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680 up2_dp1 m^2/s^3 33 A u'^2_dp1, up2 budget: up2 dissipation term 1
681 up2_dp2 m^2/s^3 33 A u'^2_d'^2, up2 budget: up2 dissipation term 2
682 up2_ma m^2/s^3 33 A u'^2_ma, up2 budget: up2 mean advection
683 up2_pd m^2/s^3 33 A u'^2_pd, up2 budget: up2 positive definite adjustment
684 up2_pr1 m^2/s^3 33 A u'^2_pr1, up2 budget: up2 pressure term 1
685 up2_pr2 m^2/s^3 33 A u'^2_pr2, up2 budget: up2 pressure term 2
686 up2_sf m^2/s^3 33 A u'^2_sf, up2 budget: up2 surface variance
687 up2_ta m^2/s^3 33 A u'^2_ta, up2 budget: up2 turbulent advection
688 up2_tp m^2/s^3 33 A u'^2_tp, up2 budget: up2 turbulent production
689 up2_zt m^2/s^2 33 A up2_zt, u'^2 interpolated to thermodynamic levels
690 upwp m^2/s^2 33 A u'w', Vertical turbulent flux of eastward (u) wind
691 upwp_zt m^2/s^2 33 A upwp_zt, u'w' interpolated to thermodynamic levels
692 varnce_rt_1 (kg^2)/(kg^2) 33 A varnce_rt_1, pdf parameter: rt variance of component 1
693 varnce_rt_2 (kg^2)/(kg^2) 33 A varnce_rt_2, pdf parameter: rt variance of component 2
694 varnce_thl_1 K^2 33 A varnce_thl_1, pdf parameter: thl variance of component 1
695 varnce_thl_2 K^2 33 A varnce_thl_2, pdf parameter: thl variance of component 2
696 varnce_w_1 m^2/s^2 33 A varnce_w_1, pdf parameter: w variance of component 1
697 varnce_w_2 m^2/s^2 33 A varnce_w_2, pdf parameter: w variance of component 2
698 vg m/s 33 A vg, v geostrophic wind
699 vm m/s 33 A v_bar, Grid-mean northward (v) wind
700 vm_bt m s^{-2} 33 A vm_bt, vm budget: vm time tendency
701 vm_cf m s^{-2} 33 A vm_cf, vm budget: vm coriolis forcing
702 vm_f m s^{-2} 33 A vm_f, vm budget: vm forcing
703 vm_gf m s^{-2} 33 A vm_gf, vm budget: vm geostrophic forcing
704 vm_ma m s^{-2} 33 A vm_ma, vm budget: vm vertical mean advection
705 vm_ndg m s^{-2} 33 A vm_ndg, vm budget: vm nudging
706 vm_ref m/s 33 A vm_ref, Reference v wind
707 vm_sdmp m s^{-2} 33 A vm_sdmp, vm budget: vm sponge damping
708 vm_ta m s^{-2} 33 A vm_ta, vm budget: vm turbulent transport
709 vp2 m^2/s^2 33 A v'^2, Variance of northward (v) wind
710 vp2_bt m^2/s^3 33 A v'2_bt, vp2 budget: vp2 time tendency
711 vp2_cl m^2/s^3 33 A v'^2_cl, vp2 budget: vp2 clipping
712 vp2_dp1 m^2/s^3 33 A v'^2_dp1, vp2 budget: vp2 dissipation term 1
713 vp2_dp2 m^2/s^3 33 A v'^2_dp2, vp2 budget: vp2 dissipation term 2
714 vp2_ma m^2/s^3 33 A v'^2_ma, vp2 budget: vp2 mean advection
715 vp2_pd m^2/s^3 33 A v'^2_pd, vp2 budget: vp2 positive definite adjustment
716 vp2_pr1 m^2/s^3 33 A v'^2_pr1, vp2 budget: vp2 pressure term 1
717 vp2_pr2 m^2/s^3 33 A v'^2_pr2, vp2 budget: vp2 pressure term 2
718 vp2_sf m^2/s^3 33 A v'^2_sf, vp2 budget: vp2 surface variance
719 vp2_ta m^2/s^3 33 A v'^2_ta, vp2 budget: vp2 turbulent advection
720 vp2_tp m^2/s^3 33 A v'^2_tp, vp2 budget: vp2 turbulent production
721 vp2_zt m^2/s^2 33 A vp2_zt, v'^2 interpolated to thermodynamic levels
722 vpwp m^2/s^2 33 A v'w', Vertical turbulent flux of northward (v) wind
723 vpwp_zt m^2/s^2 33 A vpwp_zt, v'w' interpolated to thermodynamic levels
724 w_1 m/s 33 A w_1, pdf parameter: mean w of component 1
725 w_2 m/s 33 A w_2, pdf paramete: mean w of component 2
726 wm_zm m/s 33 A wm_zm, Vertical (w) wind
727 wp2 m^2/s^2 33 A w'^2, Variance of vertical air velocity
728 wp2_ac m^2/s^3 33 A w'^2_ac, wp2 budget: wp2 accumulation term
729 wp2_bp m^2/s^3 33 A w'^2_bp, wp2 budget: wp2 buoyancy production
730 wp2_bt m^2/s^3 33 A w'^2_bt, wp2 budget: wp2 time tendency
731 wp2_cl m^2/s^3 33 A w'^2_cl, wp2 budget: wp2 clipping term
732 wp2_dp1 m^2/s^3 33 A w'^2_dp1, wp2 budget: wp2 dissipation term 1
733 wp2_dp2 m^2/s^3 33 A w'^2_d'^2, wp2 budget: wp2 dissipation term 2
734 wp2_ma m^2/s^3 33 A w'^2_ma, wp2 budget: wp2 vertical mean advection
735 wp2_pd m2/s3 33 A w'^2_pd, wp2 budget: wp2 positive definite adjustment
736 wp2_pr1 m^2/s^3 33 A w'^2_pr1, wp2 budget: wp2 pressure term 1
737 wp2_pr2 m^2/s^3 33 A w'^2_pr2, wp2 budget: wp2 pressure term 2
738 wp2_pr3 m^2/s^3 33 A w'^2_pr3, wp2 budget: wp2 pressure term 3
739 wp2_sf m2/s3 33 A w'^2_sf, wp2 budget: wp2 surface variance
740 wp2_ta m^2/s^3 33 A w'^2_ta, wp2 budget: wp2 turbulent advection
741 wp2_zt m^2/s^2 33 A wp2_zt, w'^2 interpolated to thermodyamic levels
742 wp2rcp (m^2 kg)/(s^2 kg 33 A w'^2rc'
743 wp2rtp (m^2 kg)/(s^2 kg 33 A w'^2rt', Vertical turbulent flux of w'rt'
744 wp2thlp (m^2 K)/s^2 33 A w'^2theta_l', Vertical turbulent flux of w'theta_l'
745 wp2thvp K m^2/s^2 33 A w'^2theta_v', Vertical turbulent flux of w'theta_v'
746 wp3 m^3/s^3 33 A w'^3, Third-order moment of vertical air velocity
747 wp3_ac m^{3} s^{-4} 33 A wp3_ac, wp3 budget: wp3 accumulation term
748 wp3_bp1 m^{3} s^{-4} 33 A wp3_bp1, wp3 budget: wp3 buoyancy production
749 wp3_bt m^{3} s^{-4} 33 A wp3_bt, wp3 budget: wp3 time tendency
750 wp3_cl m^{3} s^{-4} 33 A wp3_cl, wp3 budget: wp3 clipping term
751 wp3_dp1 m^{3} s^{-4} 33 A wp3_dp1, wp3 budget: wp3 dissipation term 1
752 wp3_ma m^{3} s^{-4} 33 A wp3_ma, wp3 budget: wp3 vertical mean advection
753 wp3_on_wp2 m/s 33 A w'^3_on_w'^2, Smoothed version of wp3 / wp2
754 wp3_on_wp2_zt m/s 33 A wp3_on_wp2_zt, Smoothed version of wp3 / wp2
755 wp3_pr1 m^{3} s^{-4} 33 A wp3_pr1, wp3 budget: wp3 pressure term 1
756 wp3_pr2 m^{3} s^{-4} 33 A wp3_pr2, wp3 budget: wp3 pressure term 2
757 wp3_pr_dfsn m^{3} s^{-4} 33 A wp3_pr_dfsn, wp3 budget: wp3 pressure diffusion term
758 wp3_pr_turb m^{3} s^{-4} 33 A wp3_pr_turb, wp3 budget: wp3 pressure-turbulence correlation term
759 wp3_ta m^{3} s^{-4} 33 A wp3_ta, wp3 budget: wp3 turbulent advection
760 wp3_tp m^{3} s^{-4} 33 A wp3_tp, wp3 budget: wp3 turbulent transport
761 wp3_zm (m^3)/(s^3) 33 A w'^3_zm, w'^3 interpolated to moment. levels
762 wp4 (m^4)/(s^4) 33 A w'^4, Fourth-order moment of vertical air velocity
763 wprcp (m/s) (kg/kg) 33 A w'rc'
764 wprtp (m kg)/(s kg) 33 A w'rt', Vertical turbulent flux of total water, rt
765 wprtp2 (m kg)/(s kg) 33 A w'rt'^2, Vertical turbulent flux of rt'^2
766 wprtp_ac (m kg)/(s^2 kg) 33 A w'rt'_ac, wprtp budget: wprtp accumulation term
767 wprtp_bp (m kg)/(s^2 kg) 33 A w'rt'_b', wprtp budget: wprtp buoyancy production
768 wprtp_bt (m kg)/(s^2 kg) 33 A w'rt'_bt, wprtp budget: wprtp time tendency
769 wprtp_cl (m kg)/(s^2 kg) 33 A w'rt'_cl, wprtp budget: wprtp clipping term
770 wprtp_dp1 (m kg)/(s^2 kg) 33 A w'rt'_dp1, wprtp budget: wprtp dissipation term 1
771 wprtp_enter_mfl (m kg)/(s kg) 33 A w'rt'_enter_mfl, Wprtp entering flux limiter
772 wprtp_exit_mfl (m kg)/(s kg) 33 A w'rt'_exit_mfl, Wprtp exiting flux limiter
773 wprtp_forcing (m kg/kg)/s^2 33 A w'rt'_forcing, wprtp budget: wprtp forcing (includes microphysics tendency)
774 wprtp_ma (m kg)/(s^2 kg) 33 A w'rt'_ma, wprtp budget: wprtp mean advection
775 wprtp_mc (m kg/kg)/s^2 33 A w'rt'_mc, Microphysics tendency for wprtp (not in budget)
776 wprtp_mfl (m kg)/(s^2 kg) 33 A w'rt'_mfl, wprtp budget: wprtp monotonic flux limiter
777 wprtp_mfl_max (m kg)/(s kg) 33 A w'rt'_mfl_max, Maximum allowable wprtp
778 wprtp_mfl_min (m kg)/(s kg) 33 A w'rt'_mfl_min, Minimum allowable wprtp
779 wprtp_pd (m kg)/(s^2 kg) 33 A w'rt'_pd, wprtp budget: wprtp flux corrected trans. term
780 wprtp_pr1 (m kg)/(s^2 kg) 33 A w'rt'_pr1, wprtp budget: wprtp pressure term 1
781 wprtp_pr2 (m kg)/(s^2 kg) 33 A w'rt'_pr2, wprtp budget: wprtp pressure term 2
782 wprtp_pr3 (m kg)/(s^2 kg) 33 A w'rt'_pr3, wprtp budget: wprtp pressure term 3
783 wprtp_sicl (m kg)/(s^2 kg) 33 A w'rt'_sicl, wprtp budget: wprtp semi-implicit clipping term
784 wprtp_ta (m kg)/(s^2 kg) 33 A w'rt'_ta, wprtp budget: wprtp turbulent advection
785 wprtp_tp (m kg)/(s^2 kg) 33 A w'rt'_t', wprtp budget: wprtp turbulent production
786 wprtp_zt (m kg)/(s kg) 33 A wprtp_zt, w'rt' interpolated to thermodynamic levels
787 wprtpthlp (m kg K)/(s kg) 33 A w'rt'theta_l', Vertical turbulent flux of rt'theta_l'
788 wpthlp (m K)/s 33 A w'thl', Vertical turbulent flux of theta_l
789 wpthlp2 (m K^2)/s 33 A w'theta_l'^2, Vertical turbulent flux of theta_l'^2
790 wpthlp_ac (m K)/s^2 33 A w'thl'_ac, wpthlp budget: wpthlp accumulation term
791 wpthlp_bp (m K)/s^2 33 A w'thl'_b', wpthlp budget: wpthlp buoyancy production
792 wpthlp_bt (m K)/s^2 33 A w'thl'_bt, wpthlp budget
793 wpthlp_cl (m K)/s^2 33 A w'thl'_cl, wpthlp budget: wpthlp clipping term
794 wpthlp_dp1 (m K)/s^2 33 A w'thl'_dp1, wpthlp budget: wpthlp dissipation term 1
795 wpthlp_enter_mfl (m K)/s 33 A w'thl'_enter_mfl, Wpthlp entering flux limiter
796 wpthlp_exit_mfl (m K)/s 33 A w'thl'_exit_mfl, Wpthlp exiting flux limiter
797 wpthlp_forcing (m K)/s^2 33 A w'thl'_forcing, wpthlp budget: wpthlp forcing (includes microphysics tendency)
798 wpthlp_ma (m K)/s^2 33 A w'thl'_ma, wpthlp budget: wpthlp mean advection
799 wpthlp_mc (m K)/s^2 33 A w'thl'_mc, Microphysics tendency for wpthlp (not in budget)
800 wpthlp_mfl (m K)/s^2 33 A w'thl'_mfl, wpthlp budget: wpthlp monotonic flux limiter
801 wpthlp_mfl_max (m K)/s 33 A w'thl'_mfl_max, Maximum allowable wpthlp
802 wpthlp_mfl_min (m K)/s 33 A w'thl'_mfl_min, Minimum allowable wpthlp
803 wpthlp_pr1 (m K)/s^2 33 A w'thl'_pr1, wpthlp budget: wpthlp pressure term 1
804 wpthlp_pr2 (m K)/s^2 33 A w'thl'_pr2, wpthlp budget: wpthlp pressure term 2
805 wpthlp_pr3 (m K)/s^2 33 A w'thl'_pr3, wpthlp budget: wpthlp pressure term 3
806 wpthlp_sicl (m K)/s^2 33 A w'thl'_sicl, wpthlp budget: wpthlp semi-implicit clipping term
807 wpthlp_ta (m K)/s^2 33 A w'thl'_ta, wpthlp budget: wpthlp turbulent advection
808 wpthlp_tp (m K)/s^2 33 A w'thl'_tp, wpthlp budget: wpthlp turbulent production
809 wpthlp_zt (m K)/s 33 A wpthlp_zt, w'thl' interpolated to thermodynamic levels
810 wpthvp K m/s 33 A w'thv', Buoyancy flux
FLDLST: History file 2 contains 12 fields
Write frequency: 48
Filename specifier: %c.cam.h%t.%y-%m-%d-%s.nc
Output precision: single
Number of time samples per file: 5000
Fields are represented on global grids:
100
Included fields are:
1 CDNUMC 1/m2 1 A Vertically-integrated droplet concentration
2 CLDICE kg/kg 32 A Grid box averaged cloud ice amount
3 CLDLIQ kg/kg 32 A Grid box averaged cloud liquid amount
4 CLDST fraction 32 A Stratus cloud fraction
5 CLDTOT fraction 1 A Vertically-integrated total cloud
6 FLUT W/m2 1 A Upwelling longwave flux at top of model
7 LWCF W/m2 1 A Longwave cloud forcing
8 PRECT m/s 1 A Total (convective and large-scale) precipitation rate (liq + ice)
9 SWCF W/m2 1 A Shortwave cloud forcing
10 U200 m/s 1 A Zonal wind at 200 mbar pressure surface
11 U850 m/s 1 A Zonal wind at 850 mbar pressure surface
12 V200 m/s 1 A Meridional wind at 200 mbar pressure surface
FLDLST: History file 3 contains 5 fields
Write frequency: 12
Filename specifier: %c.cam.h%t.%y-%m-%d-%s.nc
Output precision: single
Number of time samples per file: 5000
Fields are represented on global grids:
100
Included fields are:
1 FLUT W/m2 1 A Upwelling longwave flux at top of model
2 OMEGA500 Pa/s 1 A Vertical velocity at 500 mbar pressure surface
3 PRECT m/s 1 A Total (convective and large-scale) precipitation rate (liq + ice)
4 U200 m/s 1 A Zonal wind at 200 mbar pressure surface
5 U850 m/s 1 A Zonal wind at 850 mbar pressure surface
FLDLST: History file 4 contains 1 fields
Write frequency: 6
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 PRECT m/s 1 A Total (convective and large-scale) precipitation rate (liq + ice)
FLDLST: History file 12 contains 37 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:
102
103
101
Included fields are:
1 CLDICE&IC kg/kg 32 I Grid box averaged cloud ice amount
2 CLDLIQ&IC kg/kg 32 I Grid box averaged cloud liquid amount
3 DMS&IC kg/kg 32 I DMS
4 H2O2&IC kg/kg 32 I H2O2
5 H2SO4&IC kg/kg 32 I H2SO4
6 NUMICE&IC kg/kg 32 I Grid box averaged cloud ice number
7 NUMLIQ&IC kg/kg 32 I Grid box averaged cloud liquid number
8 NUMRAI&IC kg/kg 32 I Grid box averaged rain number
9 NUMSNO&IC kg/kg 32 I Grid box averaged snow number
10 PS&IC Pa 1 I Surface pressure
11 Q&IC kg/kg 32 I Specific humidity
12 RAINQM&IC kg/kg 32 I Grid box averaged rain amount
13 SNOWQM&IC kg/kg 32 I Grid box averaged snow amount
14 SO2&IC kg/kg 32 I SO2
15 SOAG&IC kg/kg 32 I SOAG
16 T&IC K 32 I Temperature
17 US&IC m/s 32 I Zonal wind, staggered
18 VS&IC m/s 32 I Meridional wind, staggered
19 bc_a1&IC kg/kg 32 I bc_a1
20 bc_a4&IC kg/kg 32 I bc_a4
21 dst_a1&IC kg/kg 32 I dst_a1
22 dst_a2&IC kg/kg 32 I dst_a2
23 dst_a3&IC kg/kg 32 I dst_a3
24 ncl_a1&IC kg/kg 32 I ncl_a1
25 ncl_a2&IC kg/kg 32 I ncl_a2
26 ncl_a3&IC kg/kg 32 I ncl_a3
27 num_a1&IC kg/kg 32 I num_a1
28 num_a2&IC kg/kg 32 I num_a2
29 num_a3&IC kg/kg 32 I num_a3
30 num_a4&IC kg/kg 32 I num_a4
31 pom_a1&IC kg/kg 32 I pom_a1
32 pom_a4&IC kg/kg 32 I pom_a4
33 so4_a1&IC kg/kg 32 I so4_a1
34 so4_a2&IC kg/kg 32 I so4_a2
35 so4_a3&IC kg/kg 32 I so4_a3
36 soa_a1&IC kg/kg 32 I soa_a1
37 soa_a2&IC kg/kg 32 I soa_a2
FV subcycling - nv, n2, nsplit, dt = 1 1 1 1800.0000000000000
Divergence damping: use 4th order damping
AM GLOBAL FIXER: 0.17748273397861392E-01
nstep, te 0 0.26039256497622747E+10 0.26039256497622747E+10 -0.00000000000000000E+00 0.98515089330790492E+05
chem_surfvals_set: ncdate= 101 co2vmr= 3.7037274741528211E-004
chem_surfvals_set: ch4vmr= 1.7796230601788733E-006 n2ovmr= 3.1559927877047199E-007 f11vmr= 6.9287623092291151E-010 f12vmr= 5.3897977645776600E-010
READ_NEXT_TRCDATA emiss_bb
READ_NEXT_TRCDATA emiss_oceans
READ_NEXT_TRCDATA emiss_ag_sol_was emiss_ship emiss_res_tran
READ_NEXT_TRCDATA emiss_ene_ind
READ_NEXT_TRCDATA emiss_bb
READ_NEXT_TRCDATA emiss_anthro
READ_NEXT_TRCDATA emiss_bb
READ_NEXT_TRCDATA emiss_biogenic
READ_NEXT_TRCDATA emiss_anthro
READ_NEXT_TRCDATA emiss_bb
READ_NEXT_TRCDATA num_bc_a4_anthro
READ_NEXT_TRCDATA num_bc_a4_bb
READ_NEXT_TRCDATA num_pom_a4_anthro
READ_NEXT_TRCDATA num_pom_a4_bb
READ_NEXT_TRCDATA emiss_ag_sol_was emiss_shipping
READ_NEXT_TRCDATA num_so4_a1_bb
READ_NEXT_TRCDATA emiss_res_tran
READ_NEXT_TRCDATA emiss_anthro
READ_NEXT_TRCDATA emiss_bb
READ_NEXT_TRCDATA emiss_ag_sol_was emiss_shipping
READ_NEXT_TRCDATA emiss_bb
READ_NEXT_TRCDATA emiss_res_tran
READ_NEXT_TRCDATA emiss_volcanoes
READ_NEXT_TRCDATA contvolcano
READ_NEXT_TRCDATA contvolcano
READ_NEXT_TRCDATA emiss_ene_ind
READ_NEXT_TRCDATA emiss_ene_ind
READ_NEXT_TRCDATA emiss_volcanoes
READ_NEXT_TRCDATA emiss_volcanoes
READ_NEXT_TRCDATA CH4_CHML
READ_NEXT_TRCDATA O3 OH NO3 HO2
READ_NEXT_TRCDATA ozone
READ_NEXT_TRCDATA VOLC_MMR1 VOLC_MMR2 VOLC_MMR3 VOLC_RAD_GEOM1 VOLC_RAD_GEOM2 VOLC_RAD_GEOM3 VOLC_SAD
WSHIST: writing time sample 0 to h-file 2 DATE=0000/01/01 NCSEC= 0
WSHIST: nhfil( 2 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h1.0000-01-01-00000.nc
Opening netcdf history file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h1.0000-01-01-00000.nc
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h1.0000-01-01-00000.nc to write 248
H_DEFINE: Successfully opened netcdf file
Creating new decomp: 16!29!!24!19!!d5!i5!
Creating new decomp: 16!32!29!!24!19!32!!d5!i5!
WSHIST: writing time sample 0 to h-file 3 DATE=0000/01/01 NCSEC= 0
WSHIST: nhfil( 3 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h2.0000-01-01-00000.nc
Opening netcdf history file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h2.0000-01-01-00000.nc
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h2.0000-01-01-00000.nc to write 249
H_DEFINE: Successfully opened netcdf file
WSHIST: writing time sample 0 to h-file 4 DATE=0000/01/01 NCSEC= 0
WSHIST: nhfil( 4 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h3.0000-01-01-00000.nc
Opening netcdf history file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h3.0000-01-01-00000.nc
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h3.0000-01-01-00000.nc to write 250
H_DEFINE: Successfully opened netcdf file
AM GLOBAL FIXER: 0.15309316418683331E-01
nstep, te 1 0.26036955947128935E+10 0.26037603147612910E+10 0.35872279578421256E-02 0.98514843302512978E+05
AM GLOBAL FIXER: 0.16087061063288444E-01
nstep, te 2 0.26037361567883539E+10 0.26037649701794901E+10 0.15970352301448718E-02 0.98514847920612316E+05
AM GLOBAL FIXER: 0.16919703219758869E-01
nstep, te 3 0.26037545335439758E+10 0.26037688555380287E+10 0.79382159697483502E-03 0.98515006498930394E+05
AM GLOBAL FIXER: 0.17577946404575221E-01
nstep, te 4 0.26037724191692686E+10 0.26037705222840519E+10 -0.10513760037678482E-03 0.98515552501544356E+05
AM GLOBAL FIXER: 0.17962495443226603E-01
nstep, te 5 0.26037731281383920E+10 0.26037718891732984E+10 -0.68671113853533745E-04 0.98516002377606434E+05
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.r.0000-01-01-09000.nc to write 254
Creating new decomp: 16!29!!24!19!!d4!i5!
Creating new decomp: 16!4!29!!24!19!4!!d4!i5!
Creating new decomp: 16!4!29!!24!19!4!!d6!i5!
Creating new decomp: 16!32!29!!24!19!32!!d6!i5!
Creating new decomp: 16!128!29!!24!19!128!!d6!i5!
Creating new decomp: 16!33!29!!24!19!33!!d6!i5!
Creating new decomp: 16!33!29!!24!19!33!!d4!i5!
WSHIST: writing history restart 0 to hr-file 1 DATE=0000/01/01 NCSEC= 9000
Opening netcdf history restart file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh0.0000-01-01-09000.nc
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh0.0000-01-01-09000.nc to write 255
H_DEFINE: Successfully opened netcdf file
Creating new decomp: 24!32!19!!24!19!32!!d6!i1!
Creating new decomp: 1!33!19!!1!19!33!!d6!i4!
WSHIST: writing history restart 1 to hr-file 2 DATE=0000/01/01 NCSEC= 9000
Opening netcdf history restart file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh1.0000-01-01-09000.nc
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh1.0000-01-01-09000.nc to write 256
H_DEFINE: Successfully opened netcdf file
WSHIST: writing history restart 1 to hr-file 3 DATE=0000/01/01 NCSEC= 9000
Opening netcdf history restart file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh2.0000-01-01-09000.nc
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh2.0000-01-01-09000.nc to write 257
H_DEFINE: Successfully opened netcdf file
WSHIST: writing history restart 1 to hr-file 4 DATE=0000/01/01 NCSEC= 9000
Opening netcdf history restart file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh3.0000-01-01-09000.nc
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rh3.0000-01-01-09000.nc to write 258
H_DEFINE: Successfully opened netcdf file
(OPNFIL): Successfully opened file ./rpointer.atm on unit= 64
(WRITE_REST_PFILE): successfully wrote local restart pointer file ./rpointer.atm
---------------------------------------
WRAPUP: nf_close( 2 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h1.0000-01-01-00000.nc
Auxiliary history file number 1
Output at NSTEP = 5
Number of time samples on this file = 1
Model Day = 0.10
---------------------------------------
Opened existing file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h1.0000-01-01-00000.nc 259
H_INQUIRE: Successfully opened netcdf file
WRAPUP: nf_close( 3 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h2.0000-01-01-00000.nc
Auxiliary history file number 2
Output at NSTEP = 5
Number of time samples on this file = 1
Model Day = 0.10
---------------------------------------
Opened existing file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h2.0000-01-01-00000.nc 260
H_INQUIRE: Successfully opened netcdf file
WRAPUP: nf_close( 4 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h3.0000-01-01-00000.nc
Auxiliary history file number 3
Output at NSTEP = 5
Number of time samples on this file = 1
Model Day = 0.10
---------------------------------------
Opened existing file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h3.0000-01-01-00000.nc 261
H_INQUIRE: Successfully opened netcdf file
AM GLOBAL FIXER: 0.18076328664656950E-01
nstep, te 6 0.26037731022276406E+10 0.26037721778285532E+10 -0.51235708382178349E-04 0.98516406114833881E+05
Opened file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.rs.0000-01-01-09000.nc to write 262
WSHIST: writing time sample 1 to h-file 4 DATE=0000/01/01 NCSEC= 10800
AM GLOBAL FIXER: 0.18090003989281928E-01
nstep, te 7 0.26037747267766342E+10 0.26037730063033953E+10 -0.95358490303227222E-04 0.98516811697575526E+05
AM GLOBAL FIXER: 0.17883528547799874E-01
nstep, te 8 0.26037731419718494E+10 0.26037707386638432E+10 -0.13320457122792663E-03 0.98517207612249884E+05
AM GLOBAL FIXER: 0.17557020743596490E-01
nstep, te 9 0.26037718247041750E+10 0.26037694321130238E+10 -0.13261008791668681E-03 0.98517575368402831E+05
WRAPUP: nf_close( 2 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h1.0000-01-01-00000.nc
Auxiliary history file number 1
Output at NSTEP = 9
Number of time samples on this file = 1
Model Day = 0.19
---------------------------------------
WRAPUP: nf_close( 3 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h2.0000-01-01-00000.nc
Auxiliary history file number 2
Output at NSTEP = 9
Number of time samples on this file = 1
Model Day = 0.19
---------------------------------------
WRAPUP: nf_close( 4 )=ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cam.h3.0000-01-01-00000.nc
Auxiliary history file number 3
Output at NSTEP = 9
Number of time samples on this file = 2
Model Day = 0.19
---------------------------------------
QNEG3 from D_P_COUPLING:NUMICE Min. mixing ratio violated at 3 points. Worst = -0.3E-07
QNEG3 from D_P_COUPLING:NUMSNO Min. mixing ratio violated at 24 points. Worst = -0.3E-09
QNEG3 from cldwat:Q Min. mixing ratio violated at 1256 points. Worst = -0.9E-04
QNEG3 from cldwat:CLDLIQ Min. mixing ratio violated at 14984 points. Worst = -0.1E-04
QNEG3 from cldwat:CLDICE Min. mixing ratio violated at 137843 points. Worst = -0.1E-04
QNEG3 from cldwat:RAINQM Min. mixing ratio violated at 238008 points. Worst = -0.1E-03
QNEG3 from cldwat:bc_a1 Min. mixing ratio violated at 6323 points. Worst = -0.2E-10
QNEG3 from cldwat:bc_a4 Min. mixing ratio violated at 632 points. Worst = -0.1E-09
QNEG3 from cldwat:dst_a3 Min. mixing ratio violated at 11398 points. Worst = -0.5E-10
QNEG3 from cldwat:ncl_a1 Min. mixing ratio violated at 6445 points. Worst = -0.1E-10
QNEG3 from cldwat:ncl_a2 Min. mixing ratio violated at 2370 points. Worst = -0.5E-11
QNEG3 from cldwat:ncl_a3 Min. mixing ratio violated at 6939 points. Worst = -0.1E-08
QNEG3 from cldwat:num_a1 Min. mixing ratio violated at 4956 points. Worst = -0.6E+07
QNEG3 from cldwat:num_a2 Min. mixing ratio violated at 646 points. Worst = -0.1E+09
QNEG3 from cldwat:num_a3 Min. mixing ratio violated at 7860 points. Worst = -0.2E+05
QNEG3 from cldwat:num_a4 Min. mixing ratio violated at 640 points. Worst = -0.3E+09
QNEG3 from cldwat:pom_a1 Min. mixing ratio violated at 6281 points. Worst = -0.9E-10
QNEG3 from cldwat:pom_a4 Min. mixing ratio violated at 620 points. Worst = -0.3E-09
QNEG3 from cldwat:so4_a1 Min. mixing ratio violated at 5225 points. Worst = -0.3E-11
QNEG3 from cldwat:so4_a2 Min. mixing ratio violated at 1121 points. Worst = -0.2E-10
QNEG3 from cldwat:soa_a1 Min. mixing ratio violated at 7136 points. Worst = -0.6E-10
QNEG3 from chemistry:num_a2 Min. mixing ratio violated at 47 points. Worst = 0.2E-08
QNEG3 from chemistry:num_a4 Min. mixing ratio violated at 37 points. Worst = 0.3E-08
QNEG3 from vertical diffusion:num_a2 Min. mixing ratio violated at 2 points. Worst = 0.1E-04
QNEG3 from vertical diffusion:num_a4 Min. mixing ratio violated at 1 points. Worst = 0.1E-04
AM GLOBAL FIXER: 0.17226361069567434E-01
nstep, te 10 0.26037718294695630E+10 0.26037690197446423E+10 -0.15572928222335323E-03 0.98517935756494684E+05
Number of completed timesteps: 9
Time step 10 partially done to provide convectively adjusted and time filtered values for history tape.
******* END OF MODEL RUN *******
[Pipeline] sh
+ gzip -d /home/jenkins/cam_output/scratch/ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8/run/cesm.log.220817-043825.gz
+ cat /home/jenkins/cam_output/scratch/ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220812_102133_cauz2x/run/cesm.log.220812-104437 /home/jenkins/cam_output/scratch/ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220816_035656_rxjpsv/run/cesm.log.220816-041944 /home/jenkins/cam_output/scratch/ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8/run/cesm.log.220817-043825
[0] User-specified PIO rearranger comm max pend req (comp2io), 0 (value will be reset as requested)
[0] Resetting PIO rearranger comm max pend req (comp2io) to 64
[0] User-specified PIO rearranger comm max pend req (io2comp), 0 (value will be reset as requested)
[0] Resetting PIO rearranger comm max pend req (io2comp) to 64
[0] PIO rearranger options:
[0] comm type = p2p
[0] comm fcd = 2denable
[0] max pend req (comp2io) = 64
[0] enable_hs (comp2io) = T
[0] enable_isend (comp2io) = F
[0] max pend req (io2comp) = 64
[0] enable_hs (io2comp) = F
[0] enable_isend (io2comp) = T
[0] 1 pes participating in computation of coupled model
[0] --------------------------------------------------------------
[0] GLOBAL communicator : 1 nodes, 1 MPI tasks
[0] COMMUNICATOR NODE # [NODE NAME] : (# OF MPI TASKS) TASK # LIST
[0] GLOBAL NODE 0 [ nelson ] : ( 1 MPI TASKS ) 0
[0] --------------------------------------------------------------
[0] (seq_comm_setcomm) init ID ( 1 GLOBAL ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_setcomm) init ID ( 2 CPL ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_setcomm) init ID ( 5 ATM ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 6 CPLATM ) join IDs = 2 5 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 3 ALLATMID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 4 CPLALLATMID ) join IDs = 2 3 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 9 LND ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 10 CPLLND ) join IDs = 2 9 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 7 ALLLNDID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 8 CPLALLLNDID ) join IDs = 2 7 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 13 ICE ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 14 CPLICE ) join IDs = 2 13 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 11 ALLICEID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 12 CPLALLICEID ) join IDs = 2 11 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 17 OCN ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 18 CPLOCN ) join IDs = 2 17 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 15 ALLOCNID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 16 CPLALLOCNID ) join IDs = 2 15 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 21 ROF ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 22 CPLROF ) join IDs = 2 21 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 19 ALLROFID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 20 CPLALLROFID ) join IDs = 2 19 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 25 GLC ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 26 CPLGLC ) join IDs = 2 25 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 23 ALLGLCID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 24 CPLALLGLCID ) join IDs = 2 23 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 29 WAV ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 30 CPLWAV ) join IDs = 2 29 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 27 ALLWAVID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 28 CPLALLWAVID ) join IDs = 2 27 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 33 ESP ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 34 CPLESP ) join IDs = 2 33 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 31 ALLESPID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 32 CPLALLESPID ) join IDs = 2 31 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 37 IAC ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 38 CPLIAC ) join IDs = 2 37 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 35 ALLIACID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 36 CPLALLIACID ) join IDs = 2 35 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_printcomms) 1 0 1 1 GLOBAL:
[0] (seq_comm_printcomms) 2 0 1 1 CPL:
[0] (seq_comm_printcomms) 3 0 1 1 ALLATMID:
[0] (seq_comm_printcomms) 4 0 1 1 CPLALLATMID:
[0] (seq_comm_printcomms) 5 0 1 1 ATM:
[0] (seq_comm_printcomms) 6 0 1 1 CPLATM:
[0] (seq_comm_printcomms) 7 0 1 1 ALLLNDID:
[0] (seq_comm_printcomms) 8 0 1 1 CPLALLLNDID:
[0] (seq_comm_printcomms) 9 0 1 1 LND:
[0] (seq_comm_printcomms) 10 0 1 1 CPLLND:
[0] (seq_comm_printcomms) 11 0 1 1 ALLICEID:
[0] (seq_comm_printcomms) 12 0 1 1 CPLALLICEID:
[0] (seq_comm_printcomms) 13 0 1 1 ICE:
[0] (seq_comm_printcomms) 14 0 1 1 CPLICE:
[0] (seq_comm_printcomms) 15 0 1 1 ALLOCNID:
[0] (seq_comm_printcomms) 16 0 1 1 CPLALLOCNID:
[0] (seq_comm_printcomms) 17 0 1 1 OCN:
[0] (seq_comm_printcomms) 18 0 1 1 CPLOCN:
[0] (seq_comm_printcomms) 19 0 1 1 ALLROFID:
[0] (seq_comm_printcomms) 20 0 1 1 CPLALLROFID:
[0] (seq_comm_printcomms) 21 0 1 1 ROF:
[0] (seq_comm_printcomms) 22 0 1 1 CPLROF:
[0] (seq_comm_printcomms) 23 0 1 1 ALLGLCID:
[0] (seq_comm_printcomms) 24 0 1 1 CPLALLGLCID:
[0] (seq_comm_printcomms) 25 0 1 1 GLC:
[0] (seq_comm_printcomms) 26 0 1 1 CPLGLC:
[0] (seq_comm_printcomms) 27 0 1 1 ALLWAVID:
[0] (seq_comm_printcomms) 28 0 1 1 CPLALLWAVID:
[0] (seq_comm_printcomms) 29 0 1 1 WAV:
[0] (seq_comm_printcomms) 30 0 1 1 CPLWAV:
[0] (seq_comm_printcomms) 31 0 1 1 ALLESPID:
[0] (seq_comm_printcomms) 32 0 1 1 CPLALLESPID:
[0] (seq_comm_printcomms) 33 0 1 1 ESP:
[0] (seq_comm_printcomms) 34 0 1 1 CPLESP:
[0] (seq_comm_printcomms) 35 0 1 1 ALLIACID:
[0] (seq_comm_printcomms) 36 0 1 1 CPLALLIACID:
[0] (seq_comm_printcomms) 37 0 1 1 IAC:
[0] (seq_comm_printcomms) 38 0 1 1 CPLIAC:
[0] (t_initf) Read in prof_inparm namelist from: drv_in
[0] (t_initf) Using profile_disable= F
[0] (t_initf) profile_timer= 4
[0] (t_initf) profile_depth_limit= 12
[0] (t_initf) profile_detail_limit= 2
[0] (t_initf) profile_barrier= F
[0] (t_initf) profile_outpe_num= 1
[0] (t_initf) profile_outpe_stride= 0
[0] (t_initf) profile_single_file= F
[0] (t_initf) profile_global_stats= T
[0] (t_initf) profile_ovhd_measurement= F
[0] (t_initf) profile_add_detail= F
[0] (t_initf) profile_papi_enable= F
[0] 1 pes participating in computation
[0] -----------------------------------
[0] TASK# NAME
[0] 0 nelson
[0]
[0] l, cnst_name(l), cnst_name_cw(l)
[0] 1 Q
[0] 2 CLDLIQ
[0] 3 CLDICE
[0] 4 NUMLIQ
[0] 5 NUMICE
[0] 6 RAINQM
[0] 7 SNOWQM
[0] 8 NUMRAI
[0] 9 NUMSNO
[0] 10 bc_a1 bc_c1
[0] 11 bc_a4 bc_c4
[0] 12 DMS
[0] 13 dst_a1 dst_c1
[0] 14 dst_a2 dst_c2
[0] 15 dst_a3 dst_c3
[0] 16 H2O2
[0] 17 H2SO4
[0] 18 ncl_a1 ncl_c1
[0] 19 ncl_a2 ncl_c2
[0] 20 ncl_a3 ncl_c3
[0] 21 num_a1 num_c1
[0] 22 num_a2 num_c2
[0] 23 num_a3 num_c3
[0] 24 num_a4 num_c4
[0] 25 pom_a1 pom_c1
[0] 26 pom_a4 pom_c4
[0] 27 SO2
[0] 28 so4_a1 so4_c1
[0] 29 so4_a2 so4_c2
[0] 30 so4_a3 so4_c3
[0] 31 SOAG
[0] 32 soa_a1 soa_c1
[0] 33 soa_a2 soa_c2
[0] calcsize addfld - num_a1_sfcsiz1
[0] calcsize addfld - num_a1_sfcsiz2
[0] calcsize addfld - num_c1_sfcsiz1
[0] calcsize addfld - num_c1_sfcsiz2
[0] calcsize addfld - num_a2_sfcsiz1
[0] calcsize addfld - num_a2_sfcsiz2
[0] calcsize addfld - num_c2_sfcsiz1
[0] calcsize addfld - num_c2_sfcsiz2
[0] calcsize addfld - num_a3_sfcsiz1
[0] calcsize addfld - num_a3_sfcsiz2
[0] calcsize addfld - num_c3_sfcsiz1
[0] calcsize addfld - num_c3_sfcsiz2
[0] calcsize addfld - num_a4_sfcsiz1
[0] calcsize addfld - num_a4_sfcsiz2
[0] calcsize addfld - num_c4_sfcsiz1
[0] calcsize addfld - num_c4_sfcsiz2
[0] calcsize addfld - num_a2_sfcsiz3
[0] calcsize addfld - num_a1_sfcsiz3
[0] calcsize addfld - num_a2_sfcsiz4
[0] calcsize addfld - num_a1_sfcsiz4
[0] calcsize addfld - num_c2_sfcsiz3
[0] calcsize addfld - num_c1_sfcsiz3
[0] calcsize addfld - num_c2_sfcsiz4
[0] calcsize addfld - num_c1_sfcsiz4
[0] calcsize addfld - so4_a2_sfcsiz3
[0] calcsize addfld - so4_a1_sfcsiz3
[0] calcsize addfld - so4_a2_sfcsiz4
[0] calcsize addfld - so4_a1_sfcsiz4
[0] calcsize addfld - so4_c2_sfcsiz3
[0] calcsize addfld - so4_c1_sfcsiz3
[0] calcsize addfld - so4_c2_sfcsiz4
[0] calcsize addfld - so4_c1_sfcsiz4
[0] calcsize addfld - soa_a2_sfcsiz3
[0] calcsize addfld - soa_a1_sfcsiz3
[0] calcsize addfld - soa_a2_sfcsiz4
[0] calcsize addfld - soa_a1_sfcsiz4
[0] calcsize addfld - soa_c2_sfcsiz3
[0] calcsize addfld - soa_c1_sfcsiz3
[0] calcsize addfld - soa_c2_sfcsiz4
[0] calcsize addfld - soa_c1_sfcsiz4
[0] calcsize addfld - ncl_a2_sfcsiz3
[0] calcsize addfld - ncl_a1_sfcsiz3
[0] calcsize addfld - ncl_a2_sfcsiz4
[0] calcsize addfld - ncl_a1_sfcsiz4
[0] calcsize addfld - ncl_c2_sfcsiz3
[0] calcsize addfld - ncl_c1_sfcsiz3
[0] calcsize addfld - ncl_c2_sfcsiz4
[0] calcsize addfld - ncl_c1_sfcsiz4
[0] calcsize addfld - dst_a2_sfcsiz3
[0] calcsize addfld - dst_a1_sfcsiz3
[0] calcsize addfld - dst_a2_sfcsiz4
[0] calcsize addfld - dst_a1_sfcsiz4
[0] calcsize addfld - dst_c2_sfcsiz3
[0] calcsize addfld - dst_c1_sfcsiz3
[0] calcsize addfld - dst_c2_sfcsiz4
[0] calcsize addfld - dst_c1_sfcsiz4
[0]
[0] subr. modal_aero_gasaerexch_init - primary carbon aging pointers
[0] pair 1 mode 4 ---> mode 1
[0] spec 24=num_a4 ---> spec 21=num_a1
[0] spec 26=pom_a4 ---> spec 25=pom_a1
[0] spec 11=bc_a4 ---> spec 10=bc_a1
[0]
[0] qconff addfld qconff_gaex kg/kg/s
[0] qevapff addfld qevapff_gaex kg/kg/s
[0] qconbb addfld qconbb_gaex kg/kg/s
[0] qevapbb addfld qevapbb_gaex kg/kg/s
[0] qconbg addfld qconbg_gaex kg/kg/s
[0] qevapbg addfld qevapbg_gaex kg/kg/s
[0] qcon addfld qcon_gaex kg/kg/s
[0] qevap addfld qevap_gaex kg/kg/s
[0] gasaerexch addfld bc_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld bc_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld H2SO4_sfgaex1 kg/m2/s
[0] gasaerexch addfld num_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld num_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld pom_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld pom_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a2_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a3_sfgaex1 kg/m2/s
[0] gasaerexch addfld SOAG_sfgaex1 kg/m2/s
[0] gasaerexch addfld soa_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld soa_a2_sfgaex1 kg/m2/s
[0] gasaerexch addfld dst_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld num_a1_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c1_sfgaex2 #/m2/s
[0] gasaerexch addfld num_a2_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c2_sfgaex2 #/m2/s
[0] gasaerexch addfld num_a3_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c3_sfgaex2 #/m2/s
[0] gasaerexch addfld so4_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_c2_sfgaex2 kg/m2/s
[0]
[0] subr. modal_aero_coag_init
[0] pair 1 mode 2 ---> mode 1 eff 1
[0] spec 29=so4_a2 ---> spec 28=so4_a1
[0] spec 33=soa_a2 ---> spec 32=soa_a1
[0] spec 19=ncl_a2 ---> spec 18=ncl_a1
[0] spec 14=dst_a2 ---> spec 13=dst_a1
[0] pair 2 mode 4 ---> mode 1 eff 1
[0] spec 26=pom_a4 ---> spec 25=pom_a1
[0] spec 11=bc_a4 ---> spec 10=bc_a1
[0] pair 3 mode 2 ---> mode 4 eff 1
[0] spec 29=so4_a2 ---> spec 28=so4_a1
[0] spec 33=soa_a2 ---> spec 32=soa_a1
[0] spec 19=ncl_a2 ---> spec 18=ncl_a1
[0] spec 14=dst_a2 ---> spec 13=dst_a1
[0]
[0] modal_aero_coag_init addfld bc_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld bc_a4_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld dst_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld dst_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld ncl_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld ncl_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld num_a1_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld num_a2_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld num_a4_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld pom_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld pom_a4_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld so4_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld so4_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld soa_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld soa_a2_sfcoag1 kg/m2/s
[0] modal_aero_newnuc_init addfld H2SO4_sfnnuc1 kg/m2/s
[0] modal_aero_newnuc_init addfld num_a2_sfnnuc1 #/m2/s
[0] modal_aero_newnuc_init addfld so4_a2_sfnnuc1 kg/m2/s
[0]
[0]
[0] 1 pes participating in computation for CLM
[0]
[0] -----------------------------------
[0]
[0] NODE# NAME
[0] ( 0) nelson
[0] Reading setup_nml
[0] Reading grid_nml
[0] Reading tracer_nml
[0] Reading thermo_nml
[0] Reading dynamics_nml
[0] Reading shortwave_nml
[0] Reading ponds_nml
[0] Reading forcing_nml
[0] Reading zbgc_nml
[0] Grid specification
[0] ------------------
[0] ewn : 416
[0] nsn : 704
[0] upn : 11
[0] EW grid spacing : 4000.0000000000000
[0] NS grid spacing : 4000.0000000000000
[0] Outflow global boundary conditions; scalars in global halo will be set to zero
[0] sigma file :
[0]
[0] Time steps
[0] ----------
[0] start time (yr) : 0.0000000000000000
[0] end time (yr) : 1000.0000000000000
[0] time step (yr) : 0.10000000000000001
[0] nsteps per year : 10
[0] thermal dt factor : 1.0000000000000000
[0] diagnostic interval (years): 0.10000000000000001
[0]
[0] Dycore options
[0] -------------
[0] I/O parameter file :
[0] Dycore : 2 glissade
[0] temperature calculation : 1 prognostic temperature
[0] flow law : 2 Paterson and Budd
[0] basal_water : 0 none
[0] marine_margin : 1 remove all floating ice
[0] calving_init : 1 ice calves at initialization
[0] calving_domain : 1 calving in all cells where criterion is met
[0] Icebergs will be removed
[0] The thickness of marine ice cliffs will be limited
[0] calving_domain : 1 calving in all cells where criterion is met
[0] Calving-front cells will not be culled at initialization
[0] evolution : 3 incremental remapping
[0] minthck for diagnostics : 1 include cells with H > thklim in global diagnostics
[0] vertical_integration : 0 standard
[0] basal melt, floating ice: 0 none
[0] basal mass balance : 1 in continuity eqn
[0] smb input units : 0 SMB input in units of m/yr ice
[0] smb input function : 0 SMB input as function of (x,y)
[0] artm input function : 0 artm input as function of (x,y)
[0] overwrite_acab : 0 do not overwrite acab anywhere
[0] geothermal heat flux : 1 read flux from file, if present
[0] isostasy : 0 no isostasy calculation
[0]
[0] Higher-order options:
[0] ----------
[0] ho_whichefvs : 2 nonlinear, from eff strain rate
[0] ho_whichdisp : 1 first-order model (Blatter-Pattyn)
[0] ho_whichthermal_timestep: 2 vertical thermal solve split into two parts
[0] ho_whichbabc : 3 pseudo-plastic sliding law
[0] ho_whichbeta_limit : 0 absolute beta limit based on beta_grounded_min
[0] ho_whichbwat : 2 basal water depth computed from local till model
[0] ho_whicheffecpress : 4 reduced effecpress with increasing basal water
[0] which_ho_nonlinear : 1 use Picard iteration with acceleration
[0] ho_whichresid : 4 relative L2 norm, |Ax-b|/|b|
[0] ho_whichsparse : 3 Native PCG solver, Chronopoulos-Gear
[0] ho_whichapprox : 4 Depth-integrated viscosity (glissade_velo_higher)
[0] ho_whichgradient : 0 centered gradient (glissade)
[0] ho_whichgradient_margin : 1 compute edge gradient when ice lies above ice-free land
[0] ho_whichvertical_remap : 0 first-order accurate
[0] ho_whichassemble_beta : 1 use local beta at each vertex (glissade dycore)
[0] ho_whichassemble_taud : 1 use local driving stress at each vertex (glissade dycore)
[0] ho_whichassemble_bfric : 1 use local basal friction at each vertex (glissade dycore)
[0] ho_whichassemble_lateral : 1 use local thck and usrf on each cell face (glissade dycore)
[0] ho_whichcalving_front : 0 no subgrid calving front parameterization
[0] ho_whichground : 2 deluxe GLP, 0 <= f_ground <= 1 for both vertices and cells
[0] ho_whichground_bmlt : 1 weigh bmlt_float by floating fraction of cell
[0] ho_whichflotation_function: 3 modified linear = -b - (rhoi/rhoo)*H
[0] ho_whichice_age : 1 ice age computation on
[0] glissade_maxiter : 50
[0] linear_solve_ncheck : 5
[0] linear_maxiters : 200
[0] linear_tolerance : 1.0000000000000000E-008
[0] ho_whichprecond : 1 Diagonal preconditioner (native PCG)
[0]
[0] Parameters
[0] ----------
[0] thickness limit for dynamically active ice (m) : 1.0000000000000000
[0] Advection will be subcycled when CFL > 0.50000000000000000
[0] thickness limit for temperature calculations (m) : 1.0000000000000000
[0] thickness scale for gradient ramp (m): 50.000000000000000
[0] pmp threshold for temperature (K): 1.0000000000000000E-003
[0] taumax_cliff : 1000000.0000000000
[0] cliff time scale (yr) : 0.0000000000000000
[0] ice density (kg/m^3) : 917.00000000000000
[0] ocean density (kg/m^3) : 1026.0000000000000
[0] gravitational accel (m/s^2) : 9.8061600000000002
[0] heat capacity of ice (J/kg/K) : 2117.2700000000000
[0] latent heat of ice (J/kg) : 333700.00000000000
[0] triple point of water (K) : 273.16000000000003
[0] geothermal flux (W/m^2) : -5.0000000000000003E-002
[0] flow factor (grounded ice) : 1.0000000000000000
[0] flow factor (floating ice) : 1.0000000000000000
[0] max surface slope : 0.10000000000000001
[0] min effective strain rate (yr^-1) : 1.0000000000000000E-008
[0] pseudo-plastic q : 0.50000000000000000
[0] pseudo-plastic u0 : 100.00000000000000
[0] pseudo-plastic phi_min (deg) : 5.0000000000000000
[0] pseudo-plastic phi_max (deg) : 40.000000000000000
[0] pseudo-plastic bed min (m) : -700.00000000000000
[0] pseudo-plastic bed max (m) : 700.00000000000000
[0] min beta, grounded ice (Pa yr/m) : 100.00000000000000
[0] effective pressure delta : 2.0000000000000000E-002
[0] maximum till water depth (m) : 2.0000000000000000
[0] till drainage rate (m/yr) : 1.0000000000000000E-003
[0]
[0] number of ocean levels : 1
[0] Reading zocn levels from config file
[0] No ocean basins
[0]
[0] GLAD climate
[0] -------------
[0] evolve_ice (0=fixed, 1=evolve): 0
[0] The ice sheet state will not evolve after initialization
[0] Mass-balance accumulation time will be set to max(ice timestep, mbal timestep)
[0] ice_tstep_multiply: 1
[0] In glissade_initialise
[0] CISM 2.0
[0] Setting outflow boundary conditions
[0] Layout(EW,NS) = 416 704 total procs = 1
[0] Computing Glide sigma levels
[0] Sigma levels:
[0] ------------------
[0] 0.000 0.231 0.407 0.544 0.653 0.741 0.812 0.872 0.922 0.964 1.000
[0]
[0] opening file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc for input
[0] * WARNING: Input file contained no level dimension. This is not necessarily a problem.
[0] Reading time slice 1 ( 0.0000000000000000 ) from file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc at time 0.0000000000000000
[0] Loading x1
[0] Loading y1
[0] Loading acab
[0] * scaling acab
[0] Loading artm
[0] Loading bheatflx
[0] Loading lat
[0] Loading lon
[0] Loading thk
[0] * scaling thk
[0] Loading topg
[0] * scaling topg
[0] Global idiag, jdiag: 134 280
[0] Local idiag, jdiag, task: 136 282 0
[0] * Global idiag, jdiag: 134 280
[0] * Local idiag, jdiag, task: 136 282 0
[0] Set area scale factor = 1 for polar stereographic projection
[0] Projection
[0] ----------
[0] Type: Stereographic
[0] Longitude of central meridian: -45.000000000000000
[0] Latitude of projection origin: 90.000000000000000
[0] False easting: 0.0000000000000000
[0] False northing: 0.0000000000000000
[0] Standard parallel: 70.000000000000000
[0] Scale factor: 0.0000000000000000
[0] compute_area_factor: F
[0] Initializing ice temperature based on advective-diffusive balance in each column
[0] Offset from pressure melting point temperature = 5.0000000000000000
[0] Done in glissade_initialise
[0]
[0] Compute ice velocities, time = 0.0000000000000000
[0] Solving depth-integrated viscosity approximation
[0] Running with Picard acceleration
[0]
[0] iter # resid, |Ax-b|/|b| target resid
[0] Solved the linear system, niters, err = 190 9.4299768209613969E-009
[0] 1 1.00000 0.100000E-06
[0] Solved the linear system, niters, err = 175 7.1343923159488724E-009
[0] 2 0.842258 0.100000E-06
[0] Solved the linear system, niters, err = 175 3.4561872633109964E-009
[0] 3 0.807756 0.100000E-06
[0] Solved the linear system, niters, err = 150 6.2298748722726354E-009
[0] 4 0.642726 0.100000E-06
[0] Solved the linear system, niters, err = 120 6.4413966933533493E-009
[0] 5 0.460887 0.100000E-06
[0] Solved the linear system, niters, err = 110 7.1205709868903853E-009
[0] 6 0.301137 0.100000E-06
[0] Solved the linear system, niters, err = 100 8.6702521024152997E-009
[0] 7 0.182866 0.100000E-06
[0] Solved the linear system, niters, err = 90 6.6177868696590077E-009
[0] 8 0.313033E-01 0.100000E-06
[0] Solved the linear system, niters, err = 75 9.7326993604869788E-009
[0] 9 0.143345E-02 0.100000E-06
[0] Solved the linear system, niters, err = 75 6.4917157538320861E-009
[0] 10 0.707905E-03 0.100000E-06
[0] Solved the linear system, niters, err = 60 8.9299555868344861E-009
[0] 11 0.353373E-03 0.100000E-06
[0] Solved the linear system, niters, err = 60 7.1632060934989904E-009
[0] 12 0.175953E-03 0.100000E-06
[0] Solved the linear system, niters, err = 50 6.2990100286147877E-009
[0] 13 0.832134E-04 0.100000E-06
[0] Solved the linear system, niters, err = 40 7.8484648720643616E-009
[0] 14 0.396185E-04 0.100000E-06
[0] Solved the linear system, niters, err = 35 9.8085560867664464E-009
[0] 15 0.198952E-04 0.100000E-06
[0] Solved the linear system, niters, err = 35 5.8732108186775663E-009
[0] 16 0.930144E-05 0.100000E-06
[0] Solved the linear system, niters, err = 30 5.6152062687134416E-009
[0] 17 0.444384E-05 0.100000E-06
[0] Solved the linear system, niters, err = 25 2.9790979934622039E-009
[0] 18 0.224661E-05 0.100000E-06
[0] Solved the linear system, niters, err = 20 6.3680193348642408E-009
[0] 19 0.103521E-05 0.100000E-06
[0] Solved the linear system, niters, err = 15 5.8310172491648561E-009
[0] 20 0.501909E-06 0.100000E-06
[0] Solved the linear system, niters, err = 15 3.3943220703983932E-009
[0] 21 0.253474E-06 0.100000E-06
[0] Solved the linear system, niters, err = 10 4.9155139806049346E-009
[0] 22 0.116913E-06 0.100000E-06
[0] Solved the linear system, niters, err = 5 9.4638430098709191E-009
[0] 23 0.569919E-07 0.100000E-06
[0] Glissade solution has converged, outer counter, err = 23 2.7079866333541956E-002
[0] Loading lat
[0] Loading lon
[0] ----------------------------------------------------------
[0]
[0] * Diagnostic output, time = 0.0000000000000000
[0]
[0] * Total ice area (km^2) 0.1667679999998247E+07
[0] * Grounded ice area (km^2) 0.1663999999998256E+07
[0] * Floating ice area (km^2) 0.3679999999999986E+04
[0] * Total ice volume (km^3) 0.2952805440572556E+07
[0] * Total ice mass (kg) 0.2707722589005033E+19
[0] * Mass above flotation (kg) 0.2668477290954696E+19
[0] * Total ice energy (J) -0.1142852668752744E+24
[0] * Total SMB flux (Gt/y) 0.0000000000000000E+00
[0] * Total BMB flux (Gt/y) -0.0000000000000000E+00
[0] * Total calving flux (Gt/y) -0.0000000000000000E+00
[0] * Total dmass/dt (Gt/y) 0.0000000000000000E+00
[0] * dmass/dt error (Gt/y) 0.0000000000000000E+00
[0] * Total gr line flux (Gt/y) -0.1245122946652798E+02
[0] * Mean thickness (m) 1770.6067354502413309
[0] * Mean temperature (C) -19.9347059892333647
[0] * Max thickness (m), i, j 3402.6667480468750000 230 366
[0] * Max temperature, i, j, k -2.5815498828887939 297 216 0
[0] * Min temperature, i, j, k -30.3878574371337891 236 451 0
[0] * Max sfc spd (m/yr), i, j 1014.7894831410661709 97 406
[0] * Max base spd (m/yr), i, j 982.8610145341251609 97 406
[0]
[0] * Grid point diagnostics: (i,j) = 134 280
[0] * Local (i,j,rank) = 136 282 0
[0]
[0] * Upper surface (m) 343.5833129882813068
[0] * Thickness (m) 732.3333129882812500
[0] * Bedrock topo (m) -388.7500000000000000
[0] * Sfc mass balance (m/yr) 0.0000000000000000
[0] * Basal mass balance (m/yr) -0.0000000000000000
[0] * Basal water depth (m) 0.0000000000000000
[0] * Basal heat flux (W/m^2) -0.0548120401799679
[0]
[0] * Sigma Ice speed (m/yr) Ice temperature (C)
[0] * 0.000 471.1818589831506188 -9.7645025253295898
[0] * 0.116 -9.2874932227323068
[0] * 0.231 461.9941624668956592
[0] * 0.319 -8.4476792256992574
[0] * 0.407 439.4390907943886191
[0] * 0.476 -7.8025271680867023
[0] * 0.544 407.2954860938086767
[0] * 0.599 -7.2961458155157555
[0] * 0.653 366.3998246671715719
[0] * 0.697 -6.8913726356655065
[0] * 0.741 317.1923216979085964
[0] * 0.777 -6.5627116616410941
[0] * 0.812 260.8834262648618392
[0] * 0.842 -6.2921959230560542
[0] * 0.872 199.3256794083273462
[0] * 0.897 -6.0668670412763541
[0] * 0.922 134.5214104177689478
[0] * 0.943 -5.8771875500593502
[0] * 0.964 68.2772661500775229
[0] * 0.982 -5.7160111263863413
[0] * 1.000 2.0601702094450474 -5.6417792671673537
[0]
[0] Opening file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220812_102133_cauz2x.cism.initial_hist.0000-01-01-00000.nc for output;
[0] Write output at start of run and every 1.0000000000000000 years
[0] Creating variables internal_time, time, and tstep_count
[0] Creating variable level
[0] Creating variable lithoz
[0] Creating variable nlev_smb
[0] Creating variable staglevel
[0] Creating variable stagwbndlevel
[0] Creating variable x0
[0] Creating variable x1
[0] Creating variable y0
[0] Creating variable y1
[0] Creating variable zocn
[0] Creating variable artm
[0] Creating variable smb
[0] Creating variable thk
[0] Creating variable topg
[0] Creating variable usurf
[0] Writing to file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220812_102133_cauz2x.cism.initial_hist.0000-01-01-00000.nc at time 0.0000000000000000
[0] WHL: oc_tavg_helper is not associated; associate now
[0] Opening file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220812_102133_cauz2x.cism.tavg_helper.0000-00-00-00000.nc for output;
[0] Write output every 9999999.0000000000 years
[0] Creating variables internal_time, time, and tstep_count
[0] Creating variable level
[0] Creating variable lithoz
[0] Creating variable nlev_smb
[0] Creating variable staglevel
[0] Creating variable stagwbndlevel
[0] Creating variable x0
[0] Creating variable x1
[0] Creating variable y0
[0] Creating variable y1
[0] Creating variable zocn
[0] Creating variable artm
[0] Creating variable smb
[0] Creating variable thk
[0] Creating variable topg
[0] Creating variable usurf
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] calcsize j,iq,jac, lsfrm,lstoo 1 1 1 22 21
[0] calcsize j,iq,jac, lsfrm,lstoo 1 1 2 22 21
[0] calcsize j,iq,jac, lsfrm,lstoo 1 2 1 29 28
[0] calcsize j,iq,jac, lsfrm,lstoo 1 2 2 29 28
[0] calcsize j,iq,jac, lsfrm,lstoo 1 3 1 33 32
[0] calcsize j,iq,jac, lsfrm,lstoo 1 3 2 33 32
[0] calcsize j,iq,jac, lsfrm,lstoo 1 4 1 19 18
[0] calcsize j,iq,jac, lsfrm,lstoo 1 4 2 19 18
[0] calcsize j,iq,jac, lsfrm,lstoo 1 5 1 14 13
[0] calcsize j,iq,jac, lsfrm,lstoo 1 5 2 14 13
[0] calcsize j,iq,jac, lsfrm,lstoo 2 1 1 21 22
[0] calcsize j,iq,jac, lsfrm,lstoo 2 1 2 21 22
[0] calcsize j,iq,jac, lsfrm,lstoo 2 2 1 28 29
[0] calcsize j,iq,jac, lsfrm,lstoo 2 2 2 28 29
[0] calcsize j,iq,jac, lsfrm,lstoo 2 3 1 32 33
[0] calcsize j,iq,jac, lsfrm,lstoo 2 3 2 32 33
[0] calcsize j,iq,jac, lsfrm,lstoo 2 4 1 18 19
[0] calcsize j,iq,jac, lsfrm,lstoo 2 4 2 18 19
[0] calcsize j,iq,jac, lsfrm,lstoo 2 5 1 13 14
[0] calcsize j,iq,jac, lsfrm,lstoo 2 5 2 13 14
[0] Closing input file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc
[0] Closing output file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220812_102133_cauz2x.cism.tavg_helper.0000-00-00-00000.nc
[0] Some Stats
[0] Maximum temperature iterations: 0
[0] User-specified PIO rearranger comm max pend req (comp2io), 0 (value will be reset as requested)
[0] Resetting PIO rearranger comm max pend req (comp2io) to 64
[0] User-specified PIO rearranger comm max pend req (io2comp), 0 (value will be reset as requested)
[0] Resetting PIO rearranger comm max pend req (io2comp) to 64
[0] PIO rearranger options:
[0] comm type = p2p
[0] comm fcd = 2denable
[0] max pend req (comp2io) = 64
[0] enable_hs (comp2io) = T
[0] enable_isend (comp2io) = F
[0] max pend req (io2comp) = 64
[0] enable_hs (io2comp) = F
[0] enable_isend (io2comp) = T
[0] 1 pes participating in computation of coupled model
[0] --------------------------------------------------------------
[0] GLOBAL communicator : 1 nodes, 1 MPI tasks
[0] COMMUNICATOR NODE # [NODE NAME] : (# OF MPI TASKS) TASK # LIST
[0] GLOBAL NODE 0 [ nelson ] : ( 1 MPI TASKS )[0] 0[0]
[0] --------------------------------------------------------------
[0] (seq_comm_setcomm) init ID ( 1 GLOBAL ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_setcomm) init ID ( 2 CPL ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_setcomm) init ID ( 5 ATM ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 6 CPLATM ) join IDs = 2 5 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 3 ALLATMID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 4 CPLALLATMID ) join IDs = 2 3 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 9 LND ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 10 CPLLND ) join IDs = 2 9 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 7 ALLLNDID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 8 CPLALLLNDID ) join IDs = 2 7 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 13 ICE ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 14 CPLICE ) join IDs = 2 13 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 11 ALLICEID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 12 CPLALLICEID ) join IDs = 2 11 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 17 OCN ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 18 CPLOCN ) join IDs = 2 17 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 15 ALLOCNID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 16 CPLALLOCNID ) join IDs = 2 15 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 21 ROF ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 22 CPLROF ) join IDs = 2 21 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 19 ALLROFID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 20 CPLALLROFID ) join IDs = 2 19 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 25 GLC ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 26 CPLGLC ) join IDs = 2 25 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 23 ALLGLCID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 24 CPLALLGLCID ) join IDs = 2 23 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 29 WAV ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 30 CPLWAV ) join IDs = 2 29 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 27 ALLWAVID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 28 CPLALLWAVID ) join IDs = 2 27 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 33 ESP ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 34 CPLESP ) join IDs = 2 33 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 31 ALLESPID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 32 CPLALLESPID ) join IDs = 2 31 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 37 IAC ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 38 CPLIAC ) join IDs = 2 37 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 35 ALLIACID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 36 CPLALLIACID ) join IDs = 2 35 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_printcomms) 1 0 1 1 GLOBAL:
[0] (seq_comm_printcomms) 2 0 1 1 CPL:
[0] (seq_comm_printcomms) 3 0 1 1 ALLATMID:
[0] (seq_comm_printcomms) 4 0 1 1 CPLALLATMID:
[0] (seq_comm_printcomms) 5 0 1 1 ATM:
[0] (seq_comm_printcomms) 6 0 1 1 CPLATM:
[0] (seq_comm_printcomms) 7 0 1 1 ALLLNDID:
[0] (seq_comm_printcomms) 8 0 1 1 CPLALLLNDID:
[0] (seq_comm_printcomms) 9 0 1 1 LND:
[0] (seq_comm_printcomms) 10 0 1 1 CPLLND:
[0] (seq_comm_printcomms) 11 0 1 1 ALLICEID:
[0] (seq_comm_printcomms) 12 0 1 1 CPLALLICEID:
[0] (seq_comm_printcomms) 13 0 1 1 ICE:
[0] (seq_comm_printcomms) 14 0 1 1 CPLICE:
[0] (seq_comm_printcomms) 15 0 1 1 ALLOCNID:
[0] (seq_comm_printcomms) 16 0 1 1 CPLALLOCNID:
[0] (seq_comm_printcomms) 17 0 1 1 OCN:
[0] (seq_comm_printcomms) 18 0 1 1 CPLOCN:
[0] (seq_comm_printcomms) 19 0 1 1 ALLROFID:
[0] (seq_comm_printcomms) 20 0 1 1 CPLALLROFID:
[0] (seq_comm_printcomms) 21 0 1 1 ROF:
[0] (seq_comm_printcomms) 22 0 1 1 CPLROF:
[0] (seq_comm_printcomms) 23 0 1 1 ALLGLCID:
[0] (seq_comm_printcomms) 24 0 1 1 CPLALLGLCID:
[0] (seq_comm_printcomms) 25 0 1 1 GLC:
[0] (seq_comm_printcomms) 26 0 1 1 CPLGLC:
[0] (seq_comm_printcomms) 27 0 1 1 ALLWAVID:
[0] (seq_comm_printcomms) 28 0 1 1 CPLALLWAVID:
[0] (seq_comm_printcomms) 29 0 1 1 WAV:
[0] (seq_comm_printcomms) 30 0 1 1 CPLWAV:
[0] (seq_comm_printcomms) 31 0 1 1 ALLESPID:
[0] (seq_comm_printcomms) 32 0 1 1 CPLALLESPID:
[0] (seq_comm_printcomms) 33 0 1 1 ESP:
[0] (seq_comm_printcomms) 34 0 1 1 CPLESP:
[0] (seq_comm_printcomms) 35 0 1 1 ALLIACID:
[0] (seq_comm_printcomms) 36 0 1 1 CPLALLIACID:
[0] (seq_comm_printcomms) 37 0 1 1 IAC:
[0] (seq_comm_printcomms) 38 0 1 1 CPLIAC:
[0] (t_initf) Read in prof_inparm namelist from: drv_in
[0] (t_initf) Using profile_disable= F
[0] (t_initf) profile_timer= 4
[0] (t_initf) profile_depth_limit= 12
[0] (t_initf) profile_detail_limit= 2
[0] (t_initf) profile_barrier= F
[0] (t_initf) profile_outpe_num= 1
[0] (t_initf) profile_outpe_stride= 0
[0] (t_initf) profile_single_file= F
[0] (t_initf) profile_global_stats= T
[0] (t_initf) profile_ovhd_measurement= F
[0] (t_initf) profile_add_detail= F
[0] (t_initf) profile_papi_enable= F
[0] 1 pes participating in computation
[0] -----------------------------------
[0] TASK# NAME
[0] 0 nelson
[0]
[0] l, cnst_name(l), cnst_name_cw(l)
[0] 1 Q
[0] 2 CLDLIQ
[0] 3 CLDICE
[0] 4 NUMLIQ
[0] 5 NUMICE
[0] 6 RAINQM
[0] 7 SNOWQM
[0] 8 NUMRAI
[0] 9 NUMSNO
[0] 10 bc_a1 bc_c1
[0] 11 bc_a4 bc_c4
[0] 12 DMS
[0] 13 dst_a1 dst_c1
[0] 14 dst_a2 dst_c2
[0] 15 dst_a3 dst_c3
[0] 16 H2O2
[0] 17 H2SO4
[0] 18 ncl_a1 ncl_c1
[0] 19 ncl_a2 ncl_c2
[0] 20 ncl_a3 ncl_c3
[0] 21 num_a1 num_c1
[0] 22 num_a2 num_c2
[0] 23 num_a3 num_c3
[0] 24 num_a4 num_c4
[0] 25 pom_a1 pom_c1
[0] 26 pom_a4 pom_c4
[0] 27 SO2
[0] 28 so4_a1 so4_c1
[0] 29 so4_a2 so4_c2
[0] 30 so4_a3 so4_c3
[0] 31 SOAG
[0] 32 soa_a1 soa_c1
[0] 33 soa_a2 soa_c2
[0] calcsize addfld - num_a1_sfcsiz1
[0] calcsize addfld - num_a1_sfcsiz2
[0] calcsize addfld - num_c1_sfcsiz1
[0] calcsize addfld - num_c1_sfcsiz2
[0] calcsize addfld - num_a2_sfcsiz1
[0] calcsize addfld - num_a2_sfcsiz2
[0] calcsize addfld - num_c2_sfcsiz1
[0] calcsize addfld - num_c2_sfcsiz2
[0] calcsize addfld - num_a3_sfcsiz1
[0] calcsize addfld - num_a3_sfcsiz2
[0] calcsize addfld - num_c3_sfcsiz1
[0] calcsize addfld - num_c3_sfcsiz2
[0] calcsize addfld - num_a4_sfcsiz1
[0] calcsize addfld - num_a4_sfcsiz2
[0] calcsize addfld - num_c4_sfcsiz1
[0] calcsize addfld - num_c4_sfcsiz2
[0] calcsize addfld - num_a2_sfcsiz3
[0] calcsize addfld - num_a1_sfcsiz3
[0] calcsize addfld - num_a2_sfcsiz4
[0] calcsize addfld - num_a1_sfcsiz4
[0] calcsize addfld - num_c2_sfcsiz3
[0] calcsize addfld - num_c1_sfcsiz3
[0] calcsize addfld - num_c2_sfcsiz4
[0] calcsize addfld - num_c1_sfcsiz4
[0] calcsize addfld - so4_a2_sfcsiz3
[0] calcsize addfld - so4_a1_sfcsiz3
[0] calcsize addfld - so4_a2_sfcsiz4
[0] calcsize addfld - so4_a1_sfcsiz4
[0] calcsize addfld - so4_c2_sfcsiz3
[0] calcsize addfld - so4_c1_sfcsiz3
[0] calcsize addfld - so4_c2_sfcsiz4
[0] calcsize addfld - so4_c1_sfcsiz4
[0] calcsize addfld - soa_a2_sfcsiz3
[0] calcsize addfld - soa_a1_sfcsiz3
[0] calcsize addfld - soa_a2_sfcsiz4
[0] calcsize addfld - soa_a1_sfcsiz4
[0] calcsize addfld - soa_c2_sfcsiz3
[0] calcsize addfld - soa_c1_sfcsiz3
[0] calcsize addfld - soa_c2_sfcsiz4
[0] calcsize addfld - soa_c1_sfcsiz4
[0] calcsize addfld - ncl_a2_sfcsiz3
[0] calcsize addfld - ncl_a1_sfcsiz3
[0] calcsize addfld - ncl_a2_sfcsiz4
[0] calcsize addfld - ncl_a1_sfcsiz4
[0] calcsize addfld - ncl_c2_sfcsiz3
[0] calcsize addfld - ncl_c1_sfcsiz3
[0] calcsize addfld - ncl_c2_sfcsiz4
[0] calcsize addfld - ncl_c1_sfcsiz4
[0] calcsize addfld - dst_a2_sfcsiz3
[0] calcsize addfld - dst_a1_sfcsiz3
[0] calcsize addfld - dst_a2_sfcsiz4
[0] calcsize addfld - dst_a1_sfcsiz4
[0] calcsize addfld - dst_c2_sfcsiz3
[0] calcsize addfld - dst_c1_sfcsiz3
[0] calcsize addfld - dst_c2_sfcsiz4
[0] calcsize addfld - dst_c1_sfcsiz4
[0]
[0] subr. modal_aero_gasaerexch_init - primary carbon aging pointers
[0] pair 1 mode 4 ---> mode 1
[0] spec 24=num_a4 ---> spec 21=num_a1
[0] spec 26=pom_a4 ---> spec 25=pom_a1
[0] spec 11=bc_a4 ---> spec 10=bc_a1
[0]
[0] qconff addfld qconff_gaex kg/kg/s
[0] qevapff addfld qevapff_gaex kg/kg/s
[0] qconbb addfld qconbb_gaex kg/kg/s
[0] qevapbb addfld qevapbb_gaex kg/kg/s
[0] qconbg addfld qconbg_gaex kg/kg/s
[0] qevapbg addfld qevapbg_gaex kg/kg/s
[0] qcon addfld qcon_gaex kg/kg/s
[0] qevap addfld qevap_gaex kg/kg/s
[0] gasaerexch addfld bc_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld bc_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld H2SO4_sfgaex1 kg/m2/s
[0] gasaerexch addfld num_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld num_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld pom_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld pom_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a2_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a3_sfgaex1 kg/m2/s
[0] gasaerexch addfld SOAG_sfgaex1 kg/m2/s
[0] gasaerexch addfld soa_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld soa_a2_sfgaex1 kg/m2/s
[0] gasaerexch addfld dst_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld num_a1_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c1_sfgaex2 #/m2/s
[0] gasaerexch addfld num_a2_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c2_sfgaex2 #/m2/s
[0] gasaerexch addfld num_a3_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c3_sfgaex2 #/m2/s
[0] gasaerexch addfld so4_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_c2_sfgaex2 kg/m2/s
[0]
[0] subr. modal_aero_coag_init
[0] pair 1 mode 2 ---> mode 1 eff 1
[0] spec 29=so4_a2 ---> spec 28=so4_a1
[0] spec 33=soa_a2 ---> spec 32=soa_a1
[0] spec 19=ncl_a2 ---> spec 18=ncl_a1
[0] spec 14=dst_a2 ---> spec 13=dst_a1
[0] pair 2 mode 4 ---> mode 1 eff 1
[0] spec 26=pom_a4 ---> spec 25=pom_a1
[0] spec 11=bc_a4 ---> spec 10=bc_a1
[0] pair 3 mode 2 ---> mode 4 eff 1
[0] spec 29=so4_a2 ---> spec 28=so4_a1
[0] spec 33=soa_a2 ---> spec 32=soa_a1
[0] spec 19=ncl_a2 ---> spec 18=ncl_a1
[0] spec 14=dst_a2 ---> spec 13=dst_a1
[0]
[0] modal_aero_coag_init addfld bc_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld bc_a4_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld dst_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld dst_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld ncl_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld ncl_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld num_a1_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld num_a2_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld num_a4_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld pom_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld pom_a4_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld so4_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld so4_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld soa_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld soa_a2_sfcoag1 kg/m2/s
[0] modal_aero_newnuc_init addfld H2SO4_sfnnuc1 kg/m2/s
[0] modal_aero_newnuc_init addfld num_a2_sfnnuc1 #/m2/s
[0] modal_aero_newnuc_init addfld so4_a2_sfnnuc1 kg/m2/s
[0]
[0]
[0] 1 pes participating in computation for CLM
[0]
[0] -----------------------------------
[0]
[0] NODE# NAME
[0] ( 0) nelson
[0] Reading setup_nml
[0] Reading grid_nml
[0] Reading tracer_nml
[0] Reading thermo_nml
[0] Reading dynamics_nml
[0] Reading shortwave_nml
[0] Reading ponds_nml
[0] Reading forcing_nml
[0] Reading zbgc_nml
[0] Grid specification
[0] ------------------
[0] ewn : 416
[0] nsn : 704
[0] upn : 11
[0] EW grid spacing : 4000.0000000000000
[0] NS grid spacing : 4000.0000000000000
[0] Outflow global boundary conditions; scalars in global halo will be set to zero
[0] sigma file :
[0]
[0] Time steps
[0] ----------
[0] start time (yr) : 0.0000000000000000
[0] end time (yr) : 1000.0000000000000
[0] time step (yr) : 0.10000000000000001
[0] nsteps per year : 10
[0] thermal dt factor : 1.0000000000000000
[0] diagnostic interval (years): 0.10000000000000001
[0]
[0] Dycore options
[0] -------------
[0] I/O parameter file :
[0] Dycore : 2 glissade
[0] temperature calculation : 1 prognostic temperature
[0] flow law : 2 Paterson and Budd
[0] basal_water : 0 none
[0] marine_margin : 1 remove all floating ice
[0] calving_init : 1 ice calves at initialization
[0] calving_domain : 1 calving in all cells where criterion is met
[0] Icebergs will be removed
[0] The thickness of marine ice cliffs will be limited
[0] calving_domain : 1 calving in all cells where criterion is met
[0] Calving-front cells will not be culled at initialization
[0] evolution : 3 incremental remapping
[0] minthck for diagnostics : 1 include cells with H > thklim in global diagnostics
[0] vertical_integration : 0 standard
[0] basal melt, floating ice: 0 none
[0] basal mass balance : 1 in continuity eqn
[0] smb input units : 0 SMB input in units of m/yr ice
[0] smb input function : 0 SMB input as function of (x,y)
[0] artm input function : 0 artm input as function of (x,y)
[0] overwrite_acab : 0 do not overwrite acab anywhere
[0] geothermal heat flux : 1 read flux from file, if present
[0] isostasy : 0 no isostasy calculation
[0]
[0] Higher-order options:
[0] ----------
[0] ho_whichefvs : 2 nonlinear, from eff strain rate
[0] ho_whichdisp : 1 first-order model (Blatter-Pattyn)
[0] ho_whichthermal_timestep: 2 vertical thermal solve split into two parts
[0] ho_whichbabc : 3 pseudo-plastic sliding law
[0] ho_whichbeta_limit : 0 absolute beta limit based on beta_grounded_min
[0] ho_whichbwat : 2 basal water depth computed from local till model
[0] ho_whicheffecpress : 4 reduced effecpress with increasing basal water
[0] which_ho_nonlinear : 1 use Picard iteration with acceleration
[0] ho_whichresid : 4 relative L2 norm, |Ax-b|/|b|
[0] ho_whichsparse : 3 Native PCG solver, Chronopoulos-Gear
[0] ho_whichapprox : 4 Depth-integrated viscosity (glissade_velo_higher)
[0] ho_whichgradient : 0 centered gradient (glissade)
[0] ho_whichgradient_margin : 1 compute edge gradient when ice lies above ice-free land
[0] ho_whichvertical_remap : 0 first-order accurate
[0] ho_whichassemble_beta : 1 use local beta at each vertex (glissade dycore)
[0] ho_whichassemble_taud : 1 use local driving stress at each vertex (glissade dycore)
[0] ho_whichassemble_bfric : 1 use local basal friction at each vertex (glissade dycore)
[0] ho_whichassemble_lateral : 1 use local thck and usrf on each cell face (glissade dycore)
[0] ho_whichcalving_front : 0 no subgrid calving front parameterization
[0] ho_whichground : 2 deluxe GLP, 0 <= f_ground <= 1 for both vertices and cells
[0] ho_whichground_bmlt : 1 weigh bmlt_float by floating fraction of cell
[0] ho_whichflotation_function: 3 modified linear = -b - (rhoi/rhoo)*H
[0] ho_whichice_age : 1 ice age computation on
[0] glissade_maxiter : 50
[0] linear_solve_ncheck : 5
[0] linear_maxiters : 200
[0] linear_tolerance : 1.0000000000000000E-008
[0] ho_whichprecond : 1 Diagonal preconditioner (native PCG)
[0]
[0] Parameters
[0] ----------
[0] thickness limit for dynamically active ice (m) : 1.0000000000000000
[0] Advection will be subcycled when CFL > 0.50000000000000000
[0] thickness limit for temperature calculations (m) : 1.0000000000000000
[0] thickness scale for gradient ramp (m): 50.000000000000000
[0] pmp threshold for temperature (K): 1.0000000000000000E-003
[0] taumax_cliff : 1000000.0000000000
[0] cliff time scale (yr) : 0.0000000000000000
[0] ice density (kg/m^3) : 917.00000000000000
[0] ocean density (kg/m^3) : 1026.0000000000000
[0] gravitational accel (m/s^2) : 9.8061600000000002
[0] heat capacity of ice (J/kg/K) : 2117.2700000000000
[0] latent heat of ice (J/kg) : 333700.00000000000
[0] triple point of water (K) : 273.16000000000003
[0] geothermal flux (W/m^2) : -5.0000000000000003E-002
[0] flow factor (grounded ice) : 1.0000000000000000
[0] flow factor (floating ice) : 1.0000000000000000
[0] max surface slope : 0.10000000000000001
[0] min effective strain rate (yr^-1) : 1.0000000000000000E-008
[0] pseudo-plastic q : 0.50000000000000000
[0] pseudo-plastic u0 : 100.00000000000000
[0] pseudo-plastic phi_min (deg) : 5.0000000000000000
[0] pseudo-plastic phi_max (deg) : 40.000000000000000
[0] pseudo-plastic bed min (m) : -700.00000000000000
[0] pseudo-plastic bed max (m) : 700.00000000000000
[0] min beta, grounded ice (Pa yr/m) : 100.00000000000000
[0] effective pressure delta : 2.0000000000000000E-002
[0] maximum till water depth (m) : 2.0000000000000000
[0] till drainage rate (m/yr) : 1.0000000000000000E-003
[0]
[0] number of ocean levels : 1
[0] Reading zocn levels from config file
[0] No ocean basins
[0]
[0] GLAD climate
[0] -------------
[0] evolve_ice (0=fixed, 1=evolve): 0
[0] The ice sheet state will not evolve after initialization
[0] Mass-balance accumulation time will be set to max(ice timestep, mbal timestep)
[0] ice_tstep_multiply: 1
[0] In glissade_initialise
[0] CISM 2.0
[0] Setting outflow boundary conditions
[0] Layout(EW,NS) = 416 704 total procs = 1
[0] Computing Glide sigma levels
[0] Sigma levels:
[0] ------------------
[0] 0.000 0.231 0.407 0.544 0.653 0.741 0.812 0.872 0.922 0.964 1.000
[0]
[0] opening file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc for input
[0] * WARNING: Input file contained no level dimension. This is not necessarily a problem.
[0] Reading time slice 1 ( 0.0000000000000000 ) from file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc at time 0.0000000000000000
[0] Loading x1
[0] Loading y1
[0] Loading acab
[0] * scaling acab
[0] Loading artm
[0] Loading bheatflx
[0] Loading lat
[0] Loading lon
[0] Loading thk
[0] * scaling thk
[0] Loading topg
[0] * scaling topg
[0] Global idiag, jdiag: 134 280
[0] Local idiag, jdiag, task: 136 282 0
[0] * Global idiag, jdiag: 134 280
[0] * Local idiag, jdiag, task: 136 282 0
[0] Set area scale factor = 1 for polar stereographic projection
[0] Projection
[0] ----------
[0] Type: Stereographic
[0] Longitude of central meridian: -45.000000000000000
[0] Latitude of projection origin: 90.000000000000000
[0] False easting: 0.0000000000000000
[0] False northing: 0.0000000000000000
[0] Standard parallel: 70.000000000000000
[0] Scale factor: 0.0000000000000000
[0] compute_area_factor: F
[0] Initializing ice temperature based on advective-diffusive balance in each column
[0] Offset from pressure melting point temperature = 5.0000000000000000
[0] Done in glissade_initialise
[0]
[0] Compute ice velocities, time = 0.0000000000000000
[0] Solving depth-integrated viscosity approximation
[0] Running with Picard acceleration
[0]
[0] iter # resid, |Ax-b|/|b| target resid
[0] Solved the linear system, niters, err = 190 9.4299768209613969E-009
[0] 1 1.00000 0.100000E-06
[0] Solved the linear system, niters, err = 175 7.1343923159488724E-009
[0] 2 0.842258 0.100000E-06
[0] Solved the linear system, niters, err = 175 3.4561872633109964E-009
[0] 3 0.807756 0.100000E-06
[0] Solved the linear system, niters, err = 150 6.2298748722726354E-009
[0] 4 0.642726 0.100000E-06
[0] Solved the linear system, niters, err = 120 6.4413966933533493E-009
[0] 5 0.460887 0.100000E-06
[0] Solved the linear system, niters, err = 110 7.1205709868903853E-009
[0] 6 0.301137 0.100000E-06
[0] Solved the linear system, niters, err = 100 8.6702521024152997E-009
[0] 7 0.182866 0.100000E-06
[0] Solved the linear system, niters, err = 90 6.6177868696590077E-009
[0] 8 0.313033E-01 0.100000E-06
[0] Solved the linear system, niters, err = 75 9.7326993604869788E-009
[0] 9 0.143345E-02 0.100000E-06
[0] Solved the linear system, niters, err = 75 6.4917157538320861E-009
[0] 10 0.707905E-03 0.100000E-06
[0] Solved the linear system, niters, err = 60 8.9299555868344861E-009
[0] 11 0.353373E-03 0.100000E-06
[0] Solved the linear system, niters, err = 60 7.1632060934989904E-009
[0] 12 0.175953E-03 0.100000E-06
[0] Solved the linear system, niters, err = 50 6.2990100286147877E-009
[0] 13 0.832134E-04 0.100000E-06
[0] Solved the linear system, niters, err = 40 7.8484648720643616E-009
[0] 14 0.396185E-04 0.100000E-06
[0] Solved the linear system, niters, err = 35 9.8085560867664464E-009
[0] 15 0.198952E-04 0.100000E-06
[0] Solved the linear system, niters, err = 35 5.8732108186775663E-009
[0] 16 0.930144E-05 0.100000E-06
[0] Solved the linear system, niters, err = 30 5.6152062687134416E-009
[0] 17 0.444384E-05 0.100000E-06
[0] Solved the linear system, niters, err = 25 2.9790979934622039E-009
[0] 18 0.224661E-05 0.100000E-06
[0] Solved the linear system, niters, err = 20 6.3680193348642408E-009
[0] 19 0.103521E-05 0.100000E-06
[0] Solved the linear system, niters, err = 15 5.8310172491648561E-009
[0] 20 0.501909E-06 0.100000E-06
[0] Solved the linear system, niters, err = 15 3.3943220703983932E-009
[0] 21 0.253474E-06 0.100000E-06
[0] Solved the linear system, niters, err = 10 4.9155139806049346E-009
[0] 22 0.116913E-06 0.100000E-06
[0] Solved the linear system, niters, err = 5 9.4638430098709191E-009
[0] 23 0.569919E-07 0.100000E-06
[0] Glissade solution has converged, outer counter, err = 23 2.7079866333541956E-002
[0] Loading lat
[0] Loading lon
[0] ----------------------------------------------------------
[0]
[0] * Diagnostic output, time = 0.0000000000000000
[0]
[0] * Total ice area (km^2) 0.1667679999998247E+07
[0] * Grounded ice area (km^2) 0.1663999999998256E+07
[0] * Floating ice area (km^2) 0.3679999999999986E+04
[0] * Total ice volume (km^3) 0.2952805440572556E+07
[0] * Total ice mass (kg) 0.2707722589005033E+19
[0] * Mass above flotation (kg) 0.2668477290954696E+19
[0] * Total ice energy (J) -0.1142852668752744E+24
[0] * Total SMB flux (Gt/y) 0.0000000000000000E+00
[0] * Total BMB flux (Gt/y) -0.0000000000000000E+00
[0] * Total calving flux (Gt/y) -0.0000000000000000E+00
[0] * Total dmass/dt (Gt/y) 0.0000000000000000E+00
[0] * dmass/dt error (Gt/y) 0.0000000000000000E+00
[0] * Total gr line flux (Gt/y) -0.1245122946652798E+02
[0] * Mean thickness (m) 1770.6067354502413309
[0] * Mean temperature (C) -19.9347059892333647
[0] * Max thickness (m), i, j 3402.6667480468750000 230 366
[0] * Max temperature, i, j, k -2.5815498828887939 297 216 0
[0] * Min temperature, i, j, k -30.3878574371337891 236 451 0
[0] * Max sfc spd (m/yr), i, j 1014.7894831410661709 97 406
[0] * Max base spd (m/yr), i, j 982.8610145341251609 97 406
[0]
[0] * Grid point diagnostics: (i,j) = 134 280
[0] * Local (i,j,rank) = 136 282 0
[0]
[0] * Upper surface (m) 343.5833129882813068
[0] * Thickness (m) 732.3333129882812500
[0] * Bedrock topo (m) -388.7500000000000000
[0] * Sfc mass balance (m/yr) 0.0000000000000000
[0] * Basal mass balance (m/yr) -0.0000000000000000
[0] * Basal water depth (m) 0.0000000000000000
[0] * Basal heat flux (W/m^2) -0.0548120401799679
[0]
[0] * Sigma Ice speed (m/yr) Ice temperature (C)
[0] * 0.000 471.1818589831506188 -9.7645025253295898
[0] * 0.116 -9.2874932227323068
[0] * 0.231 461.9941624668956592
[0] * 0.319 -8.4476792256992574
[0] * 0.407 439.4390907943886191
[0] * 0.476 -7.8025271680867023
[0] * 0.544 407.2954860938086767
[0] * 0.599 -7.2961458155157555
[0] * 0.653 366.3998246671715719
[0] * 0.697 -6.8913726356655065
[0] * 0.741 317.1923216979085964
[0] * 0.777 -6.5627116616410941
[0] * 0.812 260.8834262648618392
[0] * 0.842 -6.2921959230560542
[0] * 0.872 199.3256794083273462
[0] * 0.897 -6.0668670412763541
[0] * 0.922 134.5214104177689478
[0] * 0.943 -5.8771875500593502
[0] * 0.964 68.2772661500775229
[0] * 0.982 -5.7160111263863413
[0] * 1.000 2.0601702094450474 -5.6417792671673537
[0]
[0] Opening file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220816_035656_rxjpsv.cism.initial_hist.0000-01-01-00000.nc for output;
[0] Write output at start of run and every 1.0000000000000000 years
[0] Creating variables internal_time, time, and tstep_count
[0] Creating variable level
[0] Creating variable lithoz
[0] Creating variable nlev_smb
[0] Creating variable staglevel
[0] Creating variable stagwbndlevel
[0] Creating variable x0
[0] Creating variable x1
[0] Creating variable y0
[0] Creating variable y1
[0] Creating variable zocn
[0] Creating variable artm
[0] Creating variable smb
[0] Creating variable thk
[0] Creating variable topg
[0] Creating variable usurf
[0] Writing to file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220816_035656_rxjpsv.cism.initial_hist.0000-01-01-00000.nc at time 0.0000000000000000
[0] WHL: oc_tavg_helper is not associated; associate now
[0] Opening file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220816_035656_rxjpsv.cism.tavg_helper.0000-00-00-00000.nc for output;
[0] Write output every 9999999.0000000000 years
[0] Creating variables internal_time, time, and tstep_count
[0] Creating variable level
[0] Creating variable lithoz
[0] Creating variable nlev_smb
[0] Creating variable staglevel
[0] Creating variable stagwbndlevel
[0] Creating variable x0
[0] Creating variable x1
[0] Creating variable y0
[0] Creating variable y1
[0] Creating variable zocn
[0] Creating variable artm
[0] Creating variable smb
[0] Creating variable thk
[0] Creating variable topg
[0] Creating variable usurf
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] calcsize j,iq,jac, lsfrm,lstoo 1 1 1 22 21
[0] calcsize j,iq,jac, lsfrm,lstoo 1 1 2 22 21
[0] calcsize j,iq,jac, lsfrm,lstoo 1 2 1 29 28
[0] calcsize j,iq,jac, lsfrm,lstoo 1 2 2 29 28
[0] calcsize j,iq,jac, lsfrm,lstoo 1 3 1 33 32
[0] calcsize j,iq,jac, lsfrm,lstoo 1 3 2 33 32
[0] calcsize j,iq,jac, lsfrm,lstoo 1 4 1 19 18
[0] calcsize j,iq,jac, lsfrm,lstoo 1 4 2 19 18
[0] calcsize j,iq,jac, lsfrm,lstoo 1 5 1 14 13
[0] calcsize j,iq,jac, lsfrm,lstoo 1 5 2 14 13
[0] calcsize j,iq,jac, lsfrm,lstoo 2 1 1 21 22
[0] calcsize j,iq,jac, lsfrm,lstoo 2 1 2 21 22
[0] calcsize j,iq,jac, lsfrm,lstoo 2 2 1 28 29
[0] calcsize j,iq,jac, lsfrm,lstoo 2 2 2 28 29
[0] calcsize j,iq,jac, lsfrm,lstoo 2 3 1 32 33
[0] calcsize j,iq,jac, lsfrm,lstoo 2 3 2 32 33
[0] calcsize j,iq,jac, lsfrm,lstoo 2 4 1 18 19
[0] calcsize j,iq,jac, lsfrm,lstoo 2 4 2 18 19
[0] calcsize j,iq,jac, lsfrm,lstoo 2 5 1 13 14
[0] calcsize j,iq,jac, lsfrm,lstoo 2 5 2 13 14
[0] Closing input file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc
[0] Closing output file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220816_035656_rxjpsv.cism.tavg_helper.0000-00-00-00000.nc
[0] Some Stats
[0] Maximum temperature iterations: 0
[0] User-specified PIO rearranger comm max pend req (comp2io), 0 (value will be reset as requested)
[0] Resetting PIO rearranger comm max pend req (comp2io) to 64
[0] User-specified PIO rearranger comm max pend req (io2comp), 0 (value will be reset as requested)
[0] Resetting PIO rearranger comm max pend req (io2comp) to 64
[0] PIO rearranger options:
[0] comm type = p2p
[0] comm fcd = 2denable
[0] max pend req (comp2io) = 64
[0] enable_hs (comp2io) = T
[0] enable_isend (comp2io) = F
[0] max pend req (io2comp) = 64
[0] enable_hs (io2comp) = F
[0] enable_isend (io2comp) = T
[0] 1 pes participating in computation of coupled model
[0] --------------------------------------------------------------
[0] GLOBAL communicator : 1 nodes, 1 MPI tasks
[0] COMMUNICATOR NODE # [NODE NAME] : (# OF MPI TASKS) TASK # LIST
[0] GLOBAL NODE 0 [ nelson ] : ( 1 MPI TASKS )[0] 0[0]
[0] --------------------------------------------------------------
[0] (seq_comm_setcomm) init ID ( 1 GLOBAL ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_setcomm) init ID ( 2 CPL ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_setcomm) init ID ( 5 ATM ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 6 CPLATM ) join IDs = 2 5 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 3 ALLATMID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 4 CPLALLATMID ) join IDs = 2 3 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 9 LND ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 10 CPLLND ) join IDs = 2 9 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 7 ALLLNDID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 8 CPLALLLNDID ) join IDs = 2 7 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 13 ICE ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 14 CPLICE ) join IDs = 2 13 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 11 ALLICEID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 12 CPLALLICEID ) join IDs = 2 11 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 17 OCN ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 18 CPLOCN ) join IDs = 2 17 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 15 ALLOCNID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 16 CPLALLOCNID ) join IDs = 2 15 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 21 ROF ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 22 CPLROF ) join IDs = 2 21 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 19 ALLROFID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 20 CPLALLROFID ) join IDs = 2 19 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 25 GLC ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 26 CPLGLC ) join IDs = 2 25 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 23 ALLGLCID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 24 CPLALLGLCID ) join IDs = 2 23 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 29 WAV ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 30 CPLWAV ) join IDs = 2 29 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 27 ALLWAVID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 28 CPLALLWAVID ) join IDs = 2 27 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 33 ESP ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 34 CPLESP ) join IDs = 2 33 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 31 ALLESPID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 32 CPLALLESPID ) join IDs = 2 31 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_setcomm) init ID ( 37 IAC ) pelist = 0 0 1 ( npes = 1) ( nthreads = 1)( suffix =)
[0] (seq_comm_joincomm) init ID ( 38 CPLIAC ) join IDs = 2 37 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_jcommarr) init ID ( 35 ALLIACID ) join multiple comp IDs ( npes = 1) ( nthreads = 1)
[0] (seq_comm_joincomm) init ID ( 36 CPLALLIACID ) join IDs = 2 35 ( npes = 1) ( nthreads = 1)
[0] (seq_comm_printcomms) 1 0 1 1 GLOBAL:
[0] (seq_comm_printcomms) 2 0 1 1 CPL:
[0] (seq_comm_printcomms) 3 0 1 1 ALLATMID:
[0] (seq_comm_printcomms) 4 0 1 1 CPLALLATMID:
[0] (seq_comm_printcomms) 5 0 1 1 ATM:
[0] (seq_comm_printcomms) 6 0 1 1 CPLATM:
[0] (seq_comm_printcomms) 7 0 1 1 ALLLNDID:
[0] (seq_comm_printcomms) 8 0 1 1 CPLALLLNDID:
[0] (seq_comm_printcomms) 9 0 1 1 LND:
[0] (seq_comm_printcomms) 10 0 1 1 CPLLND:
[0] (seq_comm_printcomms) 11 0 1 1 ALLICEID:
[0] (seq_comm_printcomms) 12 0 1 1 CPLALLICEID:
[0] (seq_comm_printcomms) 13 0 1 1 ICE:
[0] (seq_comm_printcomms) 14 0 1 1 CPLICE:
[0] (seq_comm_printcomms) 15 0 1 1 ALLOCNID:
[0] (seq_comm_printcomms) 16 0 1 1 CPLALLOCNID:
[0] (seq_comm_printcomms) 17 0 1 1 OCN:
[0] (seq_comm_printcomms) 18 0 1 1 CPLOCN:
[0] (seq_comm_printcomms) 19 0 1 1 ALLROFID:
[0] (seq_comm_printcomms) 20 0 1 1 CPLALLROFID:
[0] (seq_comm_printcomms) 21 0 1 1 ROF:
[0] (seq_comm_printcomms) 22 0 1 1 CPLROF:
[0] (seq_comm_printcomms) 23 0 1 1 ALLGLCID:
[0] (seq_comm_printcomms) 24 0 1 1 CPLALLGLCID:
[0] (seq_comm_printcomms) 25 0 1 1 GLC:
[0] (seq_comm_printcomms) 26 0 1 1 CPLGLC:
[0] (seq_comm_printcomms) 27 0 1 1 ALLWAVID:
[0] (seq_comm_printcomms) 28 0 1 1 CPLALLWAVID:
[0] (seq_comm_printcomms) 29 0 1 1 WAV:
[0] (seq_comm_printcomms) 30 0 1 1 CPLWAV:
[0] (seq_comm_printcomms) 31 0 1 1 ALLESPID:
[0] (seq_comm_printcomms) 32 0 1 1 CPLALLESPID:
[0] (seq_comm_printcomms) 33 0 1 1 ESP:
[0] (seq_comm_printcomms) 34 0 1 1 CPLESP:
[0] (seq_comm_printcomms) 35 0 1 1 ALLIACID:
[0] (seq_comm_printcomms) 36 0 1 1 CPLALLIACID:
[0] (seq_comm_printcomms) 37 0 1 1 IAC:
[0] (seq_comm_printcomms) 38 0 1 1 CPLIAC:
[0] (t_initf) Read in prof_inparm namelist from: drv_in
[0] (t_initf) Using profile_disable= F
[0] (t_initf) profile_timer= 4
[0] (t_initf) profile_depth_limit= 12
[0] (t_initf) profile_detail_limit= 2
[0] (t_initf) profile_barrier= F
[0] (t_initf) profile_outpe_num= 1
[0] (t_initf) profile_outpe_stride= 0
[0] (t_initf) profile_single_file= F
[0] (t_initf) profile_global_stats= T
[0] (t_initf) profile_ovhd_measurement= F
[0] (t_initf) profile_add_detail= F
[0] (t_initf) profile_papi_enable= F
[0] 1 pes participating in computation
[0] -----------------------------------
[0] TASK# NAME
[0] 0 nelson
[0]
[0] l, cnst_name(l), cnst_name_cw(l)
[0] 1 Q
[0] 2 CLDLIQ
[0] 3 CLDICE
[0] 4 NUMLIQ
[0] 5 NUMICE
[0] 6 RAINQM
[0] 7 SNOWQM
[0] 8 NUMRAI
[0] 9 NUMSNO
[0] 10 bc_a1 bc_c1
[0] 11 bc_a4 bc_c4
[0] 12 DMS
[0] 13 dst_a1 dst_c1
[0] 14 dst_a2 dst_c2
[0] 15 dst_a3 dst_c3
[0] 16 H2O2
[0] 17 H2SO4
[0] 18 ncl_a1 ncl_c1
[0] 19 ncl_a2 ncl_c2
[0] 20 ncl_a3 ncl_c3
[0] 21 num_a1 num_c1
[0] 22 num_a2 num_c2
[0] 23 num_a3 num_c3
[0] 24 num_a4 num_c4
[0] 25 pom_a1 pom_c1
[0] 26 pom_a4 pom_c4
[0] 27 SO2
[0] 28 so4_a1 so4_c1
[0] 29 so4_a2 so4_c2
[0] 30 so4_a3 so4_c3
[0] 31 SOAG
[0] 32 soa_a1 soa_c1
[0] 33 soa_a2 soa_c2
[0] calcsize addfld - num_a1_sfcsiz1
[0] calcsize addfld - num_a1_sfcsiz2
[0] calcsize addfld - num_c1_sfcsiz1
[0] calcsize addfld - num_c1_sfcsiz2
[0] calcsize addfld - num_a2_sfcsiz1
[0] calcsize addfld - num_a2_sfcsiz2
[0] calcsize addfld - num_c2_sfcsiz1
[0] calcsize addfld - num_c2_sfcsiz2
[0] calcsize addfld - num_a3_sfcsiz1
[0] calcsize addfld - num_a3_sfcsiz2
[0] calcsize addfld - num_c3_sfcsiz1
[0] calcsize addfld - num_c3_sfcsiz2
[0] calcsize addfld - num_a4_sfcsiz1
[0] calcsize addfld - num_a4_sfcsiz2
[0] calcsize addfld - num_c4_sfcsiz1
[0] calcsize addfld - num_c4_sfcsiz2
[0] calcsize addfld - num_a2_sfcsiz3
[0] calcsize addfld - num_a1_sfcsiz3
[0] calcsize addfld - num_a2_sfcsiz4
[0] calcsize addfld - num_a1_sfcsiz4
[0] calcsize addfld - num_c2_sfcsiz3
[0] calcsize addfld - num_c1_sfcsiz3
[0] calcsize addfld - num_c2_sfcsiz4
[0] calcsize addfld - num_c1_sfcsiz4
[0] calcsize addfld - so4_a2_sfcsiz3
[0] calcsize addfld - so4_a1_sfcsiz3
[0] calcsize addfld - so4_a2_sfcsiz4
[0] calcsize addfld - so4_a1_sfcsiz4
[0] calcsize addfld - so4_c2_sfcsiz3
[0] calcsize addfld - so4_c1_sfcsiz3
[0] calcsize addfld - so4_c2_sfcsiz4
[0] calcsize addfld - so4_c1_sfcsiz4
[0] calcsize addfld - soa_a2_sfcsiz3
[0] calcsize addfld - soa_a1_sfcsiz3
[0] calcsize addfld - soa_a2_sfcsiz4
[0] calcsize addfld - soa_a1_sfcsiz4
[0] calcsize addfld - soa_c2_sfcsiz3
[0] calcsize addfld - soa_c1_sfcsiz3
[0] calcsize addfld - soa_c2_sfcsiz4
[0] calcsize addfld - soa_c1_sfcsiz4
[0] calcsize addfld - ncl_a2_sfcsiz3
[0] calcsize addfld - ncl_a1_sfcsiz3
[0] calcsize addfld - ncl_a2_sfcsiz4
[0] calcsize addfld - ncl_a1_sfcsiz4
[0] calcsize addfld - ncl_c2_sfcsiz3
[0] calcsize addfld - ncl_c1_sfcsiz3
[0] calcsize addfld - ncl_c2_sfcsiz4
[0] calcsize addfld - ncl_c1_sfcsiz4
[0] calcsize addfld - dst_a2_sfcsiz3
[0] calcsize addfld - dst_a1_sfcsiz3
[0] calcsize addfld - dst_a2_sfcsiz4
[0] calcsize addfld - dst_a1_sfcsiz4
[0] calcsize addfld - dst_c2_sfcsiz3
[0] calcsize addfld - dst_c1_sfcsiz3
[0] calcsize addfld - dst_c2_sfcsiz4
[0] calcsize addfld - dst_c1_sfcsiz4
[0]
[0] subr. modal_aero_gasaerexch_init - primary carbon aging pointers
[0] pair 1 mode 4 ---> mode 1
[0] spec 24=num_a4 ---> spec 21=num_a1
[0] spec 26=pom_a4 ---> spec 25=pom_a1
[0] spec 11=bc_a4 ---> spec 10=bc_a1
[0]
[0] qconff addfld qconff_gaex kg/kg/s
[0] qevapff addfld qevapff_gaex kg/kg/s
[0] qconbb addfld qconbb_gaex kg/kg/s
[0] qevapbb addfld qevapbb_gaex kg/kg/s
[0] qconbg addfld qconbg_gaex kg/kg/s
[0] qevapbg addfld qevapbg_gaex kg/kg/s
[0] qcon addfld qcon_gaex kg/kg/s
[0] qevap addfld qevap_gaex kg/kg/s
[0] gasaerexch addfld bc_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld bc_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld H2SO4_sfgaex1 kg/m2/s
[0] gasaerexch addfld num_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld num_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld pom_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld pom_a4_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a2_sfgaex1 kg/m2/s
[0] gasaerexch addfld so4_a3_sfgaex1 kg/m2/s
[0] gasaerexch addfld SOAG_sfgaex1 kg/m2/s
[0] gasaerexch addfld soa_a1_sfgaex1 kg/m2/s
[0] gasaerexch addfld soa_a2_sfgaex1 kg/m2/s
[0] gasaerexch addfld dst_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld dst_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld ncl_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld num_a1_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c1_sfgaex2 #/m2/s
[0] gasaerexch addfld num_a2_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c2_sfgaex2 #/m2/s
[0] gasaerexch addfld num_a3_sfgaex2 #/m2/s
[0] gasaerexch addfld num_c3_sfgaex2 #/m2/s
[0] gasaerexch addfld so4_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c2_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_a3_sfgaex2 kg/m2/s
[0] gasaerexch addfld so4_c3_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_a1_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_c1_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_a2_sfgaex2 kg/m2/s
[0] gasaerexch addfld soa_c2_sfgaex2 kg/m2/s
[0]
[0] subr. modal_aero_coag_init
[0] pair 1 mode 2 ---> mode 1 eff 1
[0] spec 29=so4_a2 ---> spec 28=so4_a1
[0] spec 33=soa_a2 ---> spec 32=soa_a1
[0] spec 19=ncl_a2 ---> spec 18=ncl_a1
[0] spec 14=dst_a2 ---> spec 13=dst_a1
[0] pair 2 mode 4 ---> mode 1 eff 1
[0] spec 26=pom_a4 ---> spec 25=pom_a1
[0] spec 11=bc_a4 ---> spec 10=bc_a1
[0] pair 3 mode 2 ---> mode 4 eff 1
[0] spec 29=so4_a2 ---> spec 28=so4_a1
[0] spec 33=soa_a2 ---> spec 32=soa_a1
[0] spec 19=ncl_a2 ---> spec 18=ncl_a1
[0] spec 14=dst_a2 ---> spec 13=dst_a1
[0]
[0] modal_aero_coag_init addfld bc_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld bc_a4_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld dst_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld dst_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld ncl_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld ncl_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld num_a1_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld num_a2_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld num_a4_sfcoag1 #/m2/s
[0] modal_aero_coag_init addfld pom_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld pom_a4_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld so4_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld so4_a2_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld soa_a1_sfcoag1 kg/m2/s
[0] modal_aero_coag_init addfld soa_a2_sfcoag1 kg/m2/s
[0] modal_aero_newnuc_init addfld H2SO4_sfnnuc1 kg/m2/s
[0] modal_aero_newnuc_init addfld num_a2_sfnnuc1 #/m2/s
[0] modal_aero_newnuc_init addfld so4_a2_sfnnuc1 kg/m2/s
[0]
[0]
[0] 1 pes participating in computation for CLM
[0]
[0] -----------------------------------
[0]
[0] NODE# NAME
[0] ( 0) nelson
[0] Reading setup_nml
[0] Reading grid_nml
[0] Reading tracer_nml
[0] Reading thermo_nml
[0] Reading dynamics_nml
[0] Reading shortwave_nml
[0] Reading ponds_nml
[0] Reading forcing_nml
[0] Reading zbgc_nml
[0] Grid specification
[0] ------------------
[0] ewn : 416
[0] nsn : 704
[0] upn : 11
[0] EW grid spacing : 4000.0000000000000
[0] NS grid spacing : 4000.0000000000000
[0] Outflow global boundary conditions; scalars in global halo will be set to zero
[0] sigma file :
[0]
[0] Time steps
[0] ----------
[0] start time (yr) : 0.0000000000000000
[0] end time (yr) : 1000.0000000000000
[0] time step (yr) : 0.10000000000000001
[0] nsteps per year : 10
[0] thermal dt factor : 1.0000000000000000
[0] diagnostic interval (years): 0.10000000000000001
[0]
[0] Dycore options
[0] -------------
[0] I/O parameter file :
[0] Dycore : 2 glissade
[0] temperature calculation : 1 prognostic temperature
[0] flow law : 2 Paterson and Budd
[0] basal_water : 0 none
[0] marine_margin : 1 remove all floating ice
[0] calving_init : 1 ice calves at initialization
[0] calving_domain : 1 calving in all cells where criterion is met
[0] Icebergs will be removed
[0] The thickness of marine ice cliffs will be limited
[0] calving_domain : 1 calving in all cells where criterion is met
[0] Calving-front cells will not be culled at initialization
[0] evolution : 3 incremental remapping
[0] minthck for diagnostics : 1 include cells with H > thklim in global diagnostics
[0] vertical_integration : 0 standard
[0] basal melt, floating ice: 0 none
[0] basal mass balance : 1 in continuity eqn
[0] smb input units : 0 SMB input in units of m/yr ice
[0] smb input function : 0 SMB input as function of (x,y)
[0] artm input function : 0 artm input as function of (x,y)
[0] overwrite_acab : 0 do not overwrite acab anywhere
[0] geothermal heat flux : 1 read flux from file, if present
[0] isostasy : 0 no isostasy calculation
[0]
[0] Higher-order options:
[0] ----------
[0] ho_whichefvs : 2 nonlinear, from eff strain rate
[0] ho_whichdisp : 1 first-order model (Blatter-Pattyn)
[0] ho_whichthermal_timestep: 2 vertical thermal solve split into two parts
[0] ho_whichbabc : 3 pseudo-plastic sliding law
[0] ho_whichbeta_limit : 0 absolute beta limit based on beta_grounded_min
[0] ho_whichbwat : 2 basal water depth computed from local till model
[0] ho_whicheffecpress : 4 reduced effecpress with increasing basal water
[0] which_ho_nonlinear : 1 use Picard iteration with acceleration
[0] ho_whichresid : 4 relative L2 norm, |Ax-b|/|b|
[0] ho_whichsparse : 3 Native PCG solver, Chronopoulos-Gear
[0] ho_whichapprox : 4 Depth-integrated viscosity (glissade_velo_higher)
[0] ho_whichgradient : 0 centered gradient (glissade)
[0] ho_whichgradient_margin : 1 compute edge gradient when ice lies above ice-free land
[0] ho_whichvertical_remap : 0 first-order accurate
[0] ho_whichassemble_beta : 1 use local beta at each vertex (glissade dycore)
[0] ho_whichassemble_taud : 1 use local driving stress at each vertex (glissade dycore)
[0] ho_whichassemble_bfric : 1 use local basal friction at each vertex (glissade dycore)
[0] ho_whichassemble_lateral : 1 use local thck and usrf on each cell face (glissade dycore)
[0] ho_whichcalving_front : 0 no subgrid calving front parameterization
[0] ho_whichground : 2 deluxe GLP, 0 <= f_ground <= 1 for both vertices and cells
[0] ho_whichground_bmlt : 1 weigh bmlt_float by floating fraction of cell
[0] ho_whichflotation_function: 3 modified linear = -b - (rhoi/rhoo)*H
[0] ho_whichice_age : 1 ice age computation on
[0] glissade_maxiter : 50
[0] linear_solve_ncheck : 5
[0] linear_maxiters : 200
[0] linear_tolerance : 1.0000000000000000E-008
[0] ho_whichprecond : 1 Diagonal preconditioner (native PCG)
[0]
[0] Parameters
[0] ----------
[0] thickness limit for dynamically active ice (m) : 1.0000000000000000
[0] Advection will be subcycled when CFL > 0.50000000000000000
[0] thickness limit for temperature calculations (m) : 1.0000000000000000
[0] thickness scale for gradient ramp (m): 50.000000000000000
[0] pmp threshold for temperature (K): 1.0000000000000000E-003
[0] taumax_cliff : 1000000.0000000000
[0] cliff time scale (yr) : 0.0000000000000000
[0] ice density (kg/m^3) : 917.00000000000000
[0] ocean density (kg/m^3) : 1026.0000000000000
[0] gravitational accel (m/s^2) : 9.8061600000000002
[0] heat capacity of ice (J/kg/K) : 2117.2700000000000
[0] latent heat of ice (J/kg) : 333700.00000000000
[0] triple point of water (K) : 273.16000000000003
[0] geothermal flux (W/m^2) : -5.0000000000000003E-002
[0] flow factor (grounded ice) : 1.0000000000000000
[0] flow factor (floating ice) : 1.0000000000000000
[0] max surface slope : 0.10000000000000001
[0] min effective strain rate (yr^-1) : 1.0000000000000000E-008
[0] pseudo-plastic q : 0.50000000000000000
[0] pseudo-plastic u0 : 100.00000000000000
[0] pseudo-plastic phi_min (deg) : 5.0000000000000000
[0] pseudo-plastic phi_max (deg) : 40.000000000000000
[0] pseudo-plastic bed min (m) : -700.00000000000000
[0] pseudo-plastic bed max (m) : 700.00000000000000
[0] min beta, grounded ice (Pa yr/m) : 100.00000000000000
[0] effective pressure delta : 2.0000000000000000E-002
[0] maximum till water depth (m) : 2.0000000000000000
[0] till drainage rate (m/yr) : 1.0000000000000000E-003
[0]
[0] number of ocean levels : 1
[0] Reading zocn levels from config file
[0] No ocean basins
[0]
[0] GLAD climate
[0] -------------
[0] evolve_ice (0=fixed, 1=evolve): 0
[0] The ice sheet state will not evolve after initialization
[0] Mass-balance accumulation time will be set to max(ice timestep, mbal timestep)
[0] ice_tstep_multiply: 1
[0] In glissade_initialise
[0] CISM 2.0
[0] Setting outflow boundary conditions
[0] Layout(EW,NS) = 416 704 total procs = 1
[0] Computing Glide sigma levels
[0] Sigma levels:
[0] ------------------
[0] 0.000 0.231 0.407 0.544 0.653 0.741 0.812 0.872 0.922 0.964 1.000
[0]
[0] opening file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc for input
[0] * WARNING: Input file contained no level dimension. This is not necessarily a problem.
[0] Reading time slice 1 ( 0.0000000000000000 ) from file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc at time 0.0000000000000000
[0] Loading x1
[0] Loading y1
[0] Loading acab
[0] * scaling acab
[0] Loading artm
[0] Loading bheatflx
[0] Loading lat
[0] Loading lon
[0] Loading thk
[0] * scaling thk
[0] Loading topg
[0] * scaling topg
[0] Global idiag, jdiag: 134 280
[0] Local idiag, jdiag, task: 136 282 0
[0] * Global idiag, jdiag: 134 280
[0] * Local idiag, jdiag, task: 136 282 0
[0] Set area scale factor = 1 for polar stereographic projection
[0] Projection
[0] ----------
[0] Type: Stereographic
[0] Longitude of central meridian: -45.000000000000000
[0] Latitude of projection origin: 90.000000000000000
[0] False easting: 0.0000000000000000
[0] False northing: 0.0000000000000000
[0] Standard parallel: 70.000000000000000
[0] Scale factor: 0.0000000000000000
[0] compute_area_factor: F
[0] Initializing ice temperature based on advective-diffusive balance in each column
[0] Offset from pressure melting point temperature = 5.0000000000000000
[0] Done in glissade_initialise
[0]
[0] Compute ice velocities, time = 0.0000000000000000
[0] Solving depth-integrated viscosity approximation
[0] Running with Picard acceleration
[0]
[0] iter # resid, |Ax-b|/|b| target resid
[0] Solved the linear system, niters, err = 190 9.4299768209613969E-009
[0] 1 1.00000 0.100000E-06
[0] Solved the linear system, niters, err = 175 7.1343923159488724E-009
[0] 2 0.842258 0.100000E-06
[0] Solved the linear system, niters, err = 175 3.4561872633109964E-009
[0] 3 0.807756 0.100000E-06
[0] Solved the linear system, niters, err = 150 6.2298748722726354E-009
[0] 4 0.642726 0.100000E-06
[0] Solved the linear system, niters, err = 120 6.4413966933533493E-009
[0] 5 0.460887 0.100000E-06
[0] Solved the linear system, niters, err = 110 7.1205709868903853E-009
[0] 6 0.301137 0.100000E-06
[0] Solved the linear system, niters, err = 100 8.6702521024152997E-009
[0] 7 0.182866 0.100000E-06
[0] Solved the linear system, niters, err = 90 6.6177868696590077E-009
[0] 8 0.313033E-01 0.100000E-06
[0] Solved the linear system, niters, err = 75 9.7326993604869788E-009
[0] 9 0.143345E-02 0.100000E-06
[0] Solved the linear system, niters, err = 75 6.4917157538320861E-009
[0] 10 0.707905E-03 0.100000E-06
[0] Solved the linear system, niters, err = 60 8.9299555868344861E-009
[0] 11 0.353373E-03 0.100000E-06
[0] Solved the linear system, niters, err = 60 7.1632060934989904E-009
[0] 12 0.175953E-03 0.100000E-06
[0] Solved the linear system, niters, err = 50 6.2990100286147877E-009
[0] 13 0.832134E-04 0.100000E-06
[0] Solved the linear system, niters, err = 40 7.8484648720643616E-009
[0] 14 0.396185E-04 0.100000E-06
[0] Solved the linear system, niters, err = 35 9.8085560867664464E-009
[0] 15 0.198952E-04 0.100000E-06
[0] Solved the linear system, niters, err = 35 5.8732108186775663E-009
[0] 16 0.930144E-05 0.100000E-06
[0] Solved the linear system, niters, err = 30 5.6152062687134416E-009
[0] 17 0.444384E-05 0.100000E-06
[0] Solved the linear system, niters, err = 25 2.9790979934622039E-009
[0] 18 0.224661E-05 0.100000E-06
[0] Solved the linear system, niters, err = 20 6.3680193348642408E-009
[0] 19 0.103521E-05 0.100000E-06
[0] Solved the linear system, niters, err = 15 5.8310172491648561E-009
[0] 20 0.501909E-06 0.100000E-06
[0] Solved the linear system, niters, err = 15 3.3943220703983932E-009
[0] 21 0.253474E-06 0.100000E-06
[0] Solved the linear system, niters, err = 10 4.9155139806049346E-009
[0] 22 0.116913E-06 0.100000E-06
[0] Solved the linear system, niters, err = 5 9.4638430098709191E-009
[0] 23 0.569919E-07 0.100000E-06
[0] Glissade solution has converged, outer counter, err = 23 2.7079866333541956E-002
[0] Loading lat
[0] Loading lon
[0] ----------------------------------------------------------
[0]
[0] * Diagnostic output, time = 0.0000000000000000
[0]
[0] * Total ice area (km^2) 0.1667679999998247E+07
[0] * Grounded ice area (km^2) 0.1663999999998256E+07
[0] * Floating ice area (km^2) 0.3679999999999986E+04
[0] * Total ice volume (km^3) 0.2952805440572556E+07
[0] * Total ice mass (kg) 0.2707722589005033E+19
[0] * Mass above flotation (kg) 0.2668477290954696E+19
[0] * Total ice energy (J) -0.1142852668752744E+24
[0] * Total SMB flux (Gt/y) 0.0000000000000000E+00
[0] * Total BMB flux (Gt/y) -0.0000000000000000E+00
[0] * Total calving flux (Gt/y) -0.0000000000000000E+00
[0] * Total dmass/dt (Gt/y) 0.0000000000000000E+00
[0] * dmass/dt error (Gt/y) 0.0000000000000000E+00
[0] * Total gr line flux (Gt/y) -0.1245122946652798E+02
[0] * Mean thickness (m) 1770.6067354502413309
[0] * Mean temperature (C) -19.9347059892333647
[0] * Max thickness (m), i, j 3402.6667480468750000 230 366
[0] * Max temperature, i, j, k -2.5815498828887939 297 216 0
[0] * Min temperature, i, j, k -30.3878574371337891 236 451 0
[0] * Max sfc spd (m/yr), i, j 1014.7894831410661709 97 406
[0] * Max base spd (m/yr), i, j 982.8610145341251609 97 406
[0]
[0] * Grid point diagnostics: (i,j) = 134 280
[0] * Local (i,j,rank) = 136 282 0
[0]
[0] * Upper surface (m) 343.5833129882813068
[0] * Thickness (m) 732.3333129882812500
[0] * Bedrock topo (m) -388.7500000000000000
[0] * Sfc mass balance (m/yr) 0.0000000000000000
[0] * Basal mass balance (m/yr) -0.0000000000000000
[0] * Basal water depth (m) 0.0000000000000000
[0] * Basal heat flux (W/m^2) -0.0548120401799679
[0]
[0] * Sigma Ice speed (m/yr) Ice temperature (C)
[0] * 0.000 471.1818589831506188 -9.7645025253295898
[0] * 0.116 -9.2874932227323068
[0] * 0.231 461.9941624668956592
[0] * 0.319 -8.4476792256992574
[0] * 0.407 439.4390907943886191
[0] * 0.476 -7.8025271680867023
[0] * 0.544 407.2954860938086767
[0] * 0.599 -7.2961458155157555
[0] * 0.653 366.3998246671715719
[0] * 0.697 -6.8913726356655065
[0] * 0.741 317.1923216979085964
[0] * 0.777 -6.5627116616410941
[0] * 0.812 260.8834262648618392
[0] * 0.842 -6.2921959230560542
[0] * 0.872 199.3256794083273462
[0] * 0.897 -6.0668670412763541
[0] * 0.922 134.5214104177689478
[0] * 0.943 -5.8771875500593502
[0] * 0.964 68.2772661500775229
[0] * 0.982 -5.7160111263863413
[0] * 1.000 2.0601702094450474 -5.6417792671673537
[0]
[0] Opening file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cism.initial_hist.0000-01-01-00000.nc for output;
[0] Write output at start of run and every 1.0000000000000000 years
[0] Creating variables internal_time, time, and tstep_count
[0] Creating variable level
[0] Creating variable lithoz
[0] Creating variable nlev_smb
[0] Creating variable staglevel
[0] Creating variable stagwbndlevel
[0] Creating variable x0
[0] Creating variable x1
[0] Creating variable y0
[0] Creating variable y1
[0] Creating variable zocn
[0] Creating variable artm
[0] Creating variable smb
[0] Creating variable thk
[0] Creating variable topg
[0] Creating variable usurf
[0] Writing to file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cism.initial_hist.0000-01-01-00000.nc at time 0.0000000000000000
[0] WHL: oc_tavg_helper is not associated; associate now
[0] Opening file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cism.tavg_helper.0000-00-00-00000.nc for output;
[0] Write output every 9999999.0000000000 years
[0] Creating variables internal_time, time, and tstep_count
[0] Creating variable level
[0] Creating variable lithoz
[0] Creating variable nlev_smb
[0] Creating variable staglevel
[0] Creating variable stagwbndlevel
[0] Creating variable x0
[0] Creating variable x1
[0] Creating variable y0
[0] Creating variable y1
[0] Creating variable zocn
[0] Creating variable artm
[0] Creating variable smb
[0] Creating variable thk
[0] Creating variable topg
[0] Creating variable usurf
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: RGSMap indices not increasing...Will correct
[0] MCT::m_Router::initp_: GSMap indices not increasing...Will correct
[0] calcsize j,iq,jac, lsfrm,lstoo 1 1 1 22 21
[0] calcsize j,iq,jac, lsfrm,lstoo 1 1 2 22 21
[0] calcsize j,iq,jac, lsfrm,lstoo 1 2 1 29 28
[0] calcsize j,iq,jac, lsfrm,lstoo 1 2 2 29 28
[0] calcsize j,iq,jac, lsfrm,lstoo 1 3 1 33 32
[0] calcsize j,iq,jac, lsfrm,lstoo 1 3 2 33 32
[0] calcsize j,iq,jac, lsfrm,lstoo 1 4 1 19 18
[0] calcsize j,iq,jac, lsfrm,lstoo 1 4 2 19 18
[0] calcsize j,iq,jac, lsfrm,lstoo 1 5 1 14 13
[0] calcsize j,iq,jac, lsfrm,lstoo 1 5 2 14 13
[0] calcsize j,iq,jac, lsfrm,lstoo 2 1 1 21 22
[0] calcsize j,iq,jac, lsfrm,lstoo 2 1 2 21 22
[0] calcsize j,iq,jac, lsfrm,lstoo 2 2 1 28 29
[0] calcsize j,iq,jac, lsfrm,lstoo 2 2 2 28 29
[0] calcsize j,iq,jac, lsfrm,lstoo 2 3 1 32 33
[0] calcsize j,iq,jac, lsfrm,lstoo 2 3 2 32 33
[0] calcsize j,iq,jac, lsfrm,lstoo 2 4 1 18 19
[0] calcsize j,iq,jac, lsfrm,lstoo 2 4 2 18 19
[0] calcsize j,iq,jac, lsfrm,lstoo 2 5 1 13 14
[0] calcsize j,iq,jac, lsfrm,lstoo 2 5 2 13 14
[0] Closing input file /home/pub/cam_inputdata/glc/cism/Greenland/greenland_4km_epsg3413_c171126.nc
[0] Closing output file ERP_Ln9.f10_f10_mg37.F2000climo.nelson_gnu.cam-silhs.20220817_041208_usz6g8.cism.tavg_helper.0000-00-00-00000.nc
[0] Some Stats
[0] Maximum temperature iterations: 0
[Pipeline] }
[Pipeline] // script
[Pipeline] script
[Pipeline] {
[Pipeline] }
[Pipeline] // script
[Pipeline] }
[Pipeline] // stage
[Pipeline] }
[Pipeline] // withEnv
[Pipeline] }
[Pipeline] // node
[Pipeline] End of Pipeline
ERROR: script returned exit code 100
Finished: FAILURE
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