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"planemo upload for repository https://github.com/ESCOMP/CESM commit 5c969e494841237de0b2301520d9321672cc9f5b"
| author | climate |
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| date | Tue, 15 Jun 2021 09:39:23 +0000 |
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CAM atmosphere model initialization Initialize PIO subsystem: iotype = 6 ------------------------------------------ *********** CAM LOG OUTPUT *************** ------------------------------------------ Initial run ********** CASE = FKESSLER ********** UNSET ********** Time Manager Configuration ********** Calendar type: NO_LEAP Timestep size (seconds): 1800 Start date (yr mon day tod): 1 1 1 0 Stop date (yr mon day tod): 1 1 1 1800 Reference date (yr mon day tod): 1 1 1 0 Current step number: 0 Current date (yr mon day tod): 1 1 1 0 ************************************************ SPMD SWAP_COMM OPTIONS: swap_comm_protocol = 4 swap_comm_maxreq = 128 SPMD FLOW CONTROL GATHER OPTION: fc_gather_flow_cntl = 64 PHYS_GRID options: Using PCOLS = 16 phys_loadbalance = 2 phys_twin_algorithm = 0 phys_alltoall = -1 chunks_per_thread = 1 cam_initfiles_readnl options: Initial run will start from: /opt/uio/tmp/tmp92gxhvfo/job_working_directory/000/2/working/inputdata/atm/cam/inic/cam_vcoords_L30_c180105.nc Topography dataset not used: PHIS, SGH, SGH30, LANDM_COSLAT set to zero Maximum abs value of scale factor used to perturb initial conditions, pertlim= 0.0000000000000000 Summary of constituent module options: Read constituent initial values from initial file by default: T Read in cam_history_nl namelist from: atm_in Unless overridden by namelist input on a per-field basis (FINCL), All fields on history file 1 will have averaging flag I Initial conditions history files will be written yearly. chem_surfvals_readnl: Settings for control of GHG surface values scenario_ghg = FIXED CO2 will be fixed: co2vmr = -1.0000000000000000 Other GHG values will be fixed as follows: n2ovmr = -1.0000000000000000 ch4vmr = -1.0000000000000000 f11vmr = -1.0000000000000000 f12vmr = -1.0000000000000000 Run model with Kessler warm-rain physics forcing check_energy options: print_energy_errors = F Read in analytic_ic_nl namelist from: atm_in Dynamics state will be set to a moist baroclinic wave initial condition used in DCMIP 2016. dyn_readnl: reading dyn_se_inparm namelist... initmpi: Number of MPI processes: 4 INITOMP: INFO: openmp not activated HOMME_POSTPROCESS_NAMELIST: omp_get_max_threads() = 1 HOMME_POSTPROCESS_NAMELIST: Mesh File:none HOMME_POSTPROCESS_NAMELIST: Reference element projection: cubed_sphere_map= 0 dyn_readnl: se_ftype = 2 dyn_readnl: se_statediag_numtrac = 3 dyn_readnl: se_hypervis_subcycle = 3 dyn_readnl: se_hypervis_subcycle_q = 1 dyn_readnl: se_limiter_option = 8 dyn_readnl: se_ne = 30 dyn_readnl: se_npes = 4 dyn_readnl: se_nsplit = 2 dyn_readnl: se_nu = 0.40E+15 dyn_readnl: se_nu_div = 0.10E+16 dyn_readnl: se_nu_p = 0.10E+16 Note that nu_q=nu_p for mass / tracer inconsistency dyn_readnl: se_nu_top = 0.25E+06 dyn_readnl: se_qsplit = 1 dyn_readnl: se_rsplit = 3 dyn_readnl: se_statefreq = 0 dyn_readnl: se_tstep_type = 4 dyn_readnl: se_vert_remap_q_alg = 1 dyn_readnl: se_qsize_condensate_loading = 1 : lcp_moist = T dyn_readnl: hypervis_on_plevs = T FYI: nu_p>0 and hypervis_on_plevs=T => hypervis is applied to dp-dp_ref dyn_readnl: Nudging off dyn_readnl: physics will run on SE GLL points dyn_readnl: se_horz_num_threads = 1 dyn_readnl: se_vert_num_threads = 1 dyn_readnl: se_tracer_num_threads = 1 dyn_readnl: do not write grid file dyn_readnl: write gll corners to SEMapping.nc = F dyn_readnl: write restart data on unstructured grid = F native_mapping_readnl: Check for native_mapping_nl namelist in atm_in native_mapping_readnl: No native_mapping_nl namelist found qneg_readnl: QNEG statistics will be collected and printed at the end of the run (GETFIL): attempting to find local file cam_vcoords_L30_c180105.nc (GETFIL): using /opt/uio/tmp/tmp92gxhvfo/job_working_directory/000/2/working/inputdata/atm/cam/inic/cam_vcoords_L30_c180105.nc hycoef_read: read hyai, hybi, hyam, hybm hycoef_read: read P0 value: 100000.00000000000 Layer Locations (*1000) 1 2.2552 0.0000 2.2552 3.6435 0.0000 3.6435 2 5.0317 0.0000 5.0317 7.5948 0.0000 7.5948 3 10.1579 0.0000 10.1579 14.3566 0.0000 14.3566 4 18.5553 0.0000 18.5553 24.6122 0.0000 24.6122 5 30.6691 0.0000 30.6691 38.2683 0.0000 38.2683 6 45.8675 0.0000 45.8675 54.5955 0.0000 54.5955 7 63.3235 0.0000 63.3235 72.0125 0.0000 72.0125 8 80.7014 0.0000 80.7014 87.8212 0.0000 87.8212 9 94.9410 0.0000 94.9410 103.3171 0.0000 103.3171 10 111.6932 0.0000 111.6932 121.5472 0.0000 121.5472 11 131.4013 0.0000 131.4013 142.9940 0.0000 142.9940 12 154.5868 0.0000 154.5868 168.2251 0.0000 168.2251 13 181.8634 0.0000 181.8634 178.2307 19.6774 197.9081 14 174.5980 39.3548 213.9528 170.3243 62.5043 232.8286 15 166.0507 85.6538 251.7044 161.0229 112.8879 273.9108 16 155.9952 140.1221 296.1172 150.0803 172.1616 322.2419 17 144.1654 204.2012 348.3666 137.2069 241.8940 379.1009 18 130.2483 279.5869 409.8352 122.0619 323.9306 445.9926 19 113.8756 368.2744 482.1499 104.2447 420.4425 524.6872 20 94.6139 472.6106 567.2244 84.9792 524.7995 609.7787 21 75.3445 576.9885 652.3330 66.5017 624.8877 691.3894 22 57.6589 672.7870 730.4459 50.1968 713.2077 763.4045 23 42.7346 753.6284 796.3631 37.1887 783.6697 820.8584 24 31.6427 813.7110 845.3537 28.4319 831.1028 859.5348 25 25.2212 848.4946 873.7159 22.2090 864.8113 887.0202 26 19.1967 881.1279 900.3246 16.4074 896.2372 912.6445 27 13.6180 911.3464 924.9645 11.0746 925.1238 936.1984 28 8.5311 938.9012 947.4323 6.2550 951.2305 957.4855 29 3.9788 963.5598 967.5386 1.9894 974.3360 976.3254 30 0.0000 985.1122 985.1122 0.0000 992.5561 992.5561 31 0.0000 1000.0000 1000.0000 reference pressures (Pa) 1 225.5240 364.3466 277.6452 2 503.1692 759.4820 512.6256 3 1015.7947 1435.6632 839.7370 4 1855.5317 2461.2220 1211.3806 5 3066.9123 3826.8300 1519.8354 6 4586.7477 5459.5480 1745.6006 7 6332.3483 7201.2451 1737.7935 8 8070.1418 8782.1230 1423.9624 9 9494.1042 10331.7127 1675.2169 10 11169.3211 12154.7241 1970.8060 11 13140.1271 14299.4039 2318.5536 12 15458.6807 16822.5080 2727.6546 13 18186.3353 19790.8087 3208.9468 14 21395.2821 23282.8619 3775.1596 15 25170.4417 27391.0817 4441.2799 16 29611.7216 32224.1902 5224.9372 17 34836.6588 37910.0904 6146.8631 18 40983.5219 44599.2574 7231.4709 19 48214.9929 52468.7175 8507.4492 20 56722.4421 60977.8695 8510.8548 21 65233.2969 69138.9430 7811.2923 22 73044.5892 76340.4481 6591.7179 23 79636.3071 82085.8369 4899.0596 24 84535.3667 85953.4767 2836.2200 25 87371.5866 88702.0249 2660.8765 26 90032.4631 91264.4547 2463.9831 27 92496.4462 93619.8398 2246.7872 28 94743.2335 95748.5480 2010.6290 29 96753.8625 97632.5407 1757.3566 30 98511.2190 99255.6095 1488.7810 31 100000.0000 PRIM_INIT1: creating cube topology... ...done. PRIM_INIT1: total number of elements nelem = 5400 PRIM_INIT1: partitioning graph using SF Curve... PRIM_INIT1: init shared boundary_exchange buffers PRIM_INIT1: initializing cube elements... PRIM_INIT1: running mass_matrix PRIM_INIT1: re-initializing cube elements: area correction= 0.99999999999943145 PRIM_INIT1: re-running mass_matrix PRIM_INIT1: running global_dof PRIM_INIT1: max_num_threads= 1 PRIM_INIT1: end of prim_init Grid: GLL, ID = 101, lat coord = lat, lon coord = lon, unstruct = T, block_ind = F, zonal_grid = F Attribute: area, long name = 'gll grid areas' dimname = ncol Attribute: np, long name = '' value = 4 Attribute: ne, long name = '' value = 30 INFO: Non-scalable action: Allocating global blocks in SE dycore. create_global_coords: INFO: Non-scalable action: Creating global coords in SE dycore. create_global_area: INFO: Non-scalable action: gathering global area in SE dycore. Grid: physgrid, ID = 100, lat coord = lat, lon coord = lon, unstruct = T, block_ind = T, zonal_grid = F Attribute: area, long name = 'gll grid areas' dimname = ncol Attribute: np, long name = '' value = 4 Attribute: ne, long name = '' value = 30 Advected constituent list: 1 Q Specific humidity wet 2 CLDLIQ Grid box averaged cloud liquid amount wet 3 RAINQM Grid box averaged rain water amount wet 4 CL CL dry 5 CL2 CL2 dry 6 RHO RHO dry PHIS initialized by "BC_WAV_SET_IC" U initialized by "BC_WAV_SET_IC" V initialized by "BC_WAV_SET_IC" T initialized by "BC_WAV_SET_IC" BC_WAV_SET_IC: Model top (in km) is at z= 35.087419572768717 PS initialized by "BC_WAV_SET_IC" Q initialized by "BC_WAV_SET_IC" CLDLIQ set to minimum value RAINQM set to minimum value CL initialized by "chem_init_cnst" CL2 initialized by "chem_init_cnst" RHO initialized by "chem_init_cnst" Running Global Integral Diagnostic... Area of unit sphere is 1.0000000000000000 Should be 1.0 to round off... Element area: max/min 1.377 Average equatorial node spacing (deg, km) = 1.000 111.20 norm of Dinv (min, max): 38.302 57.296 Max Dinv-based element distortion: 1.73 dx based on Dinv svd: ave,min,max = 91.40 74.13 110.90 dx based on sqrt element area: ave,min,max = 102.45 94.71 111.15 CFL estimates in terms of S=time step stability region (i.e. advection w/leapfrog: S=1, viscosity w/forward Euler: S=2) SSP preservation (120m/s) RKSSP euler step dt < S * 154.44s Stability: advective (120m/s) dt_tracer < S * 338.20s Stability: advective (120m/s) dt_tracer < S * 338.20s Stability: gravity wave(342m/s) dt_dyn < S * 118.67s Stability: nu_q hyperviscosity dt < S * 169.89s Stability: nu_vor hyperviscosity dt < S * 424.71s Stability: nu_div hyperviscosity dt < S * 169.89s TOP3 viscosity CFL: dt < S* 412.17s tstep_type = 4 dt_remap: (0=disabled) 900.00 dt_tracer (SE), per RK stage: 300.00 150.00 dt_dyn: 300.00 dt_dyn (viscosity): 100.00 dt_tracer (viscosity): 300.00 CAM dtime (dt_phys): 1800.00 CAM-SE uses dry-mass vertical coordinates initial state: nstep= 0 time= 0.0000000000000000 [day] STATE DIAGNOSTICS MIN MAX AVE (hPa) REL. MASS. CHANGE U 0.000000000000000E+00 0.280261013339374E+02 V 0.000000000000000E+00 0.000000000000000E+00 T 0.149843161781875E+03 0.306211834562973E+03 OMEGA -0.224996632776289E+00 0.279838208014316E+00 PSDRY 0.994576161327842E+05 0.999999999999894E+05 0.996842241887747E+03 0.000000000000000E+00 PS 0.999999958842053E+05 0.100000000000089E+06 0.999999986178254E+03 0.000000000000000E+00 Q 0.100000000000100E-11 0.183316201758619E-01 0.315774429050680E+01 0.000000000000000E+00 CLDLIQ 0.000000000000000E+00 0.000000000000000E+00 0.000000000000000E+00 0.000000000000000E+00 RAINQM 0.000000000000000E+00 0.000000000000000E+00 0.000000000000000E+00 0.000000000000000E+00 FORCING DIAGNOSTICS MIN MAX FT 0.000000000000000E+00 0.000000000000000E+00 FM 0.000000000000000E+00 0.000000000000000E+00 FQ 0.000000000000000E+00 0.000000000000000E+00 FCLDLIQ 0.000000000000000E+00 0.000000000000000E+00 FRAINQM 0.000000000000000E+00 0.000000000000000E+00 *** SATURATION VAPOR PRESSURE TABLE COMPLETED *** ******* MASTER FIELD LIST ******* 1 FU m/s2 30 A Zonal wind forcing term on GLL grid 2 FV m/s2 30 A Meridional wind forcing term on GLL grid 3 FT K/s 30 A Temperature forcing term on GLL grid 4 FQ_gll kg/kg/s 30 I Specific humidity mixing ratio forcing term (q_new-q_old) on GLL grid 5 FCLDLIQ_gll kg/kg/s 30 I Grid box averaged cloud liquid amount mixing ratio forcing term (q_new-q_old) on GLL grid 6 FRAINQM_gll kg/kg/s 30 I Grid box averaged rain water amount mixing ratio forcing term (q_new-q_old) on GLL grid 7 FCL_gll kg/kg/s 30 I CL mixing ratio forcing term (q_new-q_old) on GLL grid 8 FCL2_gll kg/kg/s 30 I CL2 mixing ratio forcing term (q_new-q_old) on GLL grid 9 FRHO_gll kg/kg/s 30 I RHO mixing ratio forcing term (q_new-q_old) on GLL grid 10 ABS_dPSdt Pa/s 1 A Absolute surface pressure tendency 11 WV_PDC kg/m2 1 A Total column water vapor lost in physics-dynamics coupling 12 WL_PDC kg/m2 1 A Total column cloud water lost in physics-dynamics coupling 13 WI_PDC kg/m2 1 A Total column cloud ice lost in physics-dynamics coupling 14 TT_PDC kg/m2 1 A Total column test tracer lost in physics-dynamics coupling 15 WV_dED kg/m2 1 A Total column water vaporend of previous dynamics 16 WL_dED kg/m2 1 A Total column cloud waterend of previous dynamics 17 WI_dED kg/m2 1 A Total column cloud iceend of previous dynamics 18 SE_dED J/m2 1 A Total column dry static energyend of previous dynamics 19 KE_dED J/m2 1 A Total column kinetic energyend of previous dynamics 20 MR_dED kg*m2/s*rad2 1 A Total column wind axial angular momentumend of previous dynamics 21 MO_dED kg*m2/s*rad2 1 A Total column mass axial angular momentumend of previous dynamics 22 TT_dED kg/m2 1 A Total column test tracerend of previous dynamics 23 WV_dAF kg/m2 1 A Total column water vaporfrom previous remapping or state passed to dynamics 24 WL_dAF kg/m2 1 A Total column cloud waterfrom previous remapping or state passed to dynamics 25 WI_dAF kg/m2 1 A Total column cloud icefrom previous remapping or state passed to dynamics 26 SE_dAF J/m2 1 A Total column dry static energyfrom previous remapping or state passed to dynamics 27 KE_dAF J/m2 1 A Total column kinetic energyfrom previous remapping or state passed to dynamics 28 MR_dAF kg*m2/s*rad2 1 A Total column wind axial angular momentumfrom previous remapping or state passed to dynamics 29 MO_dAF kg*m2/s*rad2 1 A Total column mass axial angular momentumfrom previous remapping or state passed to dynamics 30 TT_dAF kg/m2 1 A Total column test tracerfrom previous remapping or state passed to dynamics 31 WV_dBD kg/m2 1 A Total column water vaporstate after applying CAM forcing 32 WL_dBD kg/m2 1 A Total column cloud waterstate after applying CAM forcing 33 WI_dBD kg/m2 1 A Total column cloud icestate after applying CAM forcing 34 SE_dBD J/m2 1 A Total column dry static energystate after applying CAM forcing 35 KE_dBD J/m2 1 A Total column kinetic energystate after applying CAM forcing 36 MR_dBD kg*m2/s*rad2 1 A Total column wind axial angular momentumstate after applying CAM forcing 37 MO_dBD kg*m2/s*rad2 1 A Total column mass axial angular momentumstate after applying CAM forcing 38 TT_dBD kg/m2 1 A Total column test tracerstate after applying CAM forcing 39 WV_dAD kg/m2 1 A Total column water vaporbefore vertical remapping 40 WL_dAD kg/m2 1 A Total column cloud waterbefore vertical remapping 41 WI_dAD kg/m2 1 A Total column cloud icebefore vertical remapping 42 SE_dAD J/m2 1 A Total column dry static energybefore vertical remapping 43 KE_dAD J/m2 1 A Total column kinetic energybefore vertical remapping 44 MR_dAD kg*m2/s*rad2 1 A Total column wind axial angular momentumbefore vertical remapping 45 MO_dAD kg*m2/s*rad2 1 A Total column mass axial angular momentumbefore vertical remapping 46 TT_dAD kg/m2 1 A Total column test tracerbefore vertical remapping 47 WV_dAR kg/m2 1 A Total column water vaporafter vertical remapping 48 WL_dAR kg/m2 1 A Total column cloud waterafter vertical remapping 49 WI_dAR kg/m2 1 A Total column cloud iceafter vertical remapping 50 SE_dAR J/m2 1 A Total column dry static energyafter vertical remapping 51 KE_dAR J/m2 1 A Total column kinetic energyafter vertical remapping 52 MR_dAR kg*m2/s*rad2 1 A Total column wind axial angular momentumafter vertical remapping 53 MO_dAR kg*m2/s*rad2 1 A Total column mass axial angular momentumafter vertical remapping 54 TT_dAR kg/m2 1 A Total column test tracerafter vertical remapping 55 WV_dBF kg/m2 1 A Total column water vaporstate passed to parameterizations 56 WL_dBF kg/m2 1 A Total column cloud waterstate passed to parameterizations 57 WI_dBF kg/m2 1 A Total column cloud icestate passed to parameterizations 58 SE_dBF J/m2 1 A Total column dry static energystate passed to parameterizations 59 KE_dBF J/m2 1 A Total column kinetic energystate passed to parameterizations 60 MR_dBF kg*m2/s*rad2 1 A Total column wind axial angular momentumstate passed to parameterizations 61 MO_dBF kg*m2/s*rad2 1 A Total column mass axial angular momentumstate passed to parameterizations 62 TT_dBF kg/m2 1 A Total column test tracerstate passed to parameterizations 63 WV_dBH kg/m2 1 A Total column water vaporstate before hypervis 64 WL_dBH kg/m2 1 A Total column cloud waterstate before hypervis 65 WI_dBH kg/m2 1 A Total column cloud icestate before hypervis 66 SE_dBH J/m2 1 A Total column dry static energystate before hypervis 67 KE_dBH J/m2 1 A Total column kinetic energystate before hypervis 68 MR_dBH kg*m2/s*rad2 1 A Total column wind axial angular momentumstate before hypervis 69 MO_dBH kg*m2/s*rad2 1 A Total column mass axial angular momentumstate before hypervis 70 TT_dBH kg/m2 1 A Total column test tracerstate before hypervis 71 WV_dCH kg/m2 1 A Total column water vaporstate after hypervis but before adding heating term 72 WL_dCH kg/m2 1 A Total column cloud waterstate after hypervis but before adding heating term 73 WI_dCH kg/m2 1 A Total column cloud icestate after hypervis but before adding heating term 74 SE_dCH J/m2 1 A Total column dry static energystate after hypervis but before adding heating term 75 KE_dCH J/m2 1 A Total column kinetic energystate after hypervis but before adding heating term 76 MR_dCH kg*m2/s*rad2 1 A Total column wind axial angular momentumstate after hypervis but before adding heating term 77 MO_dCH kg*m2/s*rad2 1 A Total column mass axial angular momentumstate after hypervis but before adding heating term 78 TT_dCH kg/m2 1 A Total column test tracerstate after hypervis but before adding heating term 79 WV_dAH kg/m2 1 A Total column water vaporstate after hypervis 80 WL_dAH kg/m2 1 A Total column cloud waterstate after hypervis 81 WI_dAH kg/m2 1 A Total column cloud icestate after hypervis 82 SE_dAH J/m2 1 A Total column dry static energystate after hypervis 83 KE_dAH J/m2 1 A Total column kinetic energystate after hypervis 84 MR_dAH kg*m2/s*rad2 1 A Total column wind axial angular momentumstate after hypervis 85 MO_dAH kg*m2/s*rad2 1 A Total column mass axial angular momentumstate after hypervis 86 TT_dAH kg/m2 1 A Total column test tracerstate after hypervis 87 WV_p2d kg/m2 1 A Total column water vaporphys2dyn mapping errors (requires ftype-1) 88 WL_p2d kg/m2 1 A Total column cloud waterphys2dyn mapping errors (requires ftype-1) 89 WI_p2d kg/m2 1 A Total column cloud icephys2dyn mapping errors (requires ftype-1) 90 SE_p2d J/m2 1 A Total column dry static energyphys2dyn mapping errors (requires ftype-1) 91 KE_p2d J/m2 1 A Total column kinetic energyphys2dyn mapping errors (requires ftype-1) 92 MR_p2d kg*m2/s*rad2 1 A Total column wind axial angular momentumphys2dyn mapping errors (requires ftype-1) 93 MO_p2d kg*m2/s*rad2 1 A Total column mass axial angular momentumphys2dyn mapping errors (requires ftype-1) 94 TT_p2d kg/m2 1 A Total column test tracerphys2dyn mapping errors (requires ftype-1) 95 Q kg/kg 30 A Specific humidity 96 NSTEP timestep 1 A Model timestep 97 PHIS m2/s2 1 I Surface geopotential 98 PS Pa 1 A Surface pressure 99 T K 30 A Temperature 100 U m/s 30 A Zonal wind 101 V m/s 30 A Meridional wind 102 TBP K 30 A Temperature (before physics) 103 QBP kg/kg 30 A Specific humidity (before physics) 104 TAP K 30 A Temperature (after physics) 105 UAP m/s 30 A Zonal wind (after physics) 106 VAP m/s 30 A Meridional wind (after physics) 107 QAP kg/kg 30 A Specific humidity (after physics) 108 TFIX K/s 1 A T fixer (T equivalent of Energy correction) 109 TTEND_TOT K/s 30 A Total temperature tendency 110 Z3 m 30 A Geopotential Height (above sea level) 111 Z1000 m 1 A Geopotential Z at 1000 mbar pressure surface 112 Z700 m 1 A Geopotential Z at 700 mbar pressure surface 113 Z500 m 1 A Geopotential Z at 500 mbar pressure surface 114 Z300 m 1 A Geopotential Z at 300 mbar pressure surface 115 Z200 m 1 A Geopotential Z at 200 mbar pressure surface 116 Z100 m 1 A Geopotential Z at 100 mbar pressure surface 117 Z050 m 1 A Geopotential Z at 50 mbar pressure surface 118 ZZ m2 30 A Eddy height variance 119 VZ m2/s 30 A Meridional transport of geopotential height 120 VT K m/s 30 A Meridional heat transport 121 VU m2/s2 30 A Meridional flux of zonal momentum 122 VV m2/s2 30 A Meridional velocity squared 123 OMEGAV m Pa/s2 30 A Vertical flux of meridional momentum 124 OMGAOMGA Pa2/s2 30 A Vertical flux of vertical momentum 125 UU m2/s2 30 A Zonal velocity squared 126 WSPEED m/s 30 X Horizontal total wind speed maximum 127 WSPDSRFMX m/s 1 X Horizontal total wind speed maximum at the surface 128 WSPDSRFAV m/s 1 A Horizontal total wind speed average at the surface 129 OMEGA Pa/s 30 A Vertical velocity (pressure) 130 OMEGAT K Pa/s 30 A Vertical heat flux 131 OMEGAU m Pa/s2 30 A Vertical flux of zonal momentum 132 OMEGA850 Pa/s 1 A Vertical velocity at 850 mbar pressure surface 133 OMEGA500 Pa/s 1 A Vertical velocity at 500 mbar pressure surface 134 PSL Pa 1 A Sea level pressure 135 T1000 K 1 A Temperature at 1000 mbar pressure surface 136 T925 K 1 A Temperature at 925 mbar pressure surface 137 T850 K 1 A Temperature at 850 mbar pressure surface 138 T700 K 1 A Temperature at 700 mbar pressure surface 139 T500 K 1 A Temperature at 500 mbar pressure surface 140 T400 K 1 A Temperature at 400 mbar pressure surface 141 T300 K 1 A Temperature at 300 mbar pressure surface 142 T200 K 1 A Temperature at 200 mbar pressure surface 143 T010 K 1 A Temperature at 10 mbar pressure surface 144 T7001000 K 1 A Temperature difference 700 mb - 1000 mb 145 TH7001000 K 1 A Theta difference 700 mb - 1000 mb 146 THE7001000 K 1 A ThetaE difference 700 mb - 1000 mb 147 T8501000 K 1 A Temperature difference 850 mb - 1000 mb 148 TH8501000 K 1 A Theta difference 850 mb - 1000 mb 149 T9251000 K 1 A Temperature difference 925 mb - 1000 mb 150 TH9251000 K 1 A Theta difference 925 mb - 1000 mb 151 TT K2 30 A Eddy temperature variance 152 U850 m/s 1 A Zonal wind at 850 mbar pressure surface 153 U500 m/s 1 A Zonal wind at 500 mbar pressure surface 154 U250 m/s 1 A Zonal wind at 250 mbar pressure surface 155 U200 m/s 1 A Zonal wind at 200 mbar pressure surface 156 U010 m/s 1 A Zonal wind at 10 mbar pressure surface 157 V850 m/s 1 A Meridional wind at 850 mbar pressure surface 158 V500 m/s 1 A Meridional wind at 500 mbar pressure surface 159 V250 m/s 1 A Meridional wind at 250 mbar pressure surface 160 V200 m/s 1 A Meridional wind at 200 mbar pressure surface 161 UBOT m/s 1 A Lowest model level zonal wind 162 VBOT m/s 1 A Lowest model level meridional wind 163 ZBOT m 1 A Lowest model level height 164 ATMEINT J/m2 1 A Vertically integrated total atmospheric energy 165 PTTEND K/s 30 A T total physics tendency 166 T_24_COS K 30 A Temperature 24hr. cos coeff. 167 T_24_SIN K 30 A Temperature 24hr. sin coeff. 168 T_12_COS K 30 A Temperature 12hr. cos coeff. 169 T_12_SIN K 30 A Temperature 12hr. sin coeff. 170 T_08_COS K 30 A Temperature 8hr. cos coeff. 171 T_08_SIN K 30 A Temperature 8hr. sin coeff. 172 U_24_COS m/s 30 A Zonal wind 24hr. cos coeff. 173 U_24_SIN m/s 30 A Zonal wind 24hr. sin coeff. 174 U_12_COS m/s 30 A Zonal wind 12hr. cos coeff. 175 U_12_SIN m/s 30 A Zonal wind 12hr. sin coeff. 176 U_08_COS m/s 30 A Zonal wind 8hr. cos coeff. 177 U_08_SIN m/s 30 A Zonal wind 8hr. sin coeff. 178 V_24_COS m/s 30 A Meridional wind 24hr. cos coeff. 179 V_24_SIN m/s 30 A Meridional wind 24hr. sin coeff. 180 V_12_COS m/s 30 A Meridional wind 12hr. cos coeff. 181 V_12_SIN m/s 30 A Meridional wind 12hr. sin coeff. 182 V_08_COS m/s 30 A Meridional wind 8hr. cos coeff. 183 V_08_SIN m/s 30 A Meridional wind 8hr. sin coeff. 184 PS_24_COS Pa 1 A surface pressure 24hr. cos coeff. 185 PS_24_SIN Pa 1 A surface pressure 24hr. sin coeff. 186 PS_12_COS Pa 1 A surface pressure 12hr. cos coeff. 187 PS_12_SIN Pa 1 A surface pressure 12hr. sin coeff. 188 PS_08_COS Pa 1 A surface pressure 8hr. cos coeff. 189 PS_08_SIN Pa 1 A surface pressure 8hr. sin coeff. 190 OMEGA_24_COS Pa/s 30 A vertical pressure velocity 24hr. cos coeff. 191 OMEGA_24_SIN Pa/s 30 A vertical pressure velocity 24hr. sin coeff. 192 OMEGA_12_COS Pa/s 30 A vertical pressure velocity 12hr. cos coeff. 193 OMEGA_12_SIN Pa/s 30 A vertical pressure velocity 12hr. sin coeff. 194 OMEGA_08_COS Pa/s 30 A vertical pressure velocity 8hr. cos coeff. 195 OMEGA_08_SIN Pa/s 30 A vertical pressure velocity 8hr. sin coeff. 196 SE_pBF J/m2 1 A Dry Static Energy before energy fixer 197 SE_pBP J/m2 1 A Dry Static Energy before parameterizations 198 SE_pAP J/m2 1 A Dry Static Energy after parameterizations 199 SE_pAM J/m2 1 A Dry Static Energy after dry mass correction 200 KE_pBF J/m2 1 A Kinetic Energy before energy fixer 201 KE_pBP J/m2 1 A Kinetic Energy before parameterizations 202 KE_pAP J/m2 1 A Kinetic Energy after parameterizations 203 KE_pAM J/m2 1 A Kinetic Energy after dry mass correction 204 TT_pBF kg/m2 1 A Total column test tracer before energy fixer 205 TT_pBP kg/m2 1 A Total column test tracer before parameterizations 206 TT_pAP kg/m2 1 A Total column test tracer after parameterizations 207 TT_pAM kg/m2 1 A Total column test tracer after dry mass correction 208 WV_pBF kg/m2 1 A Total column water vapor before energy fixer 209 WV_pBP kg/m2 1 A Total column water vapor before parameterizations 210 WV_pAP kg/m2 1 A Total column water vapor after parameterizations 211 WV_pAM kg/m2 1 A Total column water vapor after dry mass correction 212 WL_pBF kg/m2 1 A Total column cloud water before energy fixer 213 WL_pBP kg/m2 1 A Total column cloud water before parameterizations 214 WL_pAP kg/m2 1 A Total column cloud water after parameterizations 215 WL_pAM kg/m2 1 A Total column cloud water after dry mass correction 216 WI_pBF kg/m2 1 A Total column cloud ice before energy fixer 217 WI_pBP kg/m2 1 A Total column cloud ice before parameterizations 218 WI_pAP kg/m2 1 A Total column cloud ice after parameterizations 219 WI_pAM kg/m2 1 A Total column cloud ice after dry mass correction 220 MR_pBF kg*m2/s*rad2 1 A Total column wind axial angular momentum before energy fixer 221 MR_pBP kg*m2/s*rad2 1 A Total column wind axial angular momentum before parameterizations 222 MR_pAP kg*m2/s*rad2 1 A Total column wind axial angular momentum after parameterizations 223 MR_pAM kg*m2/s*rad2 1 A Total column wind axial angular momentum after dry mass correction 224 MO_pBF kg*m2/s*rad2 1 A Total column mass axial angular momentum before energy fixer 225 MO_pBP kg*m2/s*rad2 1 A Total column mass axial angular momentum before parameterizations 226 MO_pAP kg*m2/s*rad2 1 A Total column mass axial angular momentum after parameterizations 227 MO_pAM kg*m2/s*rad2 1 A Total column mass axial angular momentum after dry mass correction 228 TMCLDLIQ kg/m2 1 A CLDLIQ column burden 229 TMRAINQM kg/m2 1 A RAINQM column burden 230 TMCL kg/m2 1 A CL column burden 231 TMCL2 kg/m2 1 A CL2 column burden 232 TMRHO kg/m2 1 A RHO column burden 233 OMEGAQ kgPa/kgs 30 A Vertical water transport 234 VQ m/skg/kg 30 A Meridional water transport 235 QQ kg2/kg2 30 A Eddy moisture variance 236 MQ kg/m2 30 A Water vapor mass in layer 237 TMQ kg/m2 1 A Total (vertically integrated) precipitable water 238 RELHUM percent 30 A Relative humidity 239 RHW percent 30 A Relative humidity with respect to liquid 240 RHI percent 30 A Relative humidity with respect to ice 241 RHCFMIP percent 30 A Relative humidity with respect to water above 273 K, ice below 273 K 242 THE8501000 K 1 A ThetaE difference 850 mb - 1000 mb 243 THE9251000 K 1 A ThetaE difference 925 mb - 1000 mb 244 Q1000 kg/kg 1 A Specific Humidity at 1000 mbar pressure surface 245 Q925 kg/kg 1 A Specific Humidity at 925 mbar pressure surface 246 Q850 kg/kg 1 A Specific Humidity at 850 mbar pressure surface 247 Q200 kg/kg 1 A Specific Humidity at 700 mbar pressure surface 248 QBOT kg/kg 1 A Lowest model level water vapor mixing ratio 249 PSDRY Pa 1 A Dry surface pressure 250 PMID Pa 30 A Pressure at layer midpoints 251 PDELDRY Pa 30 A Dry pressure difference between levels 252 DTCOND K/s 30 A T tendency - moist processes 253 DTCOND_24_COS K/s 30 A T tendency - moist processes 24hr. cos coeff. 254 DTCOND_24_SIN K/s 30 A T tendency - moist processes 24hr. sin coeff. 255 DTCOND_12_COS K/s 30 A T tendency - moist processes 12hr. cos coeff. 256 DTCOND_12_SIN K/s 30 A T tendency - moist processes 12hr. sin coeff. 257 DTCOND_08_COS K/s 30 A T tendency - moist processes 8hr. cos coeff. 258 DTCOND_08_SIN K/s 30 A T tendency - moist processes 8hr. sin coeff. 259 PRECL m/s 1 A Large-scale (stable) precipitation rate (liq + ice) 260 PRECC m/s 1 A Convective precipitation rate (liq + ice) 261 PRECT m/s 1 A Total (convective and large-scale) precipitation rate (liq + ice) 262 PREC_PCW m/s 1 A LS_pcw precipitation rate 263 PREC_zmc m/s 1 A CV_zmc precipitation rate 264 PRECTMX m/s 1 X Maximum (convective and large-scale) precipitation rate (liq+ice) 265 PRECSL m/s 1 A Large-scale (stable) snow rate (water equivalent) 266 PRECSC m/s 1 A Convective snow rate (water equivalent) 267 PRECCav m/s 1 A Average large-scale precipitation (liq + ice) 268 PRECLav m/s 1 A Average convective precipitation (liq + ice) 269 SHFLX W/m2 1 A Surface sensible heat flux 270 LHFLX W/m2 1 A Surface latent heat flux 271 QFLX kg/m2/s 1 A Surface water flux 272 TAUX N/m2 1 A Zonal surface stress 273 TAUY N/m2 1 A Meridional surface stress 274 TREFHT K 1 A Reference height temperature 275 TREFHTMN K 1 M Minimum reference height temperature over output period 276 TREFHTMX K 1 X Maximum reference height temperature over output period 277 QREFHT kg/kg 1 A Reference height humidity 278 U10 m/s 1 A 10m wind speed 279 RHREFHT fraction 1 A Reference height relative humidity 280 LANDFRAC fraction 1 A Fraction of sfc area covered by land 281 ICEFRAC fraction 1 A Fraction of sfc area covered by sea-ice 282 OCNFRAC fraction 1 A Fraction of sfc area covered by ocean 283 TREFMNAV K 1 A Average of TREFHT daily minimum 284 TREFMXAV K 1 A Average of TREFHT daily maximum 285 TS K 1 A Surface temperature (radiative) 286 TSMN K 1 M Minimum surface temperature over output period 287 TSMX K 1 X Maximum surface temperature over output period 288 SNOWHLND m 1 A Water equivalent snow depth 289 SNOWHICE m 1 A Snow depth over ice 290 TBOT K 1 A Lowest model level temperature 291 ASDIR 1 1 A albedo: shortwave, direct 292 ASDIF 1 1 A albedo: shortwave, diffuse 293 ALDIR 1 1 A albedo: longwave, direct 294 ALDIF 1 1 A albedo: longwave, diffuse 295 SST K 1 A sea surface temperature 296 PTEQ kg/kg/s 30 A Q total physics tendency 297 PTECLDLIQ kg/kg/s 30 A CLDLIQ total physics tendency 298 QCWAT&IC kg/kg 30 I q associated with cloud water 299 TCWAT&IC kg/kg 30 I T associated with cloud water 300 LCWAT&IC kg/kg 30 I Cloud water (ice + liq 301 CLOUD&IC fraction 30 I Cloud fraction 302 CONCLD&IC fraction 30 I Convective cloud fraction 303 TKE&IC m2/s2 31 I Turbulent Kinetic Energy 304 CUSH&IC m 1 I Convective Scale Height 305 KVH&IC m2/s 31 I Vertical diffusion diffusivities (heat/moisture) 306 KVM&IC m2/s 31 I Vertical diffusion diffusivities (momentum) 307 PBLH&IC m 1 I PBL height 308 TPERT&IC K 1 I Perturbation temperature (eddies in PBL) 309 QPERT&IC kg/kg 1 I Perturbation specific humidity (eddies in PBL) 310 a2x_BCPHIWET kg/m2/s 1 A wetdep of hydrophilic black carbon 311 a2x_BCPHIDRY kg/m2/s 1 A drydep of hydrophilic black carbon 312 a2x_BCPHODRY kg/m2/s 1 A drydep of hydrophobic black carbon 313 a2x_OCPHIWET kg/m2/s 1 A wetdep of hydrophilic organic carbon 314 a2x_OCPHIDRY kg/m2/s 1 A drydep of hydrophilic organic carbon 315 a2x_OCPHODRY kg/m2/s 1 A drydep of hydrophobic organic carbon 316 a2x_DSTWET1 kg/m2/s 1 A wetdep of dust (bin1) 317 a2x_DSTDRY1 kg/m2/s 1 A drydep of dust (bin1) 318 a2x_DSTWET2 kg/m2/s 1 A wetdep of dust (bin2) 319 a2x_DSTDRY2 kg/m2/s 1 A drydep of dust (bin2) 320 a2x_DSTWET3 kg/m2/s 1 A wetdep of dust (bin3) 321 a2x_DSTDRY3 kg/m2/s 1 A drydep of dust (bin3) 322 a2x_DSTWET4 kg/m2/s 1 A wetdep of dust (bin4) 323 a2x_DSTDRY4 kg/m2/s 1 A drydep of dust (bin4) 324 DCQ kg/kg/s 30 A Q tendency due to moist processes 325 TEINP J/m2 1 A Total energy of physics input 326 TEOUT J/m2 1 A Total energy of physics output 327 TEFIX J/m2 1 A Total energy after fixer 328 EFIX W/m2 1 A Effective sensible heat flux due to energy fixer 329 DTCORE K/s 30 A T tendency due to dynamical core 330 CLDLIQ kg/kg 30 A Grid box averaged cloud liquid amount 331 RAINQM kg/kg 30 A Grid box averaged rain water amount 332 CLDLIQBP kg/kg 30 A Grid box averaged cloud liquid amount (before physics) 333 CLDLIQAP kg/kg 30 A Grid box averaged cloud liquid amount (after physics) 334 CL mole/mole 30 A CL mixing ratio 335 CL2 mole/mole 30 A CL2 mixing ratio 336 RHO mole/mole 30 A RHO mixing ratio 337 k1 /s 1 A reaction rate 338 k2 /s 1 A reaction rate 339 CLy mole/mole 30 A CLy mixing ratio 340 iCLy mole/mole 1 A Average mass-weighted column-integrated CLy mixing ratio 341 iCL mole/mole 1 A Average mass-weighted column-integrated CL mixing ratio 342 iCL2 mole/mole 1 A Average mass-weighted column-integrated CL2 mixing ratio 343 Q_qneg3 kg/kg 30 I Specific humidity QNEG3 error (cell) 344 Q_qneg3_col kg/kg 1 I Specific humidity QNEG3 error (column) 345 CLDLIQ_qneg3 kg/kg 30 I Grid box averaged cloud liquid amount QNEG3 error (cell) 346 CLDLIQ_qneg3_col kg/kg 1 I Grid box averaged cloud liquid amount QNEG3 error (column) 347 RAINQM_qneg3 kg/kg 30 I Grid box averaged rain water amount QNEG3 error (cell) 348 RAINQM_qneg3_col kg/kg 1 I Grid box averaged rain water amount QNEG3 error (column) 349 CL_qneg3 kg/kg 30 I CL QNEG3 error (cell) 350 CL_qneg3_col kg/kg 1 I CL QNEG3 error (column) 351 CL2_qneg3 kg/kg 30 I CL2 QNEG3 error (cell) 352 CL2_qneg3_col kg/kg 1 I CL2 QNEG3 error (column) 353 RHO_qneg3 kg/kg 30 I RHO QNEG3 error (cell) 354 RHO_qneg3_col kg/kg 1 I RHO QNEG3 error (column) 355 qflux_exceeded kg/m^2/s 1 I qflux excess (QNEG4) 356 DQP kg/kg/s 30 A Specific humidity tendency due to precipitation 357 Q_gll kg/kg 30 I Specific humidity 358 Qdp_gll kg/kg 30 I Specific humidity*dp 359 CLDLIQ_gll kg/kg 30 I Grid box averaged cloud liquid amount 360 CLDLIQdp_gll kg/kg 30 I Grid box averaged cloud liquid amount*dp 361 RAINQM_gll kg/kg 30 I Grid box averaged rain water amount 362 RAINQMdp_gll kg/kg 30 I Grid box averaged rain water amount*dp 363 CL_gll kg/kg 30 I CL 364 CLdp_gll kg/kg 30 I CL*dp 365 CL2_gll kg/kg 30 I CL2 366 CL2dp_gll kg/kg 30 I CL2*dp 367 RHO_gll kg/kg 30 I RHO 368 RHOdp_gll kg/kg 30 I RHO*dp 369 U_gll m/s 30 I U wind on gll grid 370 V_gll m/s 30 I V wind on gll grid 371 T_gll K 30 I T on gll grid 372 PSDRY_gll Pa 1 I psdry on gll grid 373 PS_gll Pa 1 I ps on gll grid 374 PHIS_gll Pa 1 I PHIS on gll grid 375 U&IC m/s 30 I Zonal wind 376 V&IC m/s 30 I Meridional wind 377 PS&IC Pa 1 I Surface pressure 378 T&IC K 30 I Temperature 379 Q&IC kg/kg 30 I Specific humidity 380 CLDLIQ&IC kg/kg 30 I Grid box averaged cloud liquid amount 381 RAINQM&IC kg/kg 30 I Grid box averaged rain water amount 382 CL&IC kg/kg 30 I CL 383 CL2&IC kg/kg 30 I CL2 384 RHO&IC kg/kg 30 I RHO intht:nfmaster= 384 FLDLST: Tape 3 is empty FLDLST: Tape 4 is empty FLDLST: Tape 5 is empty FLDLST: Tape 6 is empty FLDLST: Tape 7 is empty FLDLST: Tape 8 is empty FLDLST: Tape 9 is empty FLDLST: Tape 10 is empty FLDLST: Tape 11 is empty FLDLST: History file 1 contains 2 fields Write frequency: 48 Filename specifier: %c.cam.h%t.%y-%m-%d-%s.nc Output precision: single Number of time samples per file: 30 Fields are represented on global grids: 100 Included fields are: 1 PRECL m/s 1 I Large-scale (stable) precipitation rate (liq + ice) 2 PS Pa 1 I Surface pressure FLDLST: History file 2 contains 10 fields Write frequency: 48 Filename specifier: %c.cam.h%t.%y-%m-%d-%s.nc Output precision: single Number of time samples per file: 30 Fields are represented on global grids: 100 Included fields are: 1 CLDLIQ kg/kg 30 A Grid box averaged cloud liquid amount 2 OMEGA Pa/s 30 A Vertical velocity (pressure) 3 Q kg/kg 30 A Specific humidity 4 RAINQM kg/kg 30 A Grid box averaged rain water amount 5 T K 30 A Temperature 6 U m/s 30 A Zonal wind 7 V m/s 30 A Meridional wind 8 iCL mole/mole 1 A Average mass-weighted column-integrated CL mixing ratio 9 iCL2 mole/mole 1 A Average mass-weighted column-integrated CL2 mixing ratio 10 iCLy mole/mole 1 A Average mass-weighted column-integrated CLy mixing ratio FLDLST: History file 12 contains 10 fields Write frequency: YEARLY (INITIAL CONDITIONS) Filename specifier: %c.cam.i.%y-%m-%d-%s.nc Output precision: double Number of time samples per file: 1 Fields are represented on global grids: 101 Included fields are: 1 CL&IC kg/kg 30 I CL 2 CL2&IC kg/kg 30 I CL2 3 CLDLIQ&IC kg/kg 30 I Grid box averaged cloud liquid amount 4 PS&IC Pa 1 I Surface pressure 5 Q&IC kg/kg 30 I Specific humidity 6 RAINQM&IC kg/kg 30 I Grid box averaged rain water amount 7 RHO&IC kg/kg 30 I RHO 8 T&IC K 30 I Temperature 9 U&IC m/s 30 I Zonal wind 10 V&IC m/s 30 I Meridional wind nstep, te 0 0.26317785398197021E+10 0.26317785398197021E+10 -0.00000000000000000E+00 0.99999998617825389E+05 WSHIST: writing time sample 0 to h-file 1 DATE=0001/01/01 NCSEC= 0 WSHIST: nhfil( 1 )=FKESSLER.cam.h0.0001-01-01-00000.nc Opening netcdf history file FKESSLER.cam.h0.0001-01-01-00000.nc H_DEFINE: Successfully opened netcdf file Creating new decomp: 16!760!!48602!!d6!i2! WSHIST: writing time sample 0 to h-file 2 DATE=0001/01/01 NCSEC= 0 WSHIST: nhfil( 2 )=FKESSLER.cam.h1.0001-01-01-00000.nc Opening netcdf history file FKESSLER.cam.h1.0001-01-01-00000.nc H_DEFINE: Successfully opened netcdf file Creating new decomp: 16!30!760!!48602!30!!d6!i2! nstep, te 1 0.26317780750597858E+10 0.26317782522024746E+10 0.96723118242219288E-05 0.99999990163745926E+05 WRAPUP: nf_close( 1 )=FKESSLER.cam.h0.0001-01-01-00000.nc Primary history file Output at NSTEP = 1 Number of time samples on this file = 1 Model Day = 0.02 --------------------------------------- WRAPUP: nf_close( 2 )=FKESSLER.cam.h1.0001-01-01-00000.nc Auxiliary history file number 1 Output at NSTEP = 1 Number of time samples on this file = 1 Model Day = 0.02 --------------------------------------- nstep, te 2 0.26317780735390315E+10 0.26317780750795765E+10 0.84116548054005219E-07 0.99999990164327610E+05 Number of completed timesteps: 1 Time step 2 partially done to provide convectively adjusted and time filtered values for history tape. ******* END OF MODEL RUN *******