool) @ Base ./loading.jl:2542 [3] compilecache @ ./loading.jl:2414 [inlined] [4] (::Base.var"#971#972"{Base.PkgId})() @ Base ./loading.jl:2047 [5] mkpidlock(f::Base.var"#971#972"{Base.PkgId}, at::String, pid::Int32; kwopts::@Kwargs{stale_age::Int64, wait::Bool}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:93 [6] #mkpidlock#6 @ /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:88 [inlined] [7] trymkpidlock(::Function, ::Vararg{Any}; kwargs::@Kwargs{stale_age::Int64}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:111 [8] #invokelatest#2 @ ./essentials.jl:894 [inlined] [9] invokelatest @ ./essentials.jl:889 [inlined] [10] maybe_cachefile_lock(f::Base.var"#971#972"{Base.PkgId}, pkg::Base.PkgId, srcpath::String; stale_age::Int64) @ Base ./loading.jl:3057 [11] maybe_cachefile_lock @ ./loading.jl:3054 [inlined] [12] _require(pkg::Base.PkgId, env::String) @ Base ./loading.jl:2043 [13] __require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1885 [14] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [15] invoke_in_world @ ./essentials.jl:923 [inlined] [16] _require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1876 [17] macro expansion @ ./loading.jl:1863 [inlined] [18] macro expansion @ ./lock.jl:270 [inlined] [19] __require(into::Module, mod::Symbol) @ Base ./loading.jl:1826 [20] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [21] invoke_in_world @ ./essentials.jl:923 [inlined] [22] require(into::Module, mod::Symbol) @ Base ./loading.jl:1819 [23] include @ ./Base.jl:495 [inlined] [24] include_package_for_output(pkg::Base.PkgId, input::String, depot_path::Vector{String}, dl_load_path::Vector{String}, load_path::Vector{String}, concrete_deps::Vector{Pair{Base.PkgId, UInt128}}, source::String) @ Base ./loading.jl:2295 [25] top-level scope @ stdin:4 in expression starting at /home/pkgeval/.julia/packages/CairoMakie/h1BHQ/src/CairoMakie.jl:1 in expression starting at stdin:4 StrengthEnvelop: Error During Test at /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:23 Got exception outside of a @test LoadError: Failed to precompile CairoMakie [13f3f980-e62b-5c42-98c6-ff1f3baf88f0] to "/home/pkgeval/.julia/compiled/v1.10/CairoMakie/jl_rPTDDM". Stacktrace: [1] error(s::String) @ Base ./error.jl:35 [2] compilecache(pkg::Base.PkgId, path::String, internal_stderr::IO, internal_stdout::IO, keep_loaded_modules::Bool) @ Base ./loading.jl:2542 [3] compilecache @ ./loading.jl:2414 [inlined] [4] (::Base.var"#971#972"{Base.PkgId})() @ Base ./loading.jl:2047 [5] mkpidlock(f::Base.var"#971#972"{Base.PkgId}, at::String, pid::Int32; kwopts::@Kwargs{stale_age::Int64, wait::Bool}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:93 [6] #mkpidlock#6 @ /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:88 [inlined] [7] trymkpidlock(::Function, ::Vararg{Any}; kwargs::@Kwargs{stale_age::Int64}) @ FileWatching.Pidfile /opt/julia/share/julia/stdlib/v1.10/FileWatching/src/pidfile.jl:111 [8] #invokelatest#2 @ ./essentials.jl:894 [inlined] [9] invokelatest @ ./essentials.jl:889 [inlined] [10] maybe_cachefile_lock(f::Base.var"#971#972"{Base.PkgId}, pkg::Base.PkgId, srcpath::String; stale_age::Int64) @ Base ./loading.jl:3057 [11] maybe_cachefile_lock @ ./loading.jl:3054 [inlined] [12] _require(pkg::Base.PkgId, env::String) @ Base ./loading.jl:2043 [13] __require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1885 [14] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [15] invoke_in_world @ ./essentials.jl:923 [inlined] [16] _require_prelocked(uuidkey::Base.PkgId, env::String) @ Base ./loading.jl:1876 [17] macro expansion @ ./loading.jl:1863 [inlined] [18] macro expansion @ ./lock.jl:270 [inlined] [19] __require(into::Module, mod::Symbol) @ Base ./loading.jl:1826 [20] #invoke_in_world#3 @ ./essentials.jl:926 [inlined] [21] invoke_in_world @ ./essentials.jl:923 [inlined] [22] require(into::Module, mod::Symbol) @ Base ./loading.jl:1819 [23] include(fname::String) @ Base.MainInclude ./client.jl:487 [24] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:25 [inlined] [25] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [26] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:24 [inlined] [27] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [28] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:6 [29] include(fname::String) @ Base.MainInclude ./client.jl:487 [30] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:14 [inlined] [31] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [32] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [33] include(fname::String) @ Base.MainInclude ./client.jl:487 [34] top-level scope @ none:6 in expression starting at /home/pkgeval/.julia/packages/LaMEM/qcV9I/example_scripts/StrengthEnvelop.jl:1 Saved file: Model3D.vts Saved file: Model3D.vts TM_Subduction_example: Error During Test at /home/pkgeval/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:33 Got exception outside of a @test LoadError: MethodError: no method matching length(::Nothing) Closest candidates are: length(!Matched::Base.AsyncGenerator) @ Base asyncmap.jl:390 length(!Matched::Markdown.MD) @ Markdown /opt/julia/share/julia/stdlib/v1.10/Markdown/src/parse/parse.jl:28 length(!Matched::ReadVTK.PVTKData) @ ReadVTK ~/.julia/packages/ReadVTK/cMvIT/src/ReadVTK.jl:556 ... Stacktrace: [1] run_lamem_save_grid(ParamFile::String, cores::Int64; verbose::Bool, directory::String) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:92 [2] run_lamem_save_grid @ ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:76 [inlined] [3] create_initialsetup(model::Model, cores::Int64, args::String; verbose::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:296 [4] create_initialsetup @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:273 [inlined] [5] run_lamem(model::Model, cores::Int64, args::String; wait::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:200 [6] run_lamem @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [inlined] [7] run_lamem(model::Model, cores::Int64) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [8] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/example_scripts/TM_Subduction_example.jl:249 [9] include(fname::String) @ Base.MainInclude ./client.jl:487 [10] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:35 [inlined] [11] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [12] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:34 [inlined] [13] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [14] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:6 [15] include(fname::String) @ Base.MainInclude ./client.jl:487 [16] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:14 [inlined] [17] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [18] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [19] include(fname::String) @ Base.MainInclude ./client.jl:487 [20] top-level scope @ none:6 in expression starting at /home/pkgeval/.julia/packages/LaMEM/qcV9I/example_scripts/TM_Subduction_example.jl:241 caused by: MethodError: no method matching length(::Nothing) Closest candidates are: length(!Matched::Base.AsyncGenerator) @ Base asyncmap.jl:390 length(!Matched::Markdown.MD) @ Markdown /opt/julia/share/julia/stdlib/v1.10/Markdown/src/parse/parse.jl:28 length(!Matched::ReadVTK.PVTKData) @ ReadVTK ~/.julia/packages/ReadVTK/cMvIT/src/ReadVTK.jl:556 ... Stacktrace: [1] run_lamem_save_grid(ParamFile::String, cores::Int64; verbose::Bool, directory::String) @ LaMEM.Run ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:92 [2] run_lamem_save_grid @ ~/.julia/packages/LaMEM/qcV9I/src/run_lamem_save_grid.jl:76 [inlined] [3] create_initialsetup(model::Model, cores::Int64, args::String; verbose::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:296 [4] create_initialsetup @ ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:273 [inlined] [5] run_lamem(model::Model, cores::Int64, args::String; wait::Bool) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:200 [6] run_lamem(model::Model, cores::Int64, args::String) @ LaMEM.LaMEM_Model ~/.julia/packages/LaMEM/qcV9I/src/LaMEM_ModelGeneration/Model.jl:195 [7] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/example_scripts/TM_Subduction_example.jl:244 [8] include(fname::String) @ Base.MainInclude ./client.jl:487 [9] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:35 [inlined] [10] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [11] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:34 [inlined] [12] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [13] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/test_examples.jl:6 [14] include(fname::String) @ Base.MainInclude ./client.jl:487 [15] macro expansion @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:14 [inlined] [16] macro expansion @ /opt/julia/share/julia/stdlib/v1.10/Test/src/Test.jl:1582 [inlined] [17] top-level scope @ ~/.julia/packages/LaMEM/qcV9I/test/runtests.jl:6 [18] include(fname::String) @ Base.MainInclude ./client.jl:487 [19] top-level scope @ none:6 Adding Plots.jl plotting extensions for LaMEM Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 2000. [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+07 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 1. [Myr] Maximum number of steps : 50 Time step : 0.04 [Myr] Minimum time step : 0.004 [Myr] Maximum time step : 0.2 [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 1 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [16, 16, 16] Number of cells : 4096 Number of faces : 13056 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-1., -1., -1.] Upper coordinate bounds [ex, ey, ez] : [1., 1., 1.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 1 -- sphere (dens) : rho = 3200. [kg/m^3] (diff) : eta = 1e+23 [Pa*s] Bd = 5e-24 [1/Pa/s] Phase ID : 0 -- matrix (dens) : rho = 3000. [kg/m^3] (diff) : eta = 1e+20 [Pa*s] Bd = 5e-21 [1/Pa/s] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Passive Tracers are active @ Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.0308014 sec) -------------------------------------------------------------------------- -------------------------------------------------------------------------- Passive Tracers: Initial coordinate Box x = [Left,Right] : -1.000000, 1.000000 Initial coordinate Box y = [Front,Back] : -1.000000, 1.000000 Initial coordinate Box z = [Bot, Top] : -1.000000, 1.000000 # of tracers in [x,y,z] direction : [100, 1, 100] Total # of tracers : 10000 Tracer advection activation type : Always active -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ -------------------------------------------------------------------------- Passive Tracers output parameters: Write Passive tracers pvd file -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 3.664918676663e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.215613387327e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 2.39986 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.300037785756e-10 |Div|_2 = 2.197695050567e-09 Momentum: |mRes|_2 = 2.812101470692e-10 -------------------------------------------------------------------------- Saving output ... done (0.00641385 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.04000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.082829273721e+03 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 9.002885850221e-05 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.21085 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.741679978688e-10 |Div|_2 = 4.173398077089e-09 Momentum: |mRes|_2 = 9.002885840548e-05 -------------------------------------------------------------------------- Actual time step : 0.04400 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00196763 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.1809e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00605545 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.04400000 [Myr] Tentative time step : 0.04400000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.324213934454e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.462458915117e-06 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.38991 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.819866997521e-10 |Div|_2 = 2.940635640205e-09 Momentum: |mRes|_2 = 3.462457666389e-06 -------------------------------------------------------------------------- Actual time step : 0.04840 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00178971 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.2607e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00634336 sec) -------------------------------------------------------------------------- ================================= STEP 3 ================================= -------------------------------------------------------------------------- Current time : 0.09240000 [Myr] Tentative time step : 0.04840000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.165563003467e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.089079940882e-06 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.3975 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.574193490624e-10 |Div|_2 = 2.610060920587e-09 Momentum: |mRes|_2 = 2.089078310398e-06 -------------------------------------------------------------------------- Actual time step : 0.05324 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00185557 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.2108e-02 s -------------------------------------------------------------------------- Saving output ... done (0.0065092 sec) -------------------------------------------------------------------------- ================================= STEP 4 ================================= -------------------------------------------------------------------------- Current time : 0.14564000 [Myr] Tentative time step : 0.05324000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.593494674489e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.251421534051e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.31086 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.308498975623e-10 |Div|_2 = 3.434028191940e-09 Momentum: |mRes|_2 = 7.251340221610e-07 -------------------------------------------------------------------------- Actual time step : 0.05856 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00182099 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3497e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00626392 sec) -------------------------------------------------------------------------- ================================= STEP 5 ================================= -------------------------------------------------------------------------- Current time : 0.20420400 [Myr] Tentative time step : 0.05856400 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.629420757250e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.050131976791e-06 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.39719 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.256838745710e-10 |Div|_2 = 3.498013790468e-09 Momentum: |mRes|_2 = 4.050130466210e-06 -------------------------------------------------------------------------- Actual time step : 0.06442 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00201014 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.4856e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00635189 sec) -------------------------------------------------------------------------- ================================= STEP 6 ================================= -------------------------------------------------------------------------- Current time : 0.26862440 [Myr] Tentative time step : 0.06442040 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.907965097930e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.576690420797e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.35235 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.582154427562e-10 |Div|_2 = 2.601437557826e-09 Momentum: |mRes|_2 = 4.576616486016e-07 -------------------------------------------------------------------------- Actual time step : 0.07086 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00179748 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.2252e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00671288 sec) -------------------------------------------------------------------------- ================================= STEP 7 ================================= -------------------------------------------------------------------------- Current time : 0.33948684 [Myr] Tentative time step : 0.07086244 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.190965994971e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.397810426894e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.36898 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.782584496679e-10 |Div|_2 = 5.395537714107e-10 Momentum: |mRes|_2 = 1.397800013488e-07 -------------------------------------------------------------------------- Actual time step : 0.07795 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00176365 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.1826e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00648239 sec) -------------------------------------------------------------------------- ================================= STEP 8 ================================= -------------------------------------------------------------------------- Current time : 0.41743552 [Myr] Tentative time step : 0.07794868 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.389821845717e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.117285484745e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 2.3303 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.277297465868e-10 |Div|_2 = 1.416385545135e-09 Momentum: |mRes|_2 = 6.115645527804e-08 -------------------------------------------------------------------------- Actual time step : 0.08574 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.0016287 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.1755e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00722941 sec) -------------------------------------------------------------------------- ================================= STEP 9 ================================= -------------------------------------------------------------------------- Current time : 0.50317908 [Myr] Tentative time step : 0.08574355 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.734976103562e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.735393580882e-06 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.33468 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.824010405886e-10 |Div|_2 = 1.768443077894e-09 Momentum: |mRes|_2 = 1.735392679821e-06 -------------------------------------------------------------------------- Actual time step : 0.09432 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.0017652 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.2000e-02 s -------------------------------------------------------------------------- Saving output ... done (0.0065006 sec) -------------------------------------------------------------------------- ================================ STEP 10 ================================= -------------------------------------------------------------------------- Current time : 0.59749698 [Myr] Tentative time step : 0.09431791 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.541052347654e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.765103611401e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.3169 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.858312358161e-10 |Div|_2 = 4.181829320776e-10 Momentum: |mRes|_2 = 1.765098657663e-07 -------------------------------------------------------------------------- Actual time step : 0.10375 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00190039 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.1650e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00644572 sec) -------------------------------------------------------------------------- ================================ STEP 11 ================================= -------------------------------------------------------------------------- Current time : 0.70124668 [Myr] Tentative time step : 0.10374970 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.318442870748e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.392975683453e-08 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 2.27885 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.805268062116e-10 |Div|_2 = 6.040526611389e-10 Momentum: |mRes|_2 = 2.392213164712e-08 -------------------------------------------------------------------------- Actual time step : 0.11412 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00179064 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.1390e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00666475 sec) -------------------------------------------------------------------------- ================================ STEP 12 ================================= -------------------------------------------------------------------------- Current time : 0.81537135 [Myr] Tentative time step : 0.11412467 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.557663543994e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.365906079124e-09 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 2.32039 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.694067191555e-12 |Div|_2 = 1.182768370003e-11 Momentum: |mRes|_2 = 5.365893043649e-09 -------------------------------------------------------------------------- Actual time step : 0.12554 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00166958 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.2810e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00618555 sec) -------------------------------------------------------------------------- ================================ STEP 13 ================================= -------------------------------------------------------------------------- Current time : 0.94090849 [Myr] Tentative time step : 0.12553714 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.861612717370e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.834167056638e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 2.30068 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.909923239869e-10 |Div|_2 = 6.288988749242e-10 Momentum: |mRes|_2 = 1.834156274770e-07 -------------------------------------------------------------------------- Actual time step : 0.13809 [Myr] -------------------------------------------------------------------------- Advection Passive tracers ... Currently active tracers : 10000 done (0.00175159 sec) -------------------------------------------------------------------------- Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 1.3060e-02 s -------------------------------------------------------------------------- Saving output ... done (0.00631614 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 34.3498 (sec) -------------------------------------------------------------------------- Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 1e+06 [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+09 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 5. [Myr] Maximum number of steps : 200 Time step : 0.01 [Myr] Minimum time step : 1e-05 [Myr] Maximum time step : 0.1 [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 5 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [32, 1, 32] Number of cells : 1024 Number of faces : 4160 Maximum cell aspect ratio : 1.56250 Lower coordinate bounds [bx, by, bz] : [-50., -1., -50.] Upper coordinate bounds [ex, ey, ez] : [50., 1., 20.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- Air (dens) : rho = 50. [kg/m^3] (diff) : eta = 1e+19 [Pa*s] Bd = 5e-20 [1/Pa/s] (plast) : ch = 1e+07 [Pa] Phase ID : 1 -- crust (dens) : rho = 2700. [kg/m^3] (diff) : eta = 1e+21 [Pa*s] Bd = 5e-22 [1/Pa/s] (plast) : ch = 3e+07 [Pa] fr = 20. [deg] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Free surface parameters: Sticky air phase ID : 0 Initial surface level : 10. [km] Erosion model : prescribed rate with given level Sedimentation model : none Correct marker phases @ Maximum surface slope : 40. [deg] -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Warning: True pressure-dependent rheology requires open top boundary (Vd, Vn, Vp, fr, Kb, beta, p_litho_visc, p_litho_plast, open_top_bound) Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.00845014 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ Accumulated Plastic Strain (APS) @ Plastic dissipation @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 7.723483539004e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.044419511759e-05 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0431714 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.665657274183e-08 |Div|_2 = 2.922396668616e-07 Momentum: |mRes|_2 = 2.044210630007e-05 -------------------------------------------------------------------------- Saving output ... done (0.00177459 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.01000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.809392698503e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.209198080500e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0298861 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.485380468909e-19 |Div|_2 = 2.610774057723e-18 Momentum: |mRes|_2 = 1.209198080497e-12 -------------------------------------------------------------------------- Actual time step : 0.01100 [Myr] -------------------------------------------------------------------------- Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Topography is (9.989000e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4304e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00203727 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.01100000 [Myr] Tentative time step : 0.01100000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.229010285717e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 9.618275184872e-05 1 MMFD ||F||/||F0||=1.839406e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 9.977113317220e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0529668 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.106003428440e-18 |Div|_2 = 2.530575493835e-17 Momentum: |mRes|_2 = 9.977113314011e-13 -------------------------------------------------------------------------- Actual time step : 0.01210 [Myr] -------------------------------------------------------------------------- Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Topography is (9.976900e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.7433e-03 s -------------------------------------------------------------------------- ================================= STEP 3 ================================= -------------------------------------------------------------------------- Current time : 0.02310000 [Myr] Tentative time step : 0.01210000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.751911314281e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.087086476696e-04 1 MMFD ||F||/||F0||=1.889957e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.174776370256e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0533544 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.965874144306e-18 |Div|_2 = 4.774415117514e-17 Momentum: |mRes|_2 = 1.174776369285e-12 -------------------------------------------------------------------------- Actual time step : 0.01331 [Myr] -------------------------------------------------------------------------- Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Topography is (9.963590e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3383e-03 s -------------------------------------------------------------------------- ================================= STEP 4 ================================= -------------------------------------------------------------------------- Current time : 0.03641000 [Myr] Tentative time step : 0.01331000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.327102445719e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.230969872585e-04 1 MMFD ||F||/||F0||=1.945551e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.347004042197e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0513036 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 7.671259518952e-18 |Div|_2 = 9.237541222720e-17 Momentum: |mRes|_2 = 1.347004039029e-12 -------------------------------------------------------------------------- Actual time step : 0.01464 [Myr] -------------------------------------------------------------------------- Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Topography is (9.948949e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2750e-03 s -------------------------------------------------------------------------- ================================= STEP 5 ================================= -------------------------------------------------------------------------- Current time : 0.05105100 [Myr] Tentative time step : 0.01464100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.959812690284e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.396618351418e-04 1 MMFD ||F||/||F0||=2.006690e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.125681170034e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0562214 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.504713014691e-17 |Div|_2 = 1.814743317160e-16 Momentum: |mRes|_2 = 1.125681155406e-12 -------------------------------------------------------------------------- Actual time step : 0.01611 [Myr] -------------------------------------------------------------------------- Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Topography is (9.932844e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.5214e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00201852 sec) -------------------------------------------------------------------------- ================================= STEP 6 ================================= -------------------------------------------------------------------------- Current time : 0.06715610 [Myr] Tentative time step : 0.01610510 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.655793959319e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.587754245416e-04 1 MMFD ||F||/||F0||=2.073925e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.307184343930e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.053607 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.915926802349e-17 |Div|_2 = 3.520350671003e-16 Momentum: |mRes|_2 = 1.307184296528e-12 -------------------------------------------------------------------------- Actual time step : 0.01772 [Myr] -------------------------------------------------------------------------- Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Topography is (9.915128e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3460e-03 s -------------------------------------------------------------------------- ================================= STEP 7 ================================= -------------------------------------------------------------------------- Current time : 0.08487171 [Myr] Tentative time step : 0.01771561 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.421373355243e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.808795627172e-04 1 MMFD ||F||/||F0||=2.147863e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.681011930406e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0525379 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.540429922264e-17 |Div|_2 = 6.695337031823e-16 Momentum: |mRes|_2 = 1.681011797071e-12 -------------------------------------------------------------------------- Actual time step : 0.01949 [Myr] -------------------------------------------------------------------------- Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Topography is (9.895641e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.5446e-03 s -------------------------------------------------------------------------- ================================= STEP 8 ================================= -------------------------------------------------------------------------- Current time : 0.10435888 [Myr] Tentative time step : 0.01948717 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 9.263510690762e-01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.064993488760e-04 1 MMFD ||F||/||F0||=2.229169e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.660761859668e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0546901 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.041714638395e-16 |Div|_2 = 1.259538725506e-15 Momentum: |mRes|_2 = 1.660761382045e-12 -------------------------------------------------------------------------- Actual time step : 0.02144 [Myr] -------------------------------------------------------------------------- Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Topography is (9.874205e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3664e-03 s -------------------------------------------------------------------------- ================================= STEP 9 ================================= -------------------------------------------------------------------------- Current time : 0.12579477 [Myr] Tentative time step : 0.02143589 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.018986175984e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.362596651556e-04 1 MMFD ||F||/||F0||=2.318576e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.471588870227e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0526019 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.899823167557e-16 |Div|_2 = 2.296727611458e-15 Momentum: |mRes|_2 = 2.471587803108e-12 -------------------------------------------------------------------------- Actual time step : 0.02358 [Myr] -------------------------------------------------------------------------- Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Topography is (9.850626e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4459e-03 s -------------------------------------------------------------------------- ================================ STEP 10 ================================= -------------------------------------------------------------------------- Current time : 0.14937425 [Myr] Tentative time step : 0.02357948 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.120884793581e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.709050160747e-04 1 MMFD ||F||/||F0||=2.416885e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 3.413636250060e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0525132 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.426265766610e-16 |Div|_2 = 4.145093000790e-15 Momentum: |mRes|_2 = 3.413633733418e-12 -------------------------------------------------------------------------- Actual time step : 0.02594 [Myr] -------------------------------------------------------------------------- Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Topography is (9.824688e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 3.1580e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00188716 sec) -------------------------------------------------------------------------- ================================ STEP 11 ================================= -------------------------------------------------------------------------- Current time : 0.17531167 [Myr] Tentative time step : 0.02593742 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.232973272938e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 3.113234044373e-04 1 MMFD ||F||/||F0||=2.524981e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 5.208251607646e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0567565 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.735618433125e-16 |Div|_2 = 6.941483390532e-15 Momentum: |mRes|_2 = 5.208246981889e-12 -------------------------------------------------------------------------- Actual time step : 0.02853 [Myr] -------------------------------------------------------------------------- Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Topography is (9.796157e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3472e-03 s -------------------------------------------------------------------------- ================================ STEP 12 ================================= -------------------------------------------------------------------------- Current time : 0.20384284 [Myr] Tentative time step : 0.02853117 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.356270600229e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 3.585750619506e-04 1 MMFD ||F||/||F0||=2.643831e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 6.382959387562e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0532556 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.087307455303e-16 |Div|_2 = 1.100274615325e-14 Momentum: |mRes|_2 = 6.382949904460e-12 -------------------------------------------------------------------------- Actual time step : 0.03138 [Myr] -------------------------------------------------------------------------- Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Topography is (9.764773e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.5789e-03 s -------------------------------------------------------------------------- ================================ STEP 13 ================================= -------------------------------------------------------------------------- Current time : 0.23522712 [Myr] Tentative time step : 0.03138428 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.491897660250e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 4.139270279614e-04 1 MMFD ||F||/||F0||=2.774500e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.038902931149e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0528831 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.321659345050e-15 |Div|_2 = 1.601180421862e-14 Momentum: |mRes|_2 = 1.038901697260e-11 -------------------------------------------------------------------------- Actual time step : 0.03452 [Myr] -------------------------------------------------------------------------- Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Topography is (9.730250e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.6706e-03 s -------------------------------------------------------------------------- ================================ STEP 14 ================================= -------------------------------------------------------------------------- Current time : 0.26974983 [Myr] Tentative time step : 0.03452271 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.641087426269e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 4.788947890598e-04 1 MMFD ||F||/||F0||=2.918155e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.457299471065e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.052951 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.826932711242e-15 |Div|_2 = 2.215562796320e-14 Momentum: |mRes|_2 = 1.457297786881e-11 -------------------------------------------------------------------------- Actual time step : 0.03797 [Myr] -------------------------------------------------------------------------- Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Topography is (9.692275e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2688e-03 s -------------------------------------------------------------------------- ================================ STEP 15 ================================= -------------------------------------------------------------------------- Current time : 0.30772482 [Myr] Tentative time step : 0.03797498 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.805196168890e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 5.552923876926e-04 1 MMFD ||F||/||F0||=3.076078e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.089240770849e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0516161 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.391024199466e-15 |Div|_2 = 2.903913833897e-14 Momentum: |mRes|_2 = 2.089238752718e-11 -------------------------------------------------------------------------- Actual time step : 0.04177 [Myr] -------------------------------------------------------------------------- Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Topography is (9.650503e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2804e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00174406 sec) -------------------------------------------------------------------------- ================================ STEP 16 ================================= -------------------------------------------------------------------------- Current time : 0.34949730 [Myr] Tentative time step : 0.04177248 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.985715785771e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 6.452927474471e-04 1 MMFD ||F||/||F0||=3.249673e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.646141355986e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0508026 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.027553307377e-15 |Div|_2 = 3.684464791845e-14 Momentum: |mRes|_2 = 2.646138790876e-11 -------------------------------------------------------------------------- Actual time step : 0.04595 [Myr] -------------------------------------------------------------------------- Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Topography is (9.604553e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2982e-03 s -------------------------------------------------------------------------- ================================ STEP 17 ================================= -------------------------------------------------------------------------- Current time : 0.39544703 [Myr] Tentative time step : 0.04594973 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.184287364342e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.042008758968e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.027255 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.159686802134e-11 |Div|_2 = 1.416861861430e-10 Momentum: |mRes|_2 = 1.042007795685e-07 -------------------------------------------------------------------------- Actual time step : 0.05054 [Myr] -------------------------------------------------------------------------- Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Topography is (9.554008e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 3.3389e-03 s -------------------------------------------------------------------------- ================================ STEP 18 ================================= -------------------------------------------------------------------------- Current time : 0.44599173 [Myr] Tentative time step : 0.05054470 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.402716281729e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.222841764006e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0251407 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.307374084935e-11 |Div|_2 = 1.606482985943e-10 Momentum: |mRes|_2 = 1.222840708764e-07 -------------------------------------------------------------------------- Actual time step : 0.05560 [Myr] -------------------------------------------------------------------------- Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Topography is (9.498409e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2851e-03 s -------------------------------------------------------------------------- ================================ STEP 19 ================================= -------------------------------------------------------------------------- Current time : 0.50159090 [Myr] Tentative time step : 0.05559917 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.642987926428e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.438762895191e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0250504 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.485872710160e-11 |Div|_2 = 1.843391403960e-10 Momentum: |mRes|_2 = 1.438761714283e-07 -------------------------------------------------------------------------- Actual time step : 0.06116 [Myr] -------------------------------------------------------------------------- Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Topography is (9.437250e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3687e-03 s -------------------------------------------------------------------------- ================================ STEP 20 ================================= -------------------------------------------------------------------------- Current time : 0.56274999 [Myr] Tentative time step : 0.06115909 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.907286739208e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.697200907176e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.026158 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.710192460912e-11 |Div|_2 = 2.156977501078e-10 Momentum: |mRes|_2 = 1.697199536521e-07 -------------------------------------------------------------------------- Actual time step : 0.06727 [Myr] -------------------------------------------------------------------------- Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Topography is (9.369975e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4291e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00256179 sec) -------------------------------------------------------------------------- ================================ STEP 21 ================================= -------------------------------------------------------------------------- Current time : 0.63002499 [Myr] Tentative time step : 0.06727500 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.781428747096e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.050784625324e-06 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0266102 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.664640152121e-09 |Div|_2 = 1.093781914946e-08 Momentum: |mRes|_2 = 1.050727696851e-06 -------------------------------------------------------------------------- Actual time step : 0.07400 [Myr] -------------------------------------------------------------------------- Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Topography is (9.295972e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3550e-03 s -------------------------------------------------------------------------- ================================ STEP 22 ================================= -------------------------------------------------------------------------- Current time : 0.70402749 [Myr] Tentative time step : 0.07400250 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.118812267826e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.146263029870e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0280354 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.478746703889e-17 |Div|_2 = 2.548273633243e-16 Momentum: |mRes|_2 = 1.146263001544e-12 -------------------------------------------------------------------------- Actual time step : 0.08140 [Myr] -------------------------------------------------------------------------- Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Topography is (9.214570e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.7892e-03 s -------------------------------------------------------------------------- ================================ STEP 23 ================================= -------------------------------------------------------------------------- Current time : 0.78543024 [Myr] Tentative time step : 0.08140275 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.153144382778e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.601044868401e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0276445 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.135796236018e-22 |Div|_2 = 1.978952008566e-21 Momentum: |mRes|_2 = 8.601044868401e-13 -------------------------------------------------------------------------- Actual time step : 0.08954 [Myr] -------------------------------------------------------------------------- Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Topography is (9.125027e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.7134e-03 s -------------------------------------------------------------------------- ================================ STEP 24 ================================= -------------------------------------------------------------------------- Current time : 0.87497327 [Myr] Tentative time step : 0.08954302 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.604242310196e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.451661956456e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0279884 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.560947770423e-22 |Div|_2 = 1.695574618895e-21 Momentum: |mRes|_2 = 4.451661956456e-13 -------------------------------------------------------------------------- Actual time step : 0.09850 [Myr] -------------------------------------------------------------------------- Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Topography is (9.026529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 3.0209e-03 s -------------------------------------------------------------------------- ================================ STEP 25 ================================= -------------------------------------------------------------------------- Current time : 0.97347059 [Myr] Tentative time step : 0.09849733 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.709916298010e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.338396206144e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0289023 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.277649275580e-12 |Div|_2 = 8.773360011349e-11 Momentum: |mRes|_2 = 1.338395918591e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Topography is (8.926529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 3.7179e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00219802 sec) -------------------------------------------------------------------------- ================================ STEP 26 ================================= -------------------------------------------------------------------------- Current time : 1.07347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645952931e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.781918574516e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0297116 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.752367471857e-11 |Div|_2 = 2.446177696723e-10 Momentum: |mRes|_2 = 3.781917783411e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Topography is (8.826529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4084e-03 s -------------------------------------------------------------------------- ================================ STEP 27 ================================= -------------------------------------------------------------------------- Current time : 1.17347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646381147e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.799010254716e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0283946 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.760199479003e-11 |Div|_2 = 2.453278199359e-10 Momentum: |mRes|_2 = 3.799009462592e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Topography is (8.726529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.6056e-03 s -------------------------------------------------------------------------- ================================ STEP 28 ================================= -------------------------------------------------------------------------- Current time : 1.27347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646384492e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.816034505082e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0283808 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.768853451477e-11 |Div|_2 = 2.461384966648e-10 Momentum: |mRes|_2 = 3.816033711272e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Topography is (8.626529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2757e-03 s -------------------------------------------------------------------------- ================================ STEP 29 ================================= -------------------------------------------------------------------------- Current time : 1.37347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646387818e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.832970080513e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0245734 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.778461137486e-11 |Div|_2 = 2.470702480035e-10 Momentum: |mRes|_2 = 3.832969284215e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Topography is (8.526529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3095e-03 s -------------------------------------------------------------------------- ================================ STEP 30 ================================= -------------------------------------------------------------------------- Current time : 1.47347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646391118e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.849760706200e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0266304 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.789177811042e-11 |Div|_2 = 2.481483333904e-10 Momentum: |mRes|_2 = 3.849759906441e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Topography is (8.426529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2474e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00184347 sec) -------------------------------------------------------------------------- ================================ STEP 31 ================================= -------------------------------------------------------------------------- Current time : 1.57347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646394381e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.866318488220e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0246868 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.801181146024e-11 |Div|_2 = 2.494034676313e-10 Momentum: |mRes|_2 = 3.866317683810e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Topography is (8.326529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2242e-03 s -------------------------------------------------------------------------- ================================ STEP 32 ================================= -------------------------------------------------------------------------- Current time : 1.67347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646397590e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.882406034520e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0233291 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.814644682539e-11 |Div|_2 = 2.508694167270e-10 Momentum: |mRes|_2 = 3.882405223998e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Topography is (8.226529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2972e-03 s -------------------------------------------------------------------------- ================================ STEP 33 ================================= -------------------------------------------------------------------------- Current time : 1.77347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646400699e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.897328079317e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0244834 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.829601885453e-11 |Div|_2 = 2.525662374189e-10 Momentum: |mRes|_2 = 3.897327260939e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Topography is (8.126529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.7628e-03 s -------------------------------------------------------------------------- ================================ STEP 34 ================================= -------------------------------------------------------------------------- Current time : 1.87347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646403581e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.779605390357e-03 1 MMFD ||F||/||F0||=5.847312e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.229319231234e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0502443 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.052362225222e-14 |Div|_2 = 1.450711934548e-13 Momentum: |mRes|_2 = 2.229318759214e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Topography is (8.026529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3397e-03 s -------------------------------------------------------------------------- ================================ STEP 35 ================================= -------------------------------------------------------------------------- Current time : 1.97347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713906e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.777742187518e-03 1 MMFD ||F||/||F0||=5.843393e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.001542723060e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.048398 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.523258872170e-15 |Div|_2 = 1.311732683584e-13 Momentum: |mRes|_2 = 2.001542293231e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Topography is (7.926529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4121e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00182231 sec) -------------------------------------------------------------------------- ================================ STEP 36 ================================= -------------------------------------------------------------------------- Current time : 2.07347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713940e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.775872877187e-03 1 MMFD ||F||/||F0||=5.839461e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 8.327003402355e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0590994 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.993300016091e-15 |Div|_2 = 5.498732934956e-14 Momentum: |mRes|_2 = 8.327001586812e-11 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Topography is (7.826529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.1968e-03 s -------------------------------------------------------------------------- ================================ STEP 37 ================================= -------------------------------------------------------------------------- Current time : 2.17347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645714142e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.773995158696e-03 1 MMFD ||F||/||F0||=5.835511e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.184743676913e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0483599 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.060580968327e-14 |Div|_2 = 1.461303044317e-13 Momentum: |mRes|_2 = 2.184743188204e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Topography is (7.726529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2745e-03 s -------------------------------------------------------------------------- ================================ STEP 38 ================================= -------------------------------------------------------------------------- Current time : 2.27347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713901e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.772106269743e-03 1 MMFD ||F||/||F0||=5.831537e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.293125691195e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0484212 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.125213085394e-14 |Div|_2 = 1.553553835346e-13 Momentum: |mRes|_2 = 2.293125164942e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Topography is (7.626529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.1183e-03 s -------------------------------------------------------------------------- ================================ STEP 39 ================================= -------------------------------------------------------------------------- Current time : 2.37347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713881e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.996319201238e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0228069 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.011135874350e-11 |Div|_2 = 2.789791632282e-10 Momentum: |mRes|_2 = 3.996318227475e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Topography is (7.526529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2120e-03 s -------------------------------------------------------------------------- ================================ STEP 40 ================================= -------------------------------------------------------------------------- Current time : 2.47347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646421677e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.012779424187e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0243943 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.073117564038e-11 |Div|_2 = 2.900013525055e-10 Momentum: |mRes|_2 = 4.012778376275e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Topography is (7.426529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3081e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00159003 sec) -------------------------------------------------------------------------- ================================ STEP 41 ================================= -------------------------------------------------------------------------- Current time : 2.57347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646424379e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.027752948412e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0244222 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.156004347902e-11 |Div|_2 = 3.060754751755e-10 Momentum: |mRes|_2 = 4.027751785453e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Topography is (7.326529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4122e-03 s -------------------------------------------------------------------------- ================================ STEP 42 ================================= -------------------------------------------------------------------------- Current time : 2.67347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646426605e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 4.041129534540e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0239633 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.287405394040e-11 |Div|_2 = 3.310230089513e-10 Momentum: |mRes|_2 = 4.041128178778e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Topography is (7.226529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2644e-03 s -------------------------------------------------------------------------- ================================ STEP 43 ================================= -------------------------------------------------------------------------- Current time : 2.77347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.146410356177e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.660951497075e-06 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.024281 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.779608991371e-09 |Div|_2 = 1.761752849615e-08 Momentum: |mRes|_2 = 1.660858060860e-06 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Topography is (7.126529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4377e-03 s -------------------------------------------------------------------------- ================================ STEP 44 ================================= -------------------------------------------------------------------------- Current time : 2.87347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.660951497075e-06 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.154715729653e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0234132 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.020362617650e-17 |Div|_2 = 2.101221482559e-16 Momentum: |mRes|_2 = 1.154715710535e-12 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Topography is (7.026529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2543e-03 s -------------------------------------------------------------------------- ================================ STEP 45 ================================= -------------------------------------------------------------------------- Current time : 2.97347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 1.154715729653e-12 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 8.191306532451e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0246491 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.091853943780e-22 |Div|_2 = 1.155808607186e-21 Momentum: |mRes|_2 = 8.191306532451e-13 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Topography is (6.926529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2198e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00248533 sec) -------------------------------------------------------------------------- ================================ STEP 46 ================================= -------------------------------------------------------------------------- Current time : 3.07347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.191306532451e-13 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 6.654227741969e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0234593 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.856487381537e-22 |Div|_2 = 8.159376455297e-22 Momentum: |mRes|_2 = 6.654227741969e-13 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Topography is (6.826529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2446e-03 s -------------------------------------------------------------------------- ================================ STEP 47 ================================= -------------------------------------------------------------------------- Current time : 3.17347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.304128348389e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.787338954473e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0237567 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.856300489121e-12 |Div|_2 = 1.072497280841e-10 Momentum: |mRes|_2 = 1.787338632696e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Topography is (6.726529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2387e-03 s -------------------------------------------------------------------------- ================================ STEP 48 ================================= -------------------------------------------------------------------------- Current time : 3.27347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646028400e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.704094833242e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0232399 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.420427538865e-11 |Div|_2 = 2.217972035582e-10 Momentum: |mRes|_2 = 3.704094169194e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Topography is (6.626529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.1379e-03 s -------------------------------------------------------------------------- ================================ STEP 49 ================================= -------------------------------------------------------------------------- Current time : 3.37347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646365517e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.720684514644e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0233458 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.426926909722e-11 |Div|_2 = 2.224044479942e-10 Momentum: |mRes|_2 = 3.720683849931e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Topography is (6.526529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.1790e-03 s -------------------------------------------------------------------------- ================================ STEP 50 ================================= -------------------------------------------------------------------------- Current time : 3.47347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646368757e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.737208116143e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0236076 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.434113192014e-11 |Div|_2 = 2.231042122100e-10 Momentum: |mRes|_2 = 3.737207450198e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Topography is (6.426529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2289e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00168849 sec) -------------------------------------------------------------------------- ================================ STEP 51 ================================= -------------------------------------------------------------------------- Current time : 3.57347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646371980e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.753635155572e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0232137 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.442096650568e-11 |Div|_2 = 2.239160826161e-10 Momentum: |mRes|_2 = 3.753634487707e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Topography is (6.326529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.1964e-03 s -------------------------------------------------------------------------- ================================ STEP 52 ================================= -------------------------------------------------------------------------- Current time : 3.67347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646375179e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.769919376748e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.024248 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.451007773577e-11 |Div|_2 = 2.248645248253e-10 Momentum: |mRes|_2 = 3.769918706123e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Topography is (6.226529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4673e-03 s -------------------------------------------------------------------------- ================================ STEP 53 ================================= -------------------------------------------------------------------------- Current time : 3.77347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646378343e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.785954056354e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0245885 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.460993778788e-11 |Div|_2 = 2.259792377330e-10 Momentum: |mRes|_2 = 3.785953381932e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Topography is (6.126529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3175e-03 s -------------------------------------------------------------------------- ================================ STEP 54 ================================= -------------------------------------------------------------------------- Current time : 3.87347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646381461e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.801487307231e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0241579 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.472195765881e-11 |Div|_2 = 2.272930607804e-10 Momentum: |mRes|_2 = 3.801486627732e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Topography is (6.026529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2380e-03 s -------------------------------------------------------------------------- ================================ STEP 55 ================================= -------------------------------------------------------------------------- Current time : 3.97347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646384469e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.815725808667e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0231447 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.484610738506e-11 |Div|_2 = 2.288229768708e-10 Momentum: |mRes|_2 = 3.815725122560e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Topography is (5.926529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.1748e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00176251 sec) -------------------------------------------------------------------------- ================================ STEP 56 ================================= -------------------------------------------------------------------------- Current time : 4.07347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646387226e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.719936983167e-03 1 MMFD ||F||/||F0||=5.721791e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.142994758026e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.051183 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.317874901047e-15 |Div|_2 = 1.279986496914e-13 Momentum: |mRes|_2 = 2.142994375766e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Topography is (5.826529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2508e-03 s -------------------------------------------------------------------------- ================================ STEP 57 ================================= -------------------------------------------------------------------------- Current time : 4.17347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713935e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.718042249778e-03 1 MMFD ||F||/||F0||=5.717806e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.818328005585e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.05037 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 7.169963263737e-15 |Div|_2 = 1.102410135407e-13 Momentum: |mRes|_2 = 1.818327671402e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Topography is (5.726529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.2411e-03 s -------------------------------------------------------------------------- ================================ STEP 58 ================================= -------------------------------------------------------------------------- Current time : 4.27347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713988e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.716139023080e-03 1 MMFD ||F||/||F0||=5.713802e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.221401147640e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0547393 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.873431897677e-15 |Div|_2 = 7.491440606076e-14 Momentum: |mRes|_2 = 1.221400917897e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Topography is (5.626529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 3.0568e-03 s -------------------------------------------------------------------------- ================================ STEP 59 ================================= -------------------------------------------------------------------------- Current time : 4.37347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645714094e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.714224254207e-03 1 MMFD ||F||/||F0||=5.709774e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.115709291257e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0549746 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.499438908467e-15 |Div|_2 = 1.307709304836e-13 Momentum: |mRes|_2 = 2.115708887112e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Topography is (5.526529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.8658e-03 s -------------------------------------------------------------------------- ================================ STEP 60 ================================= -------------------------------------------------------------------------- Current time : 4.47347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713938e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 2.712294046634e-03 1 MMFD ||F||/||F0||=5.705713e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 2.179275419417e-10 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.0577316 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 8.965591925027e-15 |Div|_2 = 1.383193329735e-13 Momentum: |mRes|_2 = 2.179274980458e-10 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Topography is (5.426529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.5633e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00205136 sec) -------------------------------------------------------------------------- ================================ STEP 61 ================================= -------------------------------------------------------------------------- Current time : 4.57347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753645713929e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.912242449556e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.026253 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.637546409289e-11 |Div|_2 = 2.541534955932e-10 Momentum: |mRes|_2 = 3.912241624019e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Topography is (5.326529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.5214e-03 s -------------------------------------------------------------------------- ================================ STEP 62 ================================= -------------------------------------------------------------------------- Current time : 4.67347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646404883e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.928039517890e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0250808 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.690148879384e-11 |Div|_2 = 2.651056760597e-10 Momentum: |mRes|_2 = 3.928038623283e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Topography is (5.226529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4057e-03 s -------------------------------------------------------------------------- ================================ STEP 63 ================================= -------------------------------------------------------------------------- Current time : 4.77347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646407464e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.942408222348e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0250456 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.760976527127e-11 |Div|_2 = 2.813412810938e-10 Momentum: |mRes|_2 = 3.942407218483e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Topography is (5.126529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3831e-03 s -------------------------------------------------------------------------- ================================ STEP 64 ================================= -------------------------------------------------------------------------- Current time : 4.87347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.753646409577e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 3.955151780512e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0245667 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.351626185769e-11 |Div|_2 = 3.069681871490e-10 Momentum: |mRes|_2 = 3.955150589287e-07 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Topography is (5.026529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.4785e-03 s -------------------------------------------------------------------------- ================================ STEP 65 ================================= -------------------------------------------------------------------------- Current time : 4.97347059 [Myr] Tentative time step : 0.10000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.086989155971e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 1.575818368951e-06 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.0238153 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.722037044873e-09 |Div|_2 = 1.694959120056e-08 Momentum: |mRes|_2 = 1.575727210935e-06 -------------------------------------------------------------------------- Actual time step : 0.10000 [Myr] -------------------------------------------------------------------------- Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Topography is (4.926529e+00 [km]). Applying erosion at constant rate (0.100000 [cm/yr]) to internal free surface. Applying erosion at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 2.3867e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00183155 sec) -------------------------------------------------------------------------- =========================== SOLUTION IS DONE! ============================ -------------------------------------------------------------------------- Total solution time : 3.972 (sec) -------------------------------------------------------------------------- Saved file: Model3D.vts Writing LaMEM marker file -> ./markers/mdb.00000000.dat cores_compute = 1 -------------------------------------------------------------------------- Lithosphere and Mantle Evolution Model Compiled: Date: Jan 1 1970 - Time: 00:00:00 Version : 2.1.4 -------------------------------------------------------------------------- STAGGERED-GRID FINITE DIFFERENCE CANONICAL IMPLEMENTATION -------------------------------------------------------------------------- Parsing input file : output.dat Finished parsing input file -------------------------------------------------------------------------- Scaling parameters: Temperature : 1000. [C/K] Length : 1e+06 [m] Viscosity : 1e+20 [Pa*s] Stress : 1e+09 [Pa] -------------------------------------------------------------------------- Time stepping parameters: Simulation end time : 5. [Myr] Maximum number of steps : 200 Time step : 0.01 [Myr] Minimum time step : 1e-05 [Myr] Maximum time step : 0.1 [Myr] Time step increase factor : 0.1 CFL criterion : 0.5 CFLMAX (fixed time steps) : 0.8 Output every [n] steps : 5 Output [n] initial steps : 1 Save restart every [n] steps : 100 -------------------------------------------------------------------------- Grid parameters: Total number of cpu : 1 Processor grid [nx, ny, nz] : [1, 1, 1] Fine grid cells [nx, ny, nz] : [50, 1, 50] Number of cells : 2500 Number of faces : 10100 Maximum cell aspect ratio : 1.00000 Lower coordinate bounds [bx, by, bz] : [-50., -1., -50.] Upper coordinate bounds [ex, ey, ez] : [50., 1., 50.] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Material parameters: -------------------------------------------------------------------------- Phase ID : 0 -- Air (dens) : rho = 50. [kg/m^3] (diff) : eta = 1e+19 [Pa*s] Bd = 5e-20 [1/Pa/s] (plast) : ch = 1e+07 [Pa] Phase ID : 1 -- crust (dens) : rho = 2700. [kg/m^3] (diff) : eta = 1e+21 [Pa*s] Bd = 5e-22 [1/Pa/s] (plast) : ch = 3e+07 [Pa] fr = 20. [deg] -------------------------------------------------------------------------- -------------------------------------------------------------------------- Free surface parameters: Sticky air phase ID : 0 Initial surface level : -25. [km] Erosion model : none Sedimentation model : prescribed rate with given level Number of sediment layers : 1 Correct marker phases @ Maximum surface slope : 40. [deg] -------------------------------------------------------------------------- Boundary condition parameters: No-slip boundary mask [lt rt ft bk bm tp] : 0 0 0 0 0 0 Top boundary temperature : 0. [C] Bottom boundary temperature : 1300. [C] -------------------------------------------------------------------------- Warning: True pressure-dependent rheology requires open top boundary (Vd, Vn, Vp, fr, Kb, beta, p_litho_visc, p_litho_plast, open_top_bound) Solution parameters & controls: Gravity [gx, gy, gz] : [0., 0., -9.81] [m/s^2] Surface stabilization (FSSA) : 1. Compute initial guess @ Use lithostatic pressure for creep @ Enforce zero average pressure on top @ Limit pressure at first iteration @ Reference viscosity (initial guess) : 1e+20 [Pa*s] Max. melt fraction (viscosity, density) : 1. Rheology iteration number : 25 Rheology iteration tolerance : 1e-06 Ground water level type : none -------------------------------------------------------------------------- Advection parameters: Advection scheme : Runge-Kutta 2-nd order Periodic marker advection : 0 0 0 Marker setup scheme : binary files (MATLAB) Velocity interpolation scheme : STAG (linear) Marker control type : subgrid Markers per cell [nx, ny, nz] : [3, 3, 3] Marker distribution type : random noise -------------------------------------------------------------------------- Loading markers in parallel from file(s) <./markers/mdb> ... done (0.0188704 sec) -------------------------------------------------------------------------- Output parameters: Output file name : output Write .pvd file : yes Phase @ Density @ Total effective viscosity @ Creep effective viscosity @ Velocity @ Pressure @ Temperature @ Deviatoric stress second invariant @ Deviatoric strain rate second invariant @ Accumulated Plastic Strain (APS) @ Plastic dissipation @ -------------------------------------------------------------------------- Preconditioner parameters: Matrix type : monolithic Penalty parameter (pgamma) : 1.000000e+04 Preconditioner type : user-defined -------------------------------------------------------------------------- Solver parameters specified: Outermost Krylov solver : gmres Solver type : serial direct/lu Solver package : petsc -------------------------------------------------------------------------- ============================== INITIAL GUESS ============================= -------------------------------------------------------------------------- 0 SNES Function norm 6.393044702118e+02 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 2.413649416428e-05 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 1 SNES solution time : 0.1132 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.200897975778e-08 |Div|_2 = 1.660173010745e-07 Momentum: |mRes|_2 = 2.413592320169e-05 -------------------------------------------------------------------------- Saving output ... done (0.06108 sec) -------------------------------------------------------------------------- ================================= STEP 1 ================================= -------------------------------------------------------------------------- Current time : 0.00000000 [Myr] Tentative time step : 0.01000000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.737185888950e-04 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 7.909405401951e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.070854 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.941791100812e-20 |Div|_2 = 2.648466724691e-19 Momentum: |mRes|_2 = 7.909405401950e-13 -------------------------------------------------------------------------- Actual time step : 0.01100 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 6.8165e-03 s -------------------------------------------------------------------------- Saving output ... done (0.0029847 sec) -------------------------------------------------------------------------- ================================= STEP 2 ================================= -------------------------------------------------------------------------- Current time : 0.01100000 [Myr] Tentative time step : 0.01100000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.574518750000e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 5.570749594412e-04 1 MMFD ||F||/||F0||=1.558461e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 8.105712740231e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.147873 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.628519439703e-19 |Div|_2 = 4.784081921007e-18 Momentum: |mRes|_2 = 8.105712740090e-13 -------------------------------------------------------------------------- Actual time step : 0.01210 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.3385e-03 s -------------------------------------------------------------------------- ================================= STEP 3 ================================= -------------------------------------------------------------------------- Current time : 0.02310000 [Myr] Tentative time step : 0.01210000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 3.931970625000e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 6.217537768742e-04 1 MMFD ||F||/||F0||=1.581278e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 9.815103006560e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.147307 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.893071014070e-19 |Div|_2 = 2.019858400112e-17 Momentum: |mRes|_2 = 9.815103004482e-13 -------------------------------------------------------------------------- Actual time step : 0.01331 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.3877e-03 s -------------------------------------------------------------------------- ================================= STEP 4 ================================= -------------------------------------------------------------------------- Current time : 0.03641000 [Myr] Tentative time step : 0.01331000 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.325167687500e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 6.948114520452e-04 1 MMFD ||F||/||F0||=1.606438e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.474618623561e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.150714 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 2.280279642912e-18 |Div|_2 = 6.657390196669e-17 Momentum: |mRes|_2 = 1.474618622058e-12 -------------------------------------------------------------------------- Actual time step : 0.01464 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.3039e-03 s -------------------------------------------------------------------------- ================================= STEP 5 ================================= -------------------------------------------------------------------------- Current time : 0.05105100 [Myr] Tentative time step : 0.01464100 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 4.757684456250e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 7.774960333450e-04 1 MMFD ||F||/||F0||=1.634190e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.229873759688e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.148848 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 6.782738974948e-18 |Div|_2 = 1.972891308420e-16 Momentum: |mRes|_2 = 1.229873743864e-12 -------------------------------------------------------------------------- Actual time step : 0.01611 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 8.0252e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00303883 sec) -------------------------------------------------------------------------- ================================= STEP 6 ================================= -------------------------------------------------------------------------- Current time : 0.06715610 [Myr] Tentative time step : 0.01610510 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.233452901875e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 8.712694273999e-04 1 MMFD ||F||/||F0||=1.664808e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.980090592368e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.152744 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.736094906320e-17 |Div|_2 = 5.030690098929e-16 Momentum: |mRes|_2 = 1.980090528462e-12 -------------------------------------------------------------------------- Actual time step : 0.01772 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.9151e-03 s -------------------------------------------------------------------------- ================================= STEP 7 ================================= -------------------------------------------------------------------------- Current time : 0.08487171 [Myr] Tentative time step : 0.01771561 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 5.756798192062e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 9.778484495800e-04 1 MMFD ||F||/||F0||=1.698598e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 3.077044639322e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.155644 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.224430373049e-17 |Div|_2 = 1.219593113430e-15 Momentum: |mRes|_2 = 3.077044397628e-12 -------------------------------------------------------------------------- Actual time step : 0.01949 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 6.8336e-03 s -------------------------------------------------------------------------- ================================= STEP 8 ================================= -------------------------------------------------------------------------- Current time : 0.10435888 [Myr] Tentative time step : 0.01948717 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.332478011267e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.099254429716e-03 1 MMFD ||F||/||F0||=1.735899e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 5.802078258043e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.160839 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 9.377977893964e-17 |Div|_2 = 2.697889144902e-15 Momentum: |mRes|_2 = 5.802077630802e-12 -------------------------------------------------------------------------- Actual time step : 0.02144 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.9001e-03 s -------------------------------------------------------------------------- ================================= STEP 9 ================================= -------------------------------------------------------------------------- Current time : 0.12579477 [Myr] Tentative time step : 0.02143589 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 6.965725812390e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.237873265152e-03 1 MMFD ||F||/||F0||=1.777092e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 9.703045482016e-12 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.160138 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 1.887771382971e-16 |Div|_2 = 5.412451633288e-15 Momentum: |mRes|_2 = 9.703043972458e-12 -------------------------------------------------------------------------- Actual time step : 0.02358 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 6.9732e-03 s -------------------------------------------------------------------------- ================================ STEP 10 ================================= -------------------------------------------------------------------------- Current time : 0.14937425 [Myr] Tentative time step : 0.02357948 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 7.662298393624e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.396528263531e-03 1 MMFD ||F||/||F0||=1.822597e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 1.630020986564e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.155275 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 3.358031128665e-16 |Div|_2 = 9.597041729495e-15 Momentum: |mRes|_2 = 1.630020704043e-11 -------------------------------------------------------------------------- Actual time step : 0.02594 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.2206e-03 s -------------------------------------------------------------------------- Saving output ... done (0.00288675 sec) -------------------------------------------------------------------------- ================================ STEP 11 ================================= -------------------------------------------------------------------------- Current time : 0.17531167 [Myr] Tentative time step : 0.02593742 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.428528232978e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.578568656468e-03 1 MMFD ||F||/||F0||=1.872888e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 2 SNES Function norm 2.119068779225e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 2 SNES solution time : 0.144126 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.542541590545e-12 |Div|_2 = 1.294400678386e-10 Momentum: |mRes|_2 = 2.119068383893e-07 -------------------------------------------------------------------------- Actual time step : 0.02853 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.4179e-03 s -------------------------------------------------------------------------- ================================ STEP 12 ================================= -------------------------------------------------------------------------- Current time : 0.20384284 [Myr] Tentative time step : 0.02853117 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 8.022627154999e+00 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 1.546978365004e-03 1 MMFD ||F||/||F0||=1.928269e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 2 SNES Function norm 2.077873730058e-07 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < rtol*||F_initial|| Number of iterations : 2 SNES solution time : 0.147178 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 4.333885978226e-12 |Div|_2 = 1.231809114418e-10 Momentum: |mRes|_2 = 2.077873364937e-07 -------------------------------------------------------------------------- Actual time step : 0.03138 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.1631e-03 s -------------------------------------------------------------------------- ================================ STEP 13 ================================= -------------------------------------------------------------------------- Current time : 0.23522712 [Myr] Tentative time step : 0.03138428 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.141077963088e-07 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 1 SNES Function norm 5.648011532687e-13 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 1 SNES solution time : 0.0798501 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.365915719871e-22 |Div|_2 = 1.519183996506e-20 Momentum: |mRes|_2 = 5.648011532687e-13 -------------------------------------------------------------------------- Actual time step : 0.03452 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation to internal free surface. Phase that is currently being sedimented is 1 Applying sedimentation at constant rate (0.500000 [cm/yr]) to internal free surface. Applying sedimentation at constant level (0.000000e+00 [km]) to internal free surface. Performing marker control (subgrid algorithm) Marker control [0]: (subgrid) cloned 0 markers and merged 0 markers in 7.3764e-03 s -------------------------------------------------------------------------- ================================ STEP 14 ================================= -------------------------------------------------------------------------- Current time : 0.26974983 [Myr] Tentative time step : 0.03452271 [Myr] -------------------------------------------------------------------------- 0 SNES Function norm 2.266564449274e+01 0 PICARD ||F||/||F0||=1.000000e+00 Linear js_ solve converged due to CONVERGED_RTOL iterations 1 1 SNES Function norm 4.726128155180e-03 1 MMFD ||F||/||F0||=2.085151e-04 Linear js_ solve converged due to CONVERGED_RTOL iterations 2 2 SNES Function norm 8.767999874851e-11 -------------------------------------------------------------------------- SNES Convergence Reason : ||F|| < atol Number of iterations : 2 SNES solution time : 0.170011 (sec) -------------------------------------------------------------------------- Residual summary: Continuity: |Div|_inf = 5.585712124086e-15 |Div|_2 = 6.322437502279e-14 Momentum: |mRes|_2 = 8.767997595356e-11 -------------------------------------------------------------------------- Actual time step : 0.03797 [Myr] -------------------------------------------------------------------------- Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Applying sedimentation model (1) to internal free surface. Appl PkgEval terminated after 1876.81s: test log exceeded the size limit