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jscott |
1.4 |
C $Header$ |
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C $Name$ |
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jscott |
1.1 |
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#include "ctrparam.h" |
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! ========================================================== |
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! |
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! SURFACE.F: THIS SUBROUTINE CALCULATES THE SURFACE FLUXES |
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! WHICH INCLUDE SENSIBLE HEAT, EVAPORATION, |
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! THERMAL RADIATION, AND MOMENTUM DRAG. IT ALSO |
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! CALCULATES INSTANTANEOUSLY SURFACE TEMPERATURE, |
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! SURFACE SPECIFIC HUMIDITY, AND SURFACE WIND |
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! COMPONENTS. |
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! |
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! ---------------------------------------------------------- |
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! |
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! Author of Chemistry Modules: Chien Wang |
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! |
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! ---------------------------------------------------------- |
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! |
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! Revision History: |
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! |
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! When Who What |
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! ---- ---------- ------- |
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! 073100 Chien Wang repack based on CliChem3 and add cpp |
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! 092301 Chien Wang add bc and oc |
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! |
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! ========================================================== |
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SUBROUTINE SURF_OCEAN |
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C**** 5802. |
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C**** THIS SUBROUTINE CALCULATES THE SURFACE FLUXES WHICH INCLUDE 5803. |
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C**** SENSIBLE HEAT, EVAPORATION, THERMAL RADIATION, AND MOMENTUM 5804. |
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C**** DRAG. IT ALSO CALCULATES INSTANTANEOUSLY SURFACE TEMPERATURE, 5805. |
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C**** SURFACE SPECIFIC HUMIDITY, AND SURFACE WIND COMPONENTS. 5806. |
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C**** 5807. |
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#if ( defined CPL_CHEM ) |
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! |
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#include "chem_para" |
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#include "chem_com" |
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! |
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#endif |
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#include "BD2G04.COM" |
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#if ( defined CLM ) |
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jscott |
1.3 |
#include "CLM.h" |
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jscott |
1.1 |
#endif |
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COMMON/SPEC2/KM,KINC,COEK,C3LAND(IO0,JM0),C3OICE(IO0,JM0) 5808.1 |
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* ,C3LICE(IO0,JM0),WMGE(IO0,JM0),TSSFC(1,JM0,4) 5808.2 |
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COMMON U,V,T,P,Q 5809. |
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COMMON/WORK1/CONV(IM0,JM0,LM0),PK(IM0,JM0,LM0),PREC(IM0,JM0), |
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& TPREC(IM0,JM0), 5810. |
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* COSZ1(IO0,JM0) 5811. |
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COMMON/WORK2/UT(IM0,JM0,LM0),VT(IM0,JM0,LM0),DU1(IO0,JM0), |
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& DV1(IO0,JM0), 5812. |
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* RA(8),ID(8),UMS(8) 5813. |
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COMMON/WORK3/E0(IO0,JM0,4),E1(IO0,JM0,4),EVAPOR(IO0,JM0,4), 5814. |
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* TGRND(IO0,JM0,4) 5814.1 |
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COMMON/RDATA/ROUGHL(IO0,JM0) 5815. |
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DIMENSION SINI(72),COSI(72) 5816. |
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DIMENSION WMGMIN(JM0) |
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LOGICAL POLE,PRNT,HPRNT |
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common/conprn/HPRNT |
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jscott |
1.3 |
! common/TSUR/TSURFC(JM0,0:13),TSURFT(JM0),TSURFD(JM0),DTEMSR(JM0) |
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#include "TSRF.COM" |
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jscott |
1.1 |
common/SURRAD/TRSURF(JM0,4),SRSURF(JM0,4) |
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c REAL*8 B,TGV,TKV,TSV0,TSV1,TSV 5818. |
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COMMON/CWMG/WMGEA(JM0),NWMGEA(JM0),CHAVER(JM0),DTAV(JM0),DQAV(JM0) |
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& ,Z0AV(JM0),WSAV(JM0),WS0AV(JM0),TAUAV(JM0) |
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COMMON/SURFLAND/ DUL1(JM0),DVL1(JM0),DT1L(JM0),DQ1L(JM0), |
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& WSSL(JM0),T2ML(JM0), |
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& TSSL(JM0),QSSL(JM0),USSL(JM0),VSSL(JM0),TAUSL(JM0),BLJ(JM0,50) |
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& ,ELHTG(JM0),SHTG(JM0),TAUXG(JM0),TAUYG(JM0) |
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jscott |
1.3 |
real T2MZ(JM0) |
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jscott |
1.1 |
C |
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#if ( defined OCEAN_3D || defined ML_2D) |
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jscott |
1.2 |
#include "AGRID.h" |
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jscott |
1.1 |
#endif |
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c |
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DATA RVAP/461.5/ 5819. |
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DATA SHV/0./,SHW/4185./,SHI/2060./,RHOW/1000./,RHOI/916.6/, 5820. |
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* ALAMI/2.1762/,STBO/.5672573E-7/,TF/273.16/,TFO/-1.56/ 5821. |
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DATA Z1I/.1/,Z2LI/2.9/,Z1E/.1/,Z2E/4./,RHOS/91.66/,ALAMS/.35/ 5822. |
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DIMENSION AROUGH(20),BROUGH(20),CROUGH(20),DROUGH(20),EROUGH(20) 5823. |
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DATA AROUGH/16.59,13.99,10.4,7.35,5.241,3.926,3.126,2.632,2.319, 5824. |
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*2.116,1.982,1.893,1.832,1.788,1.757,1.733,1.714,1.699,1.687,1.677/5825. |
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DATA BROUGH/3.245,1.733,0.8481,0.3899,0.1832,0.9026E-1,0.4622E-1, 5826. |
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* .241E-1,.1254E-1,.6414E-2,.3199E-2,.1549E-2,.7275E-3,.3319E-3, 5827. |
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* .1474E-3,.6392E-4,.2713E-4,.1130E-4,.4630E-5,.1868E-5/ 5828. |
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DATA CROUGH/5.111,3.088,1.682,.9239,.5626,.3994,.3282,.3017,.299 5829. |
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*,.3114,.3324,.3587,.3881,.4186,.4492,.4792,.5082,.5361,.5627, 5830. |
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* .5882/ 5831. |
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DATA DROUGH/1.24,1.02,0.806,0.682,0.661,0.771,0.797,0.895,0.994, 5832. |
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* 1.09,1.18,1.27,1.35,1.43,1.50,1.58,1.65,1.71,1.78,1.84/ 5833. |
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DATA EROUGH/0.128,0.130,0.141,0.174,0.238,0.330,0.438,0.550,0.660,5834. |
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* 0.766,0.866,0.962,1.05,1.14,1.22,1.30,1.37,1.45,1.52,1.58/ 5835. |
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QSAT(TM,PR,QLH)=3.797915*EXP(QLH*(7.93252E-6-2.166847E-3/TM))/PR 5836. |
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DLQSDT(TM,QLH)=QLH*2.166847E-3/(TM*TM) |
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c TLOG(Z0)=ALOG(.36*SQRTT/(FMAG*Z0))+2.302585*ROUGH-.08 5837. |
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DATA IFIRST/1/ 5838. |
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ROSNOW(X)=0.54*X/LOG(1.+0.54*X/275.) |
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ALSNOW(X)=2.8E-6*X**2 |
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C**** 5839. |
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C**** FDATA 2 LAND COVERAGE (1) 5840. |
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C**** 3 RATIO OF LAND ICE COVERAGE TO LAND COVERAGE (1) 5841. |
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C**** 5842. |
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C**** ODATA 1 OCEAN TEMPERATURE (C) 5843. |
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C**** 2 RATIO OF OCEAN ICE COVERAGE TO WATER COVERAGE (1) 5844. |
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C**** 3 OCEAN ICE AMOUNT OF SECOND LAYER (KG/M**2) 5845. |
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C**** 5846. |
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C**** GDATA 1 OCEAN ICE SNOW AMOUNT (KG/M**2) 5847. |
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C**** 2 EARTH SNOW AMOUNT (KG/M**2) 5848. |
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C**** 3 OCEAN ICE TEMPERATURE OF FIRST LAYER (C) 5849. |
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C**** 4 EARTH TEMPERATURE OF FIRST LAYER (C) 5850. |
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C**** 5 EARTH WATER OF FIRST LAYER (KG/M**2) 5851. |
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C**** 6 EARTH ICE OF FIRST LAYER (KG/M**2) 5852. |
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C**** 7 OCEAN ICE TEMPERATURE OF SECOND LAYER (C) 5853. |
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C**** 8 EARTH TEMPERATURE OF SECOND LAYER (C) 5854. |
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C**** 9 EARTH WATER OF SECOND LAYER (KG/M**2) 5855. |
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C**** 10 EARTH ICE OF SECOND LAYER (KG/M**2) 5856. |
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C**** 12 LAND ICE SNOW AMOUNT (KG/M**2) 5857. |
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C**** 13 LAND ICE TEMPERATURE OF FIRST LAYER (C) 5858. |
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C**** 14 LAND ICE TEMPERATURE OF SECOND LAYER (C) 5859. |
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C**** 5860. |
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C**** BLDATA 1 COMPOSITE SURFACE WIND MAGNITUDE (M/S) 5861. |
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C**** 2 COMPOSITE SURFACE AIR TEMPERATURE (K) 5862. |
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C**** 3 COMPOSITE SURFACE AIR SPECIFIC HUMIDITY (1) 5863. |
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C**** 4 LAYER TO WHICH DRY CONVECTION MIXES (1) 5864. |
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C**** 5 FREE 5865. |
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C**** 6 COMPOSITE SURFACE U WIND 5866. |
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C**** 7 COMPOSITE SURFACE V WIND 5867. |
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C**** 8 COMPOSITE SURFACE MOMENTUM TRANSFER (TAU) 5868. |
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C**** 5869. |
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C**** VDATA 9 WATER FIELD CAPACITY OF FIRST LAYER (KG/M**2) 5870. |
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C**** 10 WATER FIELD CAPACITY OF SECOND LAYER (KG/M**2) 5871. |
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C**** 5872. |
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C**** ROUGHL LOG(ZGS/ROUGHNESS LENGTH) (LOGARITHM TO BASE 10) 5873. |
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C**** ROUGHL will be ROUGHNESS LENGTH |
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C**** 5874. |
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c print *,'surface TAU=',TAU |
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NSTEPS=NSURF*NSTEP/NDYN 5875. |
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IF(IFIRST.NE.1) GO TO 50 5876. |
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print *,' SURFACE after CLM' |
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IFIRST=0 5877. |
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print *,'JM=',jm |
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! WMGMIN=8. |
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! WMGMIN=16. ! 2365.05 |
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! WMGMIN=25. ! 2363.05 2366.05 |
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WMGM0=8.0 |
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WMGM45=25. |
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print *,' WMGM0=', WMGM0,' WMGM45=',WMGM45 |
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WMGMAV=0.5*( WMGM0+WMGM45) |
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DWGM=0.5*( WMGM0-WMGM45) |
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do j = 1,jm0 |
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rhrad = 3.14159*(-90.+4.*(j-1))/180. |
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WMGMIN(j) = WMGMAV+DWGM*cos(4.*rhrad) |
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enddo |
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print *,'WMGMIN 4 OCEAN is a function of latitude' |
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print 258,(WMGMIN(J),J=1,JM) |
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print *,' WMGE' |
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print 258,(WMGE(1,J),J=1,JM) |
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258 format(12f5.1) |
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COEFSN=100./ROSNOW(10.) |
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COEFSN=1. |
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print *,' COEFSN=',COEFSN |
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do 2567 J=1,JM |
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NWMGEA(J)=0 |
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WMGEA(J)=0. |
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CHAVER(J)=0. |
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DTAV(J)=0. |
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DQAV(J)=0. |
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Z0AV(J)=0. |
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WSAV(J)=0. |
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WS0AV(J)=0. |
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TAUAV(J)=0. |
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2567 CONTINUE |
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c10 CONTINUE 5878.12 |
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C SRCORX=1. 5878.13 |
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CIAX=0.3 |
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print *,' surfacen CIAX=',CIAX |
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print *,' QS=Q1, TS=T1' |
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print *,' WS=sqrt(0.75*W1+WGEM) ' |
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print *,' ROUGHL' |
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LBLMM1=LBLM-1 5880. |
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IQ1=IM/4+1 5881. |
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IQ2=IM/2+1 5882. |
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IQ3=3*IM/4+1 5883. |
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DTSURF=NDYN*DT/NSURF 5884. |
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jscott |
1.4 |
NCLMPERDAY=(24.*3600.)/DTSURF |
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jscott |
1.1 |
print *,' DTSURF=',DTSURF |
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jscott |
1.4 |
print *,' NCLMPERDAY=',NCLMPERDAY |
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jscott |
1.1 |
DTSRCE=DT*NDYN 5885. |
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SHA=RGAS/KAPA 5886. |
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RVX=0. 5887. |
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ACE1I=Z1I*RHOI 5888. |
| 200 |
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HC1I=ACE1I*SHI 5889. |
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HC2LI=Z2LI*RHOI*SHI 5890. |
| 202 |
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HC1DE=Z1E*1129950. 5891. |
| 203 |
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HC2DE=Z2E*1129950.+3.5*.125*RHOW*3100. 5892. |
| 204 |
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Z1IBYL=Z1I/ALAMI 5893. |
| 205 |
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Z2LI3L=Z2LI/(3.*ALAMI) 5894. |
| 206 |
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BYRSL=1./(RHOS*ALAMS) 5895. |
| 207 |
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ZS1CO=.5*DSIG(1)*RGAS/GRAV 5896. |
| 208 |
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P1000K=EXPBYK(1000.) 5897. |
| 209 |
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COEFS=GRAV/(100.*DSIG(1)) 5898. |
| 210 |
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COEF1=(1.-SIG(2))/DSIGO(1) 5899. |
| 211 |
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COEF2=(SIG(1)-1.)/DSIGO(1) 5900. |
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DO 20 I=1,IM 5901. |
| 213 |
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SINI(I)=SIN((I-1)*TWOPI/FIM) 5902. |
| 214 |
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20 COSI(I)=COS((I-1)*TWOPI/FIM) 5903. |
| 215 |
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50 S0=S0X*1367./RSDIST 5904. |
| 216 |
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c print *,'IM=',IM |
| 217 |
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c do i=1,200 |
| 218 |
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c print *,'HERE1' |
| 219 |
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c enddo |
| 220 |
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BYS0=RSDIST/1367. 5905. |
| 221 |
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C**** ZERO OUT ENERGY AND EVAPORATION FOR GROUND AND INITIALIZE TGRND 5906. |
| 222 |
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DO 70 J=1,JM 5907. |
| 223 |
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DO 70 I=1,IM 5908. |
| 224 |
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TGRND(I,J,2)=GDATA(I,J,3) 5909. |
| 225 |
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c TGRND(I,J,3)=GDATA(I,J,13) 5910. |
| 226 |
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c TGRND(I,J,4)=GDATA(I,J,4) 5911. |
| 227 |
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DO 70 K=1,2 5912. |
| 228 |
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EVAPOR(I,J,K)=0. 5913. |
| 229 |
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E1(I,J,K)=0. 5913. |
| 230 |
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E0(I,J,K)=0. 5913. |
| 231 |
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70 CONTINUE |
| 232 |
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IHOUR=1.5+TOFDAY 5914. |
| 233 |
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C**** 5915. |
| 234 |
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C**** OUTSIDE LOOP OVER TIME STEPS, EXECUTED NSURF TIMES EVERY HOUR 5916. |
| 235 |
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C**** 5917. |
| 236 |
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DO 9000 NS=1,NSURF 5918. |
| 237 |
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MODDSF=MOD(NSTEPS+NS-1,NDASF) 5919. |
| 238 |
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IF(MODDSF.EQ.0) IDACC(3)=IDACC(3)+1 5920. |
| 239 |
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MODD6=MOD(IDAY+NS,NSURF) 5921. |
| 240 |
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C**** ZERO OUT LAYER 1 WIND INCREMENTS 5922. |
| 241 |
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DO 60 J=1,JM 5923. |
| 242 |
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DO 60 I=1,IM 5924. |
| 243 |
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DU1(I,J)=DUL1(J) |
| 244 |
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60 DV1(I,J)=DVL1(J) |
| 245 |
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C**** 5927. |
| 246 |
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C**** OUTSIDE LOOP OVER J AND I, EXECUTED ONCE FOR EACH GRID POINT 5928. |
| 247 |
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C**** 5929. |
| 248 |
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JPR=-7 |
| 249 |
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JPRR=-31 |
| 250 |
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DO 7000 J=1,JM 5930. |
| 251 |
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PRNT=j.eq.8 |
| 252 |
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PRNT=.FALSE. |
| 253 |
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HEMI=1. 5931. |
| 254 |
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IF(J.LE.JM/2) HEMI=-1. 5932. |
| 255 |
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FCOR=2.*OMEGA*SINP(J) 5933. |
| 256 |
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FMAG=FCOR*HEMI 5934. |
| 257 |
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ROOT2F=SQRT(2.*FMAG) 5935. |
| 258 |
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IF(J.EQ.1) GO TO 80 5936. |
| 259 |
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IF(J.EQ.JM) GO TO 90 5937. |
| 260 |
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WMG0=.5*(WMGE(1,J)+WMGE(1,J+1))+.001 5937.5 |
| 261 |
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POLE=.FALSE. 5938. |
| 262 |
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IMAX=IM 5939. |
| 263 |
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GO TO 100 5940. |
| 264 |
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C**** CONDITIONS AT THE SOUTH POLE 5941. |
| 265 |
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80 POLE=.TRUE. 5942. |
| 266 |
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IMAX=1 5943. |
| 267 |
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JVPO=2 5944. |
| 268 |
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RAPO=2.*RAPVN(1) 5945. |
| 269 |
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U1=.25*(U(1,2,1)+V(IQ1,2,1)-U(IQ2,2,1)-V(IQ3,2,1)) 5946. |
| 270 |
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V1=.25*(V(1,2,1)-U(IQ1,2,1)-V(IQ2,2,1)+U(IQ3,2,1)) 5947. |
| 271 |
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WMG0=WMGE(1,2)+.001 5947.5 |
| 272 |
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GO TO 100 5948. |
| 273 |
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C**** CONDITIONS AT THE NORTH POLE 5949. |
| 274 |
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90 POLE=.TRUE. 5950. |
| 275 |
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IMAX=1 5951. |
| 276 |
|
|
JVPO=JM 5952. |
| 277 |
|
|
RAPO=2.*RAPVS(JM) 5953. |
| 278 |
|
|
U1=.25*(U(1,JM,1)-V(IQ1,JM,1)-U(IQ2,JM,1)+V(IQ3,JM,1)) 5954. |
| 279 |
|
|
V1=.25*(V(1,JM,1)+U(IQ1,JM,1)-V(IQ2,JM,1)-U(IQ3,JM,1)) 5955. |
| 280 |
|
|
WMG0=WMGE(1,JM)+.001 5955.5 |
| 281 |
|
|
C**** ZERO OUT SURFACE DIAGNOSTICS WHICH WILL BE SUMMED OVER LONGITUDE 5956. |
| 282 |
|
|
100 ATRHDT=0. 5957. |
| 283 |
|
|
BTRHDT=0. 5958. |
| 284 |
|
|
CTRHDT=0. 5959. |
| 285 |
|
|
ASHDT=0. 5960. |
| 286 |
|
|
CSHDT=0. 5962. |
| 287 |
|
|
AEVHDT=0. 5963. |
| 288 |
|
|
CEVHDT=0. 5965. |
| 289 |
|
|
ATS=0. 5966. |
| 290 |
|
|
CTS=0. 5968. |
| 291 |
|
|
AT2=0. 5966. |
| 292 |
|
|
CT2=0. 5968. |
| 293 |
|
|
ARIGS=0. 5966. |
| 294 |
|
|
CRIGS=0. 5968. |
| 295 |
|
|
ATAUL=0. |
| 296 |
|
|
ATAUF=0. |
| 297 |
|
|
CTAUL=0. |
| 298 |
|
|
CTAUF=0. |
| 299 |
|
|
AWS=0. |
| 300 |
|
|
CWS=0. |
| 301 |
|
|
AWMG=0. |
| 302 |
|
|
CWMG=0. |
| 303 |
|
|
ACH=0. |
| 304 |
|
|
CCH=0. |
| 305 |
|
|
IM1=IM 5969. |
| 306 |
|
|
DO 6000 I=1,IMAX 5970. |
| 307 |
|
|
C**** 5971. |
| 308 |
|
|
C**** DETERMINE SURFACE CONDITIONS 5972. |
| 309 |
|
|
C**** 5973. |
| 310 |
|
|
PLAND=FDATA(I,J,2) 5974. |
| 311 |
|
|
PWATER=1.-PLAND 5975. |
| 312 |
|
|
PLICE=FDATA(I,J,3)*PLAND 5976. |
| 313 |
|
|
PEARTH=PLAND-PLICE 5977. |
| 314 |
|
|
POICE=ODATA(I,J,2)*PWATER 5978. |
| 315 |
|
|
POCEAN=PWATER-POICE 5979. |
| 316 |
|
|
if(POCEAN.LE.1.E-5)then |
| 317 |
|
|
POCEAN=0. |
| 318 |
|
|
POICE=PWATER |
| 319 |
|
|
endif |
| 320 |
|
|
TTOFR=PEARTH+PLICE+POICE+POCEAN |
| 321 |
|
|
if(abs(TTOFR-1).gt.1.e-3)then |
| 322 |
|
|
print *,' From surface TTOFR=',TTOFR |
| 323 |
|
|
print *,' J=',J,' PLAND=',PLAND,' POCEAN=',POCEAN |
| 324 |
|
|
print *,'POICE=',POICE,' ODATA(I,J,2)=',ODATA(I,J,2) |
| 325 |
|
|
stop |
| 326 |
|
|
end if |
| 327 |
|
|
SP=P(I,J) 5980. |
| 328 |
|
|
PS=SP+PTOP 5981. |
| 329 |
|
|
PSK=EXPBYK(PS) 5982. |
| 330 |
|
|
P1=SIG(1)*SP+PTOP 5983. |
| 331 |
|
|
P1K=EXPBYK(P1) 5984. |
| 332 |
|
|
WSOLD=BLDATA(I,J,1) 5985. |
| 333 |
|
|
USOLD=BLDATA(I,J,6) 5986. |
| 334 |
|
|
VSOLD=BLDATA(I,J,7) 5987. |
| 335 |
|
|
TOLD=BLDATA(I,J,8) 5988. |
| 336 |
|
|
SQRTT=SQRT(TOLD) 5989. |
| 337 |
|
|
GKBYFW=.1296*GRAV/(FCOR*FMAG*WSOLD+1.E-20) 5990. |
| 338 |
|
|
COSWS=GKBYFW*USOLD 5991. |
| 339 |
|
|
SINWS=GKBYFW*VSOLD 5992. |
| 340 |
|
|
IF(POLE) GO TO 1200 5993. |
| 341 |
|
|
U1=.25*(U(IM1,J,1)+U(I,J,1)+U(IM1,J+1,1)+U(I,J+1,1)) 5994. |
| 342 |
|
|
V1=.25*(V(IM1,J,1)+V(I,J,1)+V(IM1,J+1,1)+V(I,J+1,1)) 5995. |
| 343 |
|
|
if(J.eq.JPR.or.J.eq.-12)then |
| 344 |
|
|
print *,' J=',J |
| 345 |
|
|
print *,'TAU=',TAU,' NS=',NS,' ITYPE=',ITYPE |
| 346 |
|
|
print *,'U(I,J,1)=',U(I,J,1),' V(I,J,1)=',V(I,J,1) |
| 347 |
|
|
print *,'U(I,J+1,1)=',U(I,J+1,1),' V(I,J+1,1)=',V(I,J+1,1) |
| 348 |
|
|
print *,'U(IM1,J,1)=',U(IM1,J,1),' V(IM1,J,1)=',V(IM1,J,1) |
| 349 |
|
|
print *,'U(IM1,J+1,1)=',U(IM1,J+1,1), |
| 350 |
|
|
& ' V(IM1,J+1,1)=',V(IM1,J+1,1) |
| 351 |
|
|
endif |
| 352 |
|
|
1200 TH1=T(I,J,1) 5996. |
| 353 |
|
|
Q1=Q(I,J,1) 5997. |
| 354 |
|
|
DTH1=DT1L(J) |
| 355 |
|
|
DQQ1=DQ1L(J) |
| 356 |
|
|
THV1=TH1*(1.+Q1*RVX) 5998. |
| 357 |
|
|
c SRHEAT=SRHR(I,J,1)*COSZ1(I,J)*SRCOR 5999. |
| 358 |
|
|
c SRHDT=SRHEAT*DTSURF 6000. |
| 359 |
|
|
RMBYA=100.*SP*DSIG(1)/GRAV 6001. |
| 360 |
|
|
C**** ZERO OUT QUANTITIES TO BE SUMMED OVER SURFACE TYPES 6002. |
| 361 |
|
|
USS=USSL(J) |
| 362 |
|
|
VSS=VSSL(J) |
| 363 |
|
|
WSS=WSSL(J) |
| 364 |
|
|
TSS=TSSL(J) |
| 365 |
|
|
T2MS=T2ML(J) |
| 366 |
|
|
QSS=QSSL(J) |
| 367 |
|
|
TAUS=TAUSL(J) |
| 368 |
|
|
tauu(j)=tauu(j)+TAUYG(J)*PLAND |
| 369 |
|
|
tauv(j)=tauv(j)+TAUXG(J)*PLAND |
| 370 |
|
|
SINAPS=0. 6009. |
| 371 |
|
|
COSAPS=0. 6010. |
| 372 |
|
|
JR=J |
| 373 |
|
|
DXYPJ=DXYP(J) 6012. |
| 374 |
|
|
TG1S=0. 6013. |
| 375 |
|
|
QGS=0. 6014. |
| 376 |
|
|
BETAS=0. 6015. |
| 377 |
|
|
TRHDTS=0. 6016. |
| 378 |
|
|
SHDTS=0. 6017. |
| 379 |
|
|
EVHDTS=0. 6018. |
| 380 |
|
|
UGS=0. 6019. |
| 381 |
|
|
VGS=0. 6020. |
| 382 |
|
|
WGS=0. 6021. |
| 383 |
|
|
USRS=0. 6022. |
| 384 |
|
|
VSRS=0. 6023. |
| 385 |
|
|
RIS1S=0. 6024. |
| 386 |
|
|
RIGSS=0. 6025. |
| 387 |
|
|
CDMS=0. 6026. |
| 388 |
|
|
CDHS=0. 6027. |
| 389 |
|
|
DGSS=0. 6028. |
| 390 |
|
|
EDS1S=0. 6029. |
| 391 |
|
|
PPBLS=0. 6030. |
| 392 |
|
|
EVAPS=0. 6031. |
| 393 |
|
|
C**** 6032. |
| 394 |
|
|
IF(POCEAN.LE.0.) GO TO 2200 6033. |
| 395 |
|
|
C**** 6034. |
| 396 |
|
|
C**** OCEAN 6035. |
| 397 |
|
|
C**** 6036. |
| 398 |
|
|
ITYPE=1 6037. |
| 399 |
|
|
PTYPE=POCEAN 6038. |
| 400 |
|
|
c formula charnoka |
| 401 |
|
|
TOCEAN=BLDATA(I,J,5) |
| 402 |
|
|
! ROUGH=MAX(0.018*TOCEAN/GRAV,1.5E-4) |
| 403 |
|
|
ROUGH=MAX(0.035*TOCEAN/GRAV,1.5E-4) ! 2375.05 |
| 404 |
|
|
ZGS=10. 6041. |
| 405 |
|
|
NGRNDZ=1 6043. |
| 406 |
|
|
TG1=ODATA(I,J,1) 6044. |
| 407 |
|
|
BETA=1. 6045. |
| 408 |
|
|
ELHX=LHE 6046. |
| 409 |
|
|
TRHT0=TRSURF(J,1) |
| 410 |
|
|
SRHEAT=SRSURF(J,1)*COSZ1(I,J)*SRCOR |
| 411 |
|
|
GO TO 3000 6047. |
| 412 |
|
|
C**** 6048. |
| 413 |
|
|
2200 IF(POICE.LE.0.) GO TO 5000 6049. |
| 414 |
|
|
C**** 6050. |
| 415 |
|
|
C**** OCEAN ICE 6051. |
| 416 |
|
|
C**** 6052. |
| 417 |
|
|
ITYPE=2 6053. |
| 418 |
|
|
PTYPE=POICE 6054. |
| 419 |
|
|
NGRNDZ=NGRND 6055. |
| 420 |
|
|
SNOW=GDATA(I,J,1) 6056. |
| 421 |
|
|
TG1=TGRND(I,J,2) 6057. |
| 422 |
|
|
TG2=GDATA(I,J,7) 6058. |
| 423 |
|
|
ACE2=ODATA(I,J,3) 6059. |
| 424 |
|
|
Z2=ACE2/RHOI 6060. |
| 425 |
|
|
Z2BY4L=Z2/(4.*ALAMI) 6061. |
| 426 |
|
|
if (SNOW.gt.10.)then |
| 427 |
|
|
RHOS0=ROSNOW(SNOW) |
| 428 |
|
|
else |
| 429 |
|
|
RHOS0=275. |
| 430 |
|
|
endif |
| 431 |
|
|
RHOS=COEFSN*RHOS0 |
| 432 |
|
|
ALAMS=ALSNOW(RHOS0) |
| 433 |
|
|
BYRSL=1./(RHOS*ALAMS) |
| 434 |
|
|
c Z1BY6L=(Z1IBYL+SNOW*BYRSL)*.1666667 6062. |
| 435 |
|
|
c CDTERM=1.5*TG2-.5*TFO 6063. |
| 436 |
|
|
CDTERM=TG2 |
| 437 |
|
|
c CDENOM=1./(2.*Z1BY6L+Z2BY4L) 6064. |
| 438 |
|
|
Z1BY2L=(Z1IBYL+SNOW*BYRSL)*0.5 |
| 439 |
|
|
CDENOM=1./(Z1BY2L+2.*Z2BY4L) |
| 440 |
|
|
ROUGH=10**(log10(10.)-4.37) |
| 441 |
|
|
ZGS=10. 6067. |
| 442 |
|
|
HC1=HC1I+SNOW*SHI 6069. |
| 443 |
|
|
BETA=1. 6070. |
| 444 |
|
|
ELHX=LHS 6071. |
| 445 |
|
|
TRHT0=TRSURF(J,3) |
| 446 |
|
|
SRHEAT=SRSURF(J,3)*COSZ1(I,J)*SRCOR |
| 447 |
|
|
GO TO 3000 6072. |
| 448 |
|
|
C**** 6073. |
| 449 |
|
|
C |
| 450 |
|
|
C**** BOUNDARY LAYER INTERACTION 6135. |
| 451 |
|
|
C**** 6136. |
| 452 |
|
|
3000 continue |
| 453 |
|
|
|
| 454 |
|
|
SRHDT=SRHEAT*DTSURF |
| 455 |
|
|
TKV=THV1*PSK 6137. |
| 456 |
|
|
ZS1=ZS1CO*TKV*SP/PS 6138. |
| 457 |
|
|
P1=SIG(1)*SP+PTOP 6139. |
| 458 |
|
|
DTGRND=DTSURF/NGRNDZ 6143. |
| 459 |
|
|
SHDT=0. 6144. |
| 460 |
|
|
EVHDT=0. 6145. |
| 461 |
|
|
TRHDT=0. 6146. |
| 462 |
|
|
F1DT=0. 6147. |
| 463 |
|
|
C**** LOOP OVER GROUND TIME STEPS 6148. |
| 464 |
|
|
c DO 3600 NG=1,NGRNDZ 6149. |
| 465 |
|
|
TG=TG1+TF 6150. |
| 466 |
|
|
QG=QSAT(TG,PS,ELHX) 6151. |
| 467 |
|
|
TGV=TG*(1.+QG*RVX) 6152. |
| 468 |
|
|
UG=U1 |
| 469 |
|
|
VG=V1 |
| 470 |
|
|
UG=0.75*U1 ! 2372 |
| 471 |
|
|
VG=0.75*V1 ! 2372 |
| 472 |
|
|
W1=SQRT(U1*U1+V1*V1) |
| 473 |
|
|
W1=SQRT(UG*UG+VG*VG) ! 2372 |
| 474 |
|
|
WS0=W1 |
| 475 |
|
|
WMG=WMG0+WMGMIN(J) |
| 476 |
|
|
WS=SQRT((0.75*W1)**2+WMG) |
| 477 |
|
|
WS=SQRT(W1**2+WMG) ! 2372 |
| 478 |
|
|
if(J.eq.JPR)then |
| 479 |
|
|
print *,' ' |
| 480 |
|
|
print *,'TAU=',TAU,' NS=',NS,' ITYPE=',ITYPE |
| 481 |
|
|
print *,'TG=',TG,' QG=',QG |
| 482 |
|
|
print *,'RVX=',RVX,' TG1=',TG1 |
| 483 |
|
|
endif |
| 484 |
|
|
|
| 485 |
|
|
#if ( defined CPL_OCEANCO2 || defined OCEAN_3D) |
| 486 |
|
|
if(ITYPE.eq.1)then |
| 487 |
|
|
NWMGEA(J)=NWMGEA(J)+1 |
| 488 |
|
|
WSAV(J)=WSAV(J)+WS |
| 489 |
|
|
end if |
| 490 |
|
|
#endif |
| 491 |
|
|
|
| 492 |
|
|
! WG=WS 2369 |
| 493 |
|
|
WG=WS |
| 494 |
|
|
THS=TH1 |
| 495 |
|
|
QS=Q1 |
| 496 |
|
|
TSV=THS*PSK |
| 497 |
|
|
Z0=ROUGH |
| 498 |
|
|
ROUGH=log10(ZGS/ROUGH) |
| 499 |
|
|
CDN=.0231/(ROUGH*ROUGH) |
| 500 |
|
|
LR=ROUGH*2.-.5 |
| 501 |
|
|
IF(LR.GT.20) LR=20 |
| 502 |
|
|
IF(LR.LT.1) LR=1 |
| 503 |
|
|
RIGS=ZGS*GRAV*(TSV-TGV)/(TGV*WS*WS) |
| 504 |
|
|
SINAP=0. |
| 505 |
|
|
COSAP=1. |
| 506 |
|
|
IF(RIGS.LE.0) THEN |
| 507 |
|
|
C surface layer has unstable stratification |
| 508 |
|
|
CIA=TWOPI*0.0625/(1.+WS*CIAX) |
| 509 |
|
|
DM=SQRT((1.-AROUGH(LR)*RIGS)*(1.-BROUGH(LR)*RIGS)/ |
| 510 |
|
|
* (1.-CROUGH(LR)*RIGS)) |
| 511 |
|
|
DH=1.35*SQRT((1.-DROUGH(LR)*RIGS)/(1.-EROUGH(LR)*RIGS)) |
| 512 |
|
|
ELSE |
| 513 |
|
|
C surface layer has stable stratification |
| 514 |
|
|
CIA=TWOPI*(0.09375-0.03125/(1.+4*RIGS**2))/(1.+WS*CIAX) |
| 515 |
|
|
DM=1./(1.+(11.238+89.9*RIGS)*RIGS) |
| 516 |
|
|
DH=1.35/(1.+1.93*RIGS) |
| 517 |
|
|
END IF |
| 518 |
|
|
CDH=CDN*DM*DH |
| 519 |
|
|
USR=COS(CIA) |
| 520 |
|
|
VSR=SIN(CIA)*HEMI |
| 521 |
|
|
US=(USR*UG-VSR*VG) |
| 522 |
|
|
VS=(VSR*UG+USR*VG) |
| 523 |
|
|
if(J.eq.JPRR)then |
| 524 |
|
|
print *,'TAU=',TAU,' NS=',NS,' ITYPE=',ITYPE |
| 525 |
|
|
print *,'WS=',WS,' ZGS=',ZGS |
| 526 |
|
|
print *,'DM=',DM,' DH=',DH |
| 527 |
|
|
print *,'RIGS=',RIGS,' TGV=',TGV |
| 528 |
|
|
endif |
| 529 |
|
|
RCDHWS=CDH*WS*100.*PS/(RGAS*TSV) |
| 530 |
|
|
if(J.eq.JPR)then |
| 531 |
|
|
c print *,' ' |
| 532 |
|
|
print *,'TAU=',TAU,' NS=',NS,' ITYPE=',ITYPE |
| 533 |
|
|
print *,'CDH=',CDH,' RGAS=',RGAS |
| 534 |
|
|
print *,'PS=',PS,' TSV=',TSV |
| 535 |
|
|
print *,'WS=',WS,' RCDHWS=',RCDHWS |
| 536 |
|
|
endif |
| 537 |
|
|
TS=TSV/(1.+QS*RVX) 6467. |
| 538 |
|
|
QSATS=QSAT(TS,PS,ELHX) 6468. |
| 539 |
|
|
c dLQS/dTs |
| 540 |
|
|
DLQSDTS=DLQSDT(TS,ELHX) |
| 541 |
|
|
c dLQS/dTs |
| 542 |
|
|
IF(QS.LE.QSATS) GO TO 3500 6469. |
| 543 |
|
|
DQSSDT=QSATS*ELHX/(RVAP*TS*TS) 6470. |
| 544 |
|
|
X=(QS-QSATS)/(DQSSDT+(SHA/ELHX)) 6471. |
| 545 |
|
|
TS=TS+X 6472. |
| 546 |
|
|
QS=QS+X*(SHA/ELHX) 6473. |
| 547 |
|
|
C**** CALCULATE RHOS*CDM*WS AND RHOS*CDH*WS 6474. |
| 548 |
|
|
3500 CDM=CDN*DM 6475. |
| 549 |
|
|
RCDMWS=CDM*WS*100.*PS/(RGAS*TS) 6476. |
| 550 |
|
|
C**** CALCULATE FLUXES OF SENSIBLE HEAT, LATENT HEAT, THERMAL 6478. |
| 551 |
|
|
C**** RADIATION, AND CONDUCTION HEAT (WATTS/M**2) 6479. |
| 552 |
|
|
SHEAT=SHA*RCDHWS*(TS-TG) 6480. |
| 553 |
|
|
BETAUP=BETA 6481. |
| 554 |
|
|
IF(QS.GT.QG) BETAUP=1. 6482. |
| 555 |
|
|
EVHEAT=(LHE+TG1*SHV)*BETAUP*RCDHWS*(QS-QG) 6483. |
| 556 |
|
|
TRHEAT=TRHT0-STBO*(TG*TG)*(TG*TG) |
| 557 |
|
|
if(J.eq.JPRR)then |
| 558 |
|
|
c print *,' ' |
| 559 |
|
|
! print *,'TAU=',TAU,' NS=',NS,' ITYPE=',ITYPE |
| 560 |
|
|
! print *,'TRHT0=',TRHT0,' STBO=',STBO |
| 561 |
|
|
! print *,'TG=',TG,' TS=',TS |
| 562 |
|
|
! print *,'TRHEAT=',TRHEAT |
| 563 |
|
|
print *,'EVHEAT=',EVHEAT |
| 564 |
|
|
! print *,'SHA=',SHA,' RCDHWS=',RCDHWS |
| 565 |
|
|
print *,'SHEAT=',SHEAT |
| 566 |
|
|
endif |
| 567 |
|
|
TG1OLD=TG1 |
| 568 |
|
|
SHEATOLD=SHEAT |
| 569 |
|
|
#if ( defined OCEAN_3D ) |
| 570 |
|
|
IF(ITYPE.EQ.1 .or. ITYPE.EQ.2) GO TO 3620 |
| 571 |
|
|
#else |
| 572 |
|
|
IF(ITYPE.EQ.1) GO TO 3620 6485. |
| 573 |
|
|
#endif |
| 574 |
|
|
C**** CALCULATE FLUXES USING IMPLICIT TIME STEP FOR NON-OCEAN POINTS 6486. |
| 575 |
|
|
F0=SRHEAT+TRHEAT+SHEAT+EVHEAT 6487. |
| 576 |
|
|
c F1=(TG1-CDTERM-F0*Z1BY6L)*CDENOM 6488. |
| 577 |
|
|
F1=(TG1-CDTERM)*CDENOM |
| 578 |
|
|
DSHDTG=-RCDHWS*SHA |
| 579 |
|
|
DQGDTG=QG*ELHX/(RVAP*TG*TG) 6490. |
| 580 |
|
|
DEVDTG=-RCDHWS*LHE*BETAUP*DQGDTG |
| 581 |
|
|
DTRDTG=-4.*STBO*TG*TG*TG 6492. |
| 582 |
|
|
DF0DTG=DSHDTG+DEVDTG+DTRDTG 6493. |
| 583 |
|
|
c DFDTG=DF0DTG-(1.-DF0DTG*Z1BY6L)*CDENOM 6493.5 |
| 584 |
|
|
DFDTG=DF0DTG-CDENOM |
| 585 |
|
|
c DF1DTG=(1.-DF0DTG*Z1BY6L)*CDENOM |
| 586 |
|
|
DF1DTG=CDENOM |
| 587 |
|
|
DTG=(F0-F1)*DTGRND/(HC1-DTGRND*DFDTG) 6494. |
| 588 |
|
|
SHDT=SHDT+DTGRND*(SHEAT+DTG*DSHDTG) 6495. |
| 589 |
|
|
EVHDT=EVHDT+DTGRND*(EVHEAT+DTG*DEVDTG) 6496. |
| 590 |
|
|
TRHDT=TRHDT+DTGRND*(TRHEAT+DTG*DTRDTG) 6497. |
| 591 |
|
|
TG1=TG1+DTG |
| 592 |
|
|
c F1DT=F1DT+DTGRND*(TG1-CDTERM-(F0+DTG*DF0DTG)*Z1BY6L)*CDENOM 6498. |
| 593 |
|
|
F1DT=F1DT+DTGRND*(TG1-CDTERM)*CDENOM |
| 594 |
|
|
DU1(I,J)=DU1(I,J)+PTYPE*DTGRND*RCDMWS*US*COEFS/SP 6499. |
| 595 |
|
|
DV1(I,J)=DV1(I,J)+PTYPE*DTGRND*RCDMWS*VS*COEFS/SP 6500. |
| 596 |
|
|
c TG1=TG1+DTG 6501. |
| 597 |
|
|
3600 CONTINUE 6502. |
| 598 |
|
|
GO TO 3700 6503. |
| 599 |
|
|
C**** CALCULATE FLUXES USING EXPLICIT TIME STEP FOR OCEAN POINTS 6504. |
| 600 |
|
|
3620 SHDT=DTSURF*SHEAT 6505. |
| 601 |
|
|
EVHDT=DTSURF*EVHEAT 6506. |
| 602 |
|
|
TRHDT=DTSURF*TRHEAT 6507. |
| 603 |
|
|
DU1(I,J)=DU1(I,J)+PTYPE*DTSURF*RCDMWS*US*COEFS/SP 6508. |
| 604 |
|
|
DV1(I,J)=DV1(I,J)+PTYPE*DTSURF*RCDMWS*VS*COEFS/SP 6509. |
| 605 |
|
|
3700 CONTINUE |
| 606 |
|
|
EPS=1.D-8 |
| 607 |
|
|
c print *,'FROM SURFACE NS=',NS |
| 608 |
|
|
c print *,'J=',J,' ITYPE=',ITYPE |
| 609 |
|
|
c print *,RCDMWS,WS |
| 610 |
|
|
WWS=max(W1,1.D-4) |
| 611 |
|
|
ZTEM=ZGS |
| 612 |
|
|
ZTEM=2.0 |
| 613 |
|
|
CALL TZM(T2M,TH2M,ZTEM,Z0,ZGS,SP,TG,TS,RIGS,WS, |
| 614 |
|
|
& -SHEATOLD,RCDMWS*WS,LR,EPS) |
| 615 |
|
|
c print *,'FROM SURFACE' |
| 616 |
|
|
c print *,'J=',J,' ITYPE=',ITYPE |
| 617 |
|
|
c print *,'POCEAN=',POCEAN,' PTYPE=',PTYPE |
| 618 |
|
|
c print *,'TS=',TS,' TG=',TG |
| 619 |
|
|
c print *,' T2M=',T2M,' TH2M=',TH2M |
| 620 |
|
|
F0DT=CORSR*SRHDT+TRHDT+SHDT+EVHDT 6510. |
| 621 |
|
|
if(J.eq.JPR)then |
| 622 |
|
|
print *,'TAU=',TAU,' NS=',NS,' ITYPE=',ITYPE |
| 623 |
|
|
print *,'DTSURF=',DTSURF,' CORSR=',CORSR |
| 624 |
|
|
print *,'SRHDT=',SRHDT,' TRHDT=',TRHDT |
| 625 |
|
|
print *,'SHDT=',SHDT,' EVHDT=',EVHDT |
| 626 |
|
|
print *,'F0DT=',F0DT |
| 627 |
|
|
print *,'US=',US,' VS=',VS |
| 628 |
|
|
print *,'COEFS=',COEFS,' SP=',SP |
| 629 |
|
|
endif |
| 630 |
|
|
c print *,'From surface ',TAU,CORSR,SRHDT,TRHDT,SHDT,EVHDT |
| 631 |
|
|
C**** CALCULATE EVAPORATION 6511. |
| 632 |
|
|
CCC DQ1=EVHDT/((LHE+TG1*SHV)*RMBYA) 6512. |
| 633 |
|
|
DQ1=EVHDT/(ELHX*RMBYA) |
| 634 |
|
|
IF(DQ1*PTYPE.LE.Q1) GO TO 3720 6513. |
| 635 |
|
|
DQ1=Q1/PTYPE 6514. |
| 636 |
|
|
CCC EVHDT=DQ1*(LHE+TG1*SHV)*RMBYA 6515. |
| 637 |
|
|
EVHDT=DQ1*ELHX*RMBYA |
| 638 |
|
|
3720 EVAP=-DQ1*RMBYA 6516. |
| 639 |
|
|
C**** ACCUMULATE SURFACE FLUXES AND PROGNOSTIC AND DIAGNOSTIC QUANTITIES6517. |
| 640 |
|
|
E0(I,J,ITYPE)=E0(I,J,ITYPE)+F0DT 6518. |
| 641 |
|
|
E1(I,J,ITYPE)=E1(I,J,ITYPE)+F1DT 6519. |
| 642 |
|
|
EVAPOR(I,J,ITYPE)=EVAPOR(I,J,ITYPE)+EVAP 6520. |
| 643 |
|
|
if(PRNT)then |
| 644 |
|
|
c write(78,*) ,' ' |
| 645 |
|
|
c write(78,*) ,'TAU=',TAU |
| 646 |
|
|
write(78,*) ,'J=',j,' ITYPE=',ITYPE,' PTYPE=',PTYPE |
| 647 |
|
|
write(78,*) ,'TS=',TS,' TG=',TG,' QS=',QS |
| 648 |
|
|
write(78,*) ,'TG1=',TG1,' TG1OLD=',TG1OLD |
| 649 |
|
|
write(78,*) ,'TG2=',TG2 |
| 650 |
|
|
write(78,*) ,'SHEAT=',SHEAT,' EVHEAT=',EVHEAT |
| 651 |
|
|
write(78,*) ,'TRHEAT=',TRHEAT,' SRHEAT=',SRHEAT |
| 652 |
|
|
write(78,*) ,'EVAP mm/day=',24.*3600.*EVAP/DTSURF |
| 653 |
|
|
write(78,*) ,'EVAP=',EVAP, |
| 654 |
|
|
& ' F0DT=',F0DT/DTSURF,' F1DT=',F1DT/DTSURF |
| 655 |
|
|
endif |
| 656 |
|
|
#if ( defined OCEAN_3D || defined ML_2D ) |
| 657 |
|
|
C For ocean model |
| 658 |
|
|
#if ( defined ML_2D ) |
| 659 |
|
|
if(ITYPE.eq.1)then |
| 660 |
|
|
#endif |
| 661 |
|
|
C DNetHeat by DTG |
| 662 |
|
|
DSHDTG=-RCDHWS*SHA |
| 663 |
|
|
DQGDTG=QG*ELHX/(RVAP*TG*TG) |
| 664 |
|
|
DEVDTG=-RCDHWS*LHE*BETAUP*DQGDTG |
| 665 |
|
|
DTRDTG=-4.*STBO*TG*TG*TG |
| 666 |
|
|
DF0DTG=DSHDTG+DEVDTG+DTRDTG |
| 667 |
|
|
if(EVHEAT.lt.0.0)then |
| 668 |
|
|
DEVDTGEQ=EVHEAT*DLQSDTS |
| 669 |
|
|
else |
| 670 |
|
|
DEVDTGEQ=0.0 |
| 671 |
|
|
endif |
| 672 |
|
|
C DNetHeat by DTG |
| 673 |
|
|
#if ( defined OCEAN_3D ) |
| 674 |
|
|
if(ITYPE.eq.1)then |
| 675 |
|
|
#endif |
| 676 |
|
|
dhfodtg(j)=dhfodtg(j)+DF0DTG |
| 677 |
|
|
devodtg(j)=devodtg(j)-DEVDTG/LHE |
| 678 |
|
|
dhfodtgeq(j)=dhfodtgeq(j)+DEVDTGEQ |
| 679 |
|
|
devodtgeq(j)=devodtgeq(j)-DEVDTGEQ/LHE |
| 680 |
|
|
evao(j)=evao(j)+EVAP |
| 681 |
|
|
hfluxo(j)=hfluxo(j)+F0DT |
| 682 |
|
|
naveo(j)=naveo(j)+1 |
| 683 |
|
|
endif |
| 684 |
|
|
if(ITYPE.eq.2)then |
| 685 |
|
|
evai(j)=evai(j)+EVAP |
| 686 |
|
|
hfluxi(j)=hfluxi(j)+F0DT |
| 687 |
|
|
dhfidtg(j)=dhfidtg(j)+DF0DTG |
| 688 |
|
|
devidtg(j)=devidtg(j)-DEVDTG/LHE |
| 689 |
|
|
dhfidtgeq(j)=dhfidtgeq(j)+DEVDTGEQ |
| 690 |
|
|
devidtgeq(j)=devidtgeq(j)-DEVDTGEQ/LHE |
| 691 |
|
|
c tairi(j)=tairi(j)+TS |
| 692 |
|
|
navei(j)=navei(j)+1 |
| 693 |
|
|
endif |
| 694 |
|
|
tauu(j)=tauu(j)+RCDMWS*US*PTYPE |
| 695 |
|
|
tauv(j)=tauv(j)+RCDMWS*VS*PTYPE |
| 696 |
|
|
C For ocean model |
| 697 |
|
|
#endif |
| 698 |
|
|
TGRND(I,J,ITYPE)=TG1 6521. |
| 699 |
|
|
TSSFC(I,J,ITYPE)=TS 6521.5 |
| 700 |
|
|
c TH1=TH1-SHDT*PTYPE/(SHA*RMBYA*P1K) 6522. |
| 701 |
|
|
c Q1=Q1-DQ1*PTYPE 6523. |
| 702 |
|
|
|
| 703 |
|
|
DTH1=DTH1-SHDT*PTYPE/(SHA*RMBYA*P1K) |
| 704 |
|
|
DQQ1=DQQ1-DQ1*PTYPE |
| 705 |
|
|
|
| 706 |
|
|
USS=USS+US*PTYPE 6524. |
| 707 |
|
|
VSS=VSS+VS*PTYPE 6525. |
| 708 |
|
|
WSS=WSS+WS*PTYPE 6526. |
| 709 |
|
|
TSS=TSS+TS*PTYPE 6527. |
| 710 |
|
|
T2MS=T2MS+T2M*PTYPE |
| 711 |
|
|
QSS=QSS+QS*PTYPE 6528. |
| 712 |
|
|
! TAUS=TAUS+CDM*WS*W1*PTYPE 6529. |
| 713 |
|
|
TAUS=TAUS+CDM*WS*WS*PTYPE ! 2373 |
| 714 |
|
|
SINAPS=SINAPS+SINAP*PTYPE 6530. |
| 715 |
|
|
COSAPS=COSAPS+COSAP*PTYPE 6531. |
| 716 |
|
|
TG1S=TG1S+TG1*PTYPE 6532. |
| 717 |
|
|
QGS=QGS+QG*PTYPE 6533. |
| 718 |
|
|
BETAS=BETAS+BETA*PTYPE 6534. |
| 719 |
|
|
TRHDTS=TRHDTS+TRHDT*PTYPE 6535. |
| 720 |
|
|
SHDTS=SHDTS+SHDT*PTYPE 6536. |
| 721 |
|
|
EVHDTS=EVHDTS+EVHDT*PTYPE 6537. |
| 722 |
|
|
UGS=UGS+UG*PTYPE 6538. |
| 723 |
|
|
VGS=VGS+VG*PTYPE 6539. |
| 724 |
|
|
WGS=WGS+WG*PTYPE 6540. |
| 725 |
|
|
USRS=USRS+USR*PTYPE 6541. |
| 726 |
|
|
VSRS=VSRS+VSR*PTYPE 6542. |
| 727 |
|
|
c RIS1S=RIS1S+RIS1*PTYPE 6543. |
| 728 |
|
|
RIGSS=RIGSS+RIGS*PTYPE 6544. |
| 729 |
|
|
CDMS=CDMS+CDM*PTYPE 6545. |
| 730 |
|
|
CDHS=CDHS+CDH*PTYPE 6546. |
| 731 |
|
|
c DGSS=DGSS+DGS*PTYPE 6547. |
| 732 |
|
|
c EDS1S=EDS1S+EDS1*PTYPE 6548. |
| 733 |
|
|
c PPBLS=PPBLS+PPBL*PTYPE 6549. |
| 734 |
|
|
EVAPS=EVAPS+EVAP*PTYPE 6550. |
| 735 |
|
|
GO TO (4000,4100,5000,5000),ITYPE 6551. |
| 736 |
|
|
C**** 6552. |
| 737 |
|
|
C**** OCEAN 6553. |
| 738 |
|
|
C**** 6554. |
| 739 |
|
|
4000 ASHDT=ASHDT+SHDT*POCEAN 6555. |
| 740 |
|
|
AEVHDT=AEVHDT+EVHDT*POCEAN 6556. |
| 741 |
|
|
ATRHDT=ATRHDT+TRHDT*POCEAN 6557. |
| 742 |
|
|
ATS=ATS+(TS-TF)*POCEAN 6558. |
| 743 |
|
|
c AT2=AT2+(TH2M-TF)*POCEAN |
| 744 |
|
|
AT2=AT2+(T2M-TF)*POCEAN |
| 745 |
|
|
ARIGS=ARIGS+RIGS*POCEAN |
| 746 |
|
|
BLDATA(I,J,5)=CDM*WS*W1 |
| 747 |
|
|
BLDATA(I,J,5)=CDM*WS*WS ! 2373 |
| 748 |
|
|
ATAUL=ATAUL+RCDMWS*US*POCEAN |
| 749 |
|
|
ATAUF=ATAUF+RCDMWS*VS*POCEAN |
| 750 |
|
|
AWS=AWS+WS*POCEAN |
| 751 |
|
|
AWMG=AWMG+SQRT(WMG)*POCEAN |
| 752 |
|
|
ACH=ACH+RCDHWS*POCEAN |
| 753 |
|
|
GO TO 2200 6559. |
| 754 |
|
|
C**** 6560. |
| 755 |
|
|
C**** OCEAN ICE 6561. |
| 756 |
|
|
C**** 6562. |
| 757 |
|
|
4100 CSHDT=CSHDT+SHDT*POICE 6563. |
| 758 |
|
|
CEVHDT=CEVHDT+EVHDT*POICE 6564. |
| 759 |
|
|
CTRHDT=CTRHDT+TRHDT*POICE 6565. |
| 760 |
|
|
CTS=CTS+(TS-TF)*POICE 6566. |
| 761 |
|
|
c CT2=CT2+(TH2M-TF)*POICE 6566. |
| 762 |
|
|
CT2=CT2+(T2M-TF)*POICE |
| 763 |
|
|
CRIGS=CRIGS+RIGS*POICE |
| 764 |
|
|
CTAUL=CTAUL+RCDMWS*US*POICE |
| 765 |
|
|
CTAUF=CTAUF+RCDMWS*VS*POICE |
| 766 |
|
|
CWS=CWS+WS*POICE |
| 767 |
|
|
CWMG=CWMG+SQRT(WMG)*POICE |
| 768 |
|
|
CCH=CCH+RCDHWS*POICE |
| 769 |
|
|
GO TO 5000 6567. |
| 770 |
|
|
C**** 6568. |
| 771 |
|
|
C**** NON-OCEAN POINTS WHICH ARE NOT MELTING OR FREEZING WATER USE 6583. |
| 772 |
|
|
C**** IMPLICIT TIME STEPS 6584. |
| 773 |
|
|
C**** 6585. |
| 774 |
|
|
C**** UPDATE SURFACE AND FIRST LAYER QUANTITIES 6586. |
| 775 |
|
|
C**** 6587. |
| 776 |
|
|
5000 CONTINUE |
| 777 |
|
|
c print *,j,TH1,Q1 |
| 778 |
|
|
c print *,j,DU1(1,j),DV1(1,j) |
| 779 |
|
|
T(I,J,1)=TH1 6588. |
| 780 |
|
|
& +DTH1 |
| 781 |
|
|
Q(I,J,1)=Q1 6589. |
| 782 |
|
|
& +DQQ1 |
| 783 |
|
|
BLDATA(I,J,1)=WSS 6590. |
| 784 |
|
|
BLDATA(I,J,2)=TSS 6591. |
| 785 |
|
|
BLDATA(I,J,3)=QSS 6592. |
| 786 |
|
|
BLDATA(I,J,6)=USS 6593. |
| 787 |
|
|
BLDATA(I,J,7)=VSS 6594. |
| 788 |
|
|
BLDATA(I,J,8)=TAUS 6595. |
| 789 |
jscott |
1.3 |
T2MZ(J)=T2MS |
| 790 |
jscott |
1.1 |
c print *,j,T(I,J,1),Q(I,J,1) |
| 791 |
|
|
c print *,(TGRND(I,J,k),k=1,4) |
| 792 |
|
|
c print *,(EVAPOR(I,J,k),k=1,4) |
| 793 |
|
|
c print *,(E0(I,J,k),k=1,4) |
| 794 |
|
|
c print *,(E1(I,J,k),k=1,4) |
| 795 |
|
|
c print *,j,DU1(1,j),DV1(1,j) |
| 796 |
|
|
C**** 6596. |
| 797 |
|
|
C**** ACCUMULATE DIAGNOSTICS 6597. |
| 798 |
|
|
C**** 6598. |
| 799 |
|
|
C**** QUANTITIES ACCUMULATED FOR REGIONS IN DIAG1 6599. |
| 800 |
|
|
IF(JR.EQ.JM) GO TO 5700 6600. |
| 801 |
|
|
DJ(JR,9)=DJ(JR,9)+TRHDTS*DXYPJ 6601. |
| 802 |
|
|
DJ(JR,13)=DJ(JR,13)+SHDTS*DXYPJ 6602. |
| 803 |
|
|
DJ(JR,14)=DJ(JR,14)+EVHDTS*DXYPJ 6603. |
| 804 |
|
|
DJ(JR,19)=DJ(JR,19)+EVAPS*DXYPJ 6604. |
| 805 |
|
|
IF(MODDSF.NE.0) GO TO 5700 6605. |
| 806 |
|
|
DJ(JR,23)=DJ(JR,23)+(TSS-TF)*DXYPJ 6606. |
| 807 |
|
|
5700 CONTINUE |
| 808 |
|
|
6000 IM1=I 6662. |
| 809 |
|
|
C**** QUANTITIES ACCUMULATED FOR SURFACE TYPE TABLES IN DIAG1 6663. |
| 810 |
|
|
AJ(J,9)=AJ(J,9)+ATRHDT 6664. |
| 811 |
|
|
BJ(J,9)=BJ(J,9)+BLJ(J,9) |
| 812 |
|
|
CJ(J,9)=CJ(J,9)+CTRHDT 6666. |
| 813 |
|
|
AJ(J,13)=AJ(J,13)+ASHDT 6667. |
| 814 |
|
|
BJ(J,13)=BJ(J,13)+BLJ(J,13) |
| 815 |
|
|
CJ(J,13)=CJ(J,13)+CSHDT 6669. |
| 816 |
|
|
AJ(J,14)=AJ(J,14)+AEVHDT 6670. |
| 817 |
|
|
BJ(J,14)=BJ(J,14)+BLJ(J,14) |
| 818 |
|
|
if(J.eq.-23)then |
| 819 |
|
|
print *,'TAU=',TAU,' BJ(J,14)=',BJ(J,14) |
| 820 |
|
|
endif |
| 821 |
|
|
CJ(J,14)=CJ(J,14)+CEVHDT 6672. |
| 822 |
|
|
AJ(J,32)=AJ(J,32)+ATAUL |
| 823 |
|
|
BJ(J,32)=BJ(J,32)+BLJ(J,32) |
| 824 |
|
|
CJ(J,32)=CJ(J,32)+CTAUL |
| 825 |
|
|
AJ(J,33)=AJ(J,33)+ATAUF |
| 826 |
|
|
BJ(J,33)=BJ(J,33)+BLJ(J,33) |
| 827 |
|
|
CJ(J,33)=CJ(J,33)+CTAUF |
| 828 |
|
|
AJ(J,37)=AJ(J,37)+AWS |
| 829 |
|
|
BJ(J,37)=BJ(J,37)+BLJ(J,37) |
| 830 |
|
|
CJ(J,37)=CJ(J,37)+CWS |
| 831 |
|
|
AJ(J,28)=AJ(J,28)+AWMG |
| 832 |
|
|
BJ(J,28)=BJ(J,28)+BLJ(J,28) |
| 833 |
|
|
CJ(J,28)=CJ(J,28)+CWMG |
| 834 |
|
|
AJ(J,38)=AJ(J,38)+ATAUL |
| 835 |
|
|
BJ(J,38)=BJ(J,38)+BLJ(J,38) |
| 836 |
|
|
CJ(J,38)=CJ(J,38)+CTAUL |
| 837 |
|
|
IF(MODDSF.NE.0) GO TO 7000 6673. |
| 838 |
|
|
AJ(J,23)=AJ(J,23)+ATS 6674. |
| 839 |
|
|
BJ(J,23)=BJ(J,23)+BLJ(J,23) |
| 840 |
|
|
CJ(J,23)=CJ(J,23)+CTS 6676. |
| 841 |
|
|
AJ(J,26)=AJ(J,26)+AT2 6674. |
| 842 |
|
|
BJ(J,26)=BJ(J,26)+BLJ(J,26) |
| 843 |
|
|
CJ(J,26)=CJ(J,26)+CT2 6676. |
| 844 |
|
|
AJ(J,27)=AJ(J,27)+ARIGS 6674. |
| 845 |
|
|
CJ(J,27)=CJ(J,27)+CRIGS 6676. |
| 846 |
|
|
|
| 847 |
|
|
c print *,j,'CTS=',CTS,' CT2=',CT2 |
| 848 |
|
|
c print *,'BLDATA' |
| 849 |
|
|
c print *,(BLDATA(1,j,k),k=1,3) |
| 850 |
|
|
c print *,(BLDATA(1,j,k),k=6,8) |
| 851 |
|
|
7000 CONTINUE 6677. |
| 852 |
|
|
C**** 6678. |
| 853 |
|
|
C**** ADD IN SURFACE FRICTION TO FIRST LAYER WIND 6679. |
| 854 |
|
|
C**** 6680. |
| 855 |
|
|
DO 7600 I=1,IM 6681. |
| 856 |
|
|
U(I,2,1)=U(I,2,1)-2.*(DU1(1,1)*COSI(I)-DV1(1,1)*SINI(I))*RAPVN(1) 6682. |
| 857 |
|
|
V(I,2,1)=V(I,2,1)-2.*(DV1(1,1)*COSI(I)+DU1(1,1)*SINI(I))*RAPVN(1) 6683. |
| 858 |
|
|
U(I,JM,1)=U(I,JM,1) 6684. |
| 859 |
|
|
* -2.*(DU1(1,JM)*COSI(I)+DV1(1,JM)*SINI(I))*RAPVS(JM) 6685. |
| 860 |
|
|
7600 V(I,JM,1)=V(I,JM,1) 6686. |
| 861 |
|
|
* -2.*(DV1(1,JM)*COSI(I)-DU1(1,JM)*SINI(I))*RAPVS(JM) 6687. |
| 862 |
|
|
DO 7700 J=2,JMM1 6688. |
| 863 |
|
|
I=IM 6689. |
| 864 |
|
|
DO 7700 IP1=1,IM 6690. |
| 865 |
|
|
if(J.eq.JPR.or.J.eq.-12)then |
| 866 |
|
|
print *,' J=',J,' before' |
| 867 |
|
|
print *,'U(I,J,1)=',U(I,J,1),' V(I,J,1)=',V(I,J,1) |
| 868 |
|
|
print *,'U(I,J+1,1)=',U(I,J+1,1),' V(I,J+1,1)=',V(I,J+1,1) |
| 869 |
|
|
print *,'DU1(I,J)=',DU1(I,J),' DU1(IP1,J)=',DU1(IP1,J) |
| 870 |
|
|
endif |
| 871 |
|
|
U(I,J,1)=U(I,J,1)-(DU1(I,J)+DU1(IP1,J))*RAPVS(J) 6691. |
| 872 |
|
|
V(I,J,1)=V(I,J,1)-(DV1(I,J)+DV1(IP1,J))*RAPVS(J) 6692. |
| 873 |
|
|
U(I,J+1,1)=U(I,J+1,1)-(DU1(I,J)+DU1(IP1,J))*RAPVN(J) 6693. |
| 874 |
|
|
V(I,J+1,1)=V(I,J+1,1)-(DV1(I,J)+DV1(IP1,J))*RAPVN(J) 6694. |
| 875 |
|
|
if(J.eq.JPR.or.J.eq.-12)then |
| 876 |
|
|
print *,' J=',J,' after' |
| 877 |
|
|
print *,'U(I,J,1)=',U(I,J,1),' V(I,J,1)=',V(I,J,1) |
| 878 |
|
|
print *,'U(I,J+1,1)=',U(I,J+1,1),' V(I,J+1,1)=',V(I,J+1,1) |
| 879 |
|
|
print *,'DU1(I,J)=',DU1(I,J),' DU1(IP1,J)=',DU1(IP1,J) |
| 880 |
|
|
endif |
| 881 |
|
|
7700 I=IP1 6695. |
| 882 |
|
|
c print *,'U V' |
| 883 |
|
|
c do j=1,jm |
| 884 |
|
|
c print *,j,U(I,J,1),v(I,J,1) |
| 885 |
|
|
c enddo |
| 886 |
|
|
C**** 6696. |
| 887 |
|
|
C**** DRY CONVECTION ORIGINATING FROM THE FIRST LAYER 6697. |
| 888 |
|
|
C**** 6698. |
| 889 |
|
|
C**** LOAD U,V INTO UT,VT. UT,VT WILL BE FIXED DURING DRY CONVECTION 6699. |
| 890 |
|
|
C**** WHILE U,V WILL BE UPDATED. 6700. |
| 891 |
|
|
DO 8050 L=1,LM 6701. |
| 892 |
|
|
DO 8050 J=2,JM 6702. |
| 893 |
|
|
DO 8050 I=1,IM 6703. |
| 894 |
|
|
UT(I,J,L)=U(I,J,L) 6704. |
| 895 |
|
|
8050 VT(I,J,L)=V(I,J,L) 6705. |
| 896 |
|
|
C**** OUTSIDE LOOPS OVER J AND I 6706. |
| 897 |
|
|
DO 8500 J=1,JM 6707. |
| 898 |
|
|
POLE=.FALSE. 6708. |
| 899 |
|
|
IF(J.EQ.1.OR.J.EQ.JM) POLE=.TRUE. 6709. |
| 900 |
|
|
IMAX=IM 6710. |
| 901 |
|
|
IF(POLE) IMAX=IM 6711. |
| 902 |
|
|
DO 8120 K=1,2 6712. |
| 903 |
|
|
RA(K)=RAPVS(J) 6713. |
| 904 |
|
|
8120 RA(K+2)=RAPVN(J) 6714. |
| 905 |
|
|
IM1=IM 6715. |
| 906 |
|
|
DO 8500 I=1,IMAX 6716. |
| 907 |
|
|
BLDATA(I,J,4)=1. 6717. |
| 908 |
|
|
IF(T(I,J,1)*(1.+Q(I,J,1)*RVX).LE. 6718. |
| 909 |
|
|
* T(I,J,2)*(1.+Q(I,J,2)*RVX)) GO TO 8500 6719. |
| 910 |
|
|
C**** MIX HEAT AND MOISTURE THROUGHOUT THE BOUNDARY LAYER 6720. |
| 911 |
|
|
PKMS=PK(I,J,1)*DSIG(1)+PK(I,J,2)*DSIG(2) 6721. |
| 912 |
|
|
THPKMS=T(I,J,1)*(PK(I,J,1)*DSIG(1))+T(I,J,2)*(PK(I,J,2)*DSIG(2)) 6722. |
| 913 |
|
|
QMS=Q(I,J,1)*DSIG(1)+Q(I,J,2)*DSIG(2) 6723. |
| 914 |
|
|
TVMS=T(I,J,1)*(1.+Q(I,J,1)*RVX)*(PK(I,J,1)*DSIG(1)) 6724. |
| 915 |
|
|
* +T(I,J,2)*(1.+Q(I,J,2)*RVX)*(PK(I,J,2)*DSIG(2)) 6725. |
| 916 |
|
|
THETA=TVMS/PKMS 6726. |
| 917 |
|
|
|
| 918 |
|
|
#if ( defined CPL_CHEM ) |
| 919 |
|
|
! |
| 920 |
|
|
! --- 03/23/95 |
| 921 |
|
|
! |
| 922 |
|
|
cfc11ms = cfc11(i,j,1)*dsig(1) + cfc11(i,j,2)*dsig(2) |
| 923 |
|
|
|
| 924 |
|
|
cfc12ms = cfc12(i,j,1)*dsig(1) + cfc12(i,j,2)*dsig(2) |
| 925 |
|
|
|
| 926 |
|
|
xn2oms = xn2o (i,j,1)*dsig(1) + xn2o (i,j,2)*dsig(2) |
| 927 |
|
|
|
| 928 |
|
|
o3ms = o3 (i,j,1)*dsig(1) + o3 (i,j,2)*dsig(2) |
| 929 |
|
|
|
| 930 |
|
|
coms = co (i,j,1)*dsig(1) + co (i,j,2)*dsig(2) |
| 931 |
|
|
|
| 932 |
|
|
zco2ms = zco2 (i,j,1)*dsig(1) + zco2 (i,j,2)*dsig(2) |
| 933 |
|
|
|
| 934 |
|
|
xnoms = xno (i,j,1)*dsig(1) + xno (i,j,2)*dsig(2) |
| 935 |
|
|
|
| 936 |
|
|
xno2ms = xno2 (i,j,1)*dsig(1) + xno2 (i,j,2)*dsig(2) |
| 937 |
|
|
|
| 938 |
|
|
xn2o5ms = xn2o5(i,j,1)*dsig(1) + xn2o5(i,j,2)*dsig(2) |
| 939 |
|
|
|
| 940 |
|
|
hno3ms = hno3 (i,j,1)*dsig(1) + hno3 (i,j,2)*dsig(2) |
| 941 |
|
|
|
| 942 |
|
|
ch4ms = ch4 (i,j,1)*dsig(1) + ch4 (i,j,2)*dsig(2) |
| 943 |
|
|
|
| 944 |
|
|
ch2oms = ch2o (i,j,1)*dsig(1) + ch2o (i,j,2)*dsig(2) |
| 945 |
|
|
|
| 946 |
|
|
so2ms = so2 (i,j,1)*dsig(1) + so2 (i,j,2)*dsig(2) |
| 947 |
|
|
|
| 948 |
|
|
h2so4ms = h2so4(i,j,1)*dsig(1) + h2so4(i,j,2)*dsig(2) |
| 949 |
|
|
|
| 950 |
|
|
! === if hfc, pfc, and sf6 are included: |
| 951 |
|
|
#ifdef INC_3GASES |
| 952 |
|
|
! === 032698 |
| 953 |
|
|
hfc134ams = hfc134a(i,j,1)*dsig(1) |
| 954 |
|
|
& + hfc134a(i,j,2)*dsig(2) |
| 955 |
|
|
|
| 956 |
|
|
pfcms = pfc(i,j,1)*dsig(1) |
| 957 |
|
|
& + pfc(i,j,2)*dsig(2) |
| 958 |
|
|
|
| 959 |
|
|
sf6ms = sf6(i,j,1)*dsig(1) |
| 960 |
|
|
& + sf6(i,j,2)*dsig(2) |
| 961 |
|
|
! === |
| 962 |
|
|
#endif |
| 963 |
|
|
|
| 964 |
|
|
bcms = bcarbon (i,j,1)*dsig(1) + bcarbon (i,j,2)*dsig(2) |
| 965 |
|
|
ocms = ocarbon (i,j,1)*dsig(1) + ocarbon (i,j,2)*dsig(2) |
| 966 |
|
|
|
| 967 |
|
|
c 062295 |
| 968 |
|
|
c h2o2ms = h2o2 (i,j,1)*dsig(1) + h2o2 (i,j,2)*dsig(2) |
| 969 |
|
|
|
| 970 |
|
|
! |
| 971 |
|
|
#endif |
| 972 |
|
|
|
| 973 |
|
|
DO 8140 L=3,LM 6727. |
| 974 |
|
|
IF(THETA.LT.T(I,J,L)*(1.+Q(I,J,L)*RVX)) GO TO 8160 6728. |
| 975 |
|
|
PKMS=PKMS+(PK(I,J,L)*DSIG(L)) 6729. |
| 976 |
|
|
THPKMS=THPKMS+T(I,J,L)*(PK(I,J,L)*DSIG(L)) 6730. |
| 977 |
|
|
QMS=QMS+Q(I,J,L)*DSIG(L) 6731. |
| 978 |
|
|
TVMS=TVMS+T(I,J,L)*(1.+Q(I,J,L)*RVX)*(PK(I,J,L)*DSIG(L)) 6732. |
| 979 |
|
|
|
| 980 |
|
|
#if ( defined CPL_CHEM ) |
| 981 |
|
|
! |
| 982 |
|
|
! --- 03/23/95 |
| 983 |
|
|
! |
| 984 |
|
|
cfc11ms = cfc11ms + cfc11(i,j,l)*dsig(l) |
| 985 |
|
|
|
| 986 |
|
|
cfc12ms = cfc12ms + cfc12(i,j,l)*dsig(l) |
| 987 |
|
|
|
| 988 |
|
|
xn2oms = xn2oms + xn2o (i,j,l)*dsig(l) |
| 989 |
|
|
|
| 990 |
|
|
o3ms = o3ms + o3 (i,j,l)*dsig(l) |
| 991 |
|
|
|
| 992 |
|
|
coms = coms + co (i,j,l)*dsig(l) |
| 993 |
|
|
|
| 994 |
|
|
zco2ms = zco2ms + zco2 (i,j,l)*dsig(l) |
| 995 |
|
|
|
| 996 |
|
|
xnoms = xnoms + xno (i,j,l)*dsig(l) |
| 997 |
|
|
|
| 998 |
|
|
xno2ms = xno2ms + xno2 (i,j,l)*dsig(l) |
| 999 |
|
|
|
| 1000 |
|
|
xn2o5ms = xn2o5ms + xn2o5(i,j,l)*dsig(l) |
| 1001 |
|
|
|
| 1002 |
|
|
hno3ms = hno3ms + hno3 (i,j,l)*dsig(l) |
| 1003 |
|
|
|
| 1004 |
|
|
ch4ms = ch4ms + ch4 (i,j,l)*dsig(l) |
| 1005 |
|
|
|
| 1006 |
|
|
ch2oms = ch2oms + ch2o (i,j,l)*dsig(l) |
| 1007 |
|
|
|
| 1008 |
|
|
so2ms = so2ms + so2 (i,j,l)*dsig(l) |
| 1009 |
|
|
|
| 1010 |
|
|
h2so4ms = h2so4ms + h2so4(i,j,l)*dsig(l) |
| 1011 |
|
|
|
| 1012 |
|
|
! === if hfc, pfc, and sf6 are included: |
| 1013 |
|
|
#ifdef INC_3GASES |
| 1014 |
|
|
! === 032698 |
| 1015 |
|
|
hfc134ams = hfc134ams |
| 1016 |
|
|
& + hfc134a(i,j,l)*dsig(l) |
| 1017 |
|
|
|
| 1018 |
|
|
pfcms = pfcms |
| 1019 |
|
|
& + pfc(i,j,l)*dsig(l) |
| 1020 |
|
|
|
| 1021 |
|
|
sf6ms = sf6ms |
| 1022 |
|
|
& + sf6(i,j,l)*dsig(l) |
| 1023 |
|
|
! === |
| 1024 |
|
|
#endif |
| 1025 |
|
|
|
| 1026 |
|
|
bcms = bcms + bcarbon (i,j,l)*dsig(l) |
| 1027 |
|
|
ocms = ocms + ocarbon (i,j,l)*dsig(l) |
| 1028 |
|
|
|
| 1029 |
|
|
c 062295 |
| 1030 |
|
|
c h2o2ms = h2o2ms + h2o2 (i,j,l)*dsig(l) |
| 1031 |
|
|
! |
| 1032 |
|
|
#endif |
| 1033 |
|
|
|
| 1034 |
|
|
8140 THETA=TVMS/PKMS 6733. |
| 1035 |
|
|
L=LM+1 6734. |
| 1036 |
|
|
8160 LMAX=L-1 6735. |
| 1037 |
|
|
RDSIGS=1./(SIGE(1)-SIGE(LMAX+1)) 6736. |
| 1038 |
|
|
THM=THPKMS/PKMS 6737. |
| 1039 |
|
|
QMS=QMS*RDSIGS 6738. |
| 1040 |
|
|
|
| 1041 |
|
|
#if ( defined CPL_CHEM ) |
| 1042 |
|
|
! |
| 1043 |
|
|
! --- 03/23/95 |
| 1044 |
|
|
! |
| 1045 |
|
|
cfc11ms = cfc11ms*rdsigs |
| 1046 |
|
|
|
| 1047 |
|
|
cfc12ms = cfc12ms*rdsigs |
| 1048 |
|
|
|
| 1049 |
|
|
xn2oms = xn2oms *rdsigs |
| 1050 |
|
|
|
| 1051 |
|
|
o3ms = o3ms *rdsigs |
| 1052 |
|
|
|
| 1053 |
|
|
coms = coms *rdsigs |
| 1054 |
|
|
|
| 1055 |
|
|
zco2ms = zco2ms *rdsigs |
| 1056 |
|
|
|
| 1057 |
|
|
xnoms = xnoms *rdsigs |
| 1058 |
|
|
|
| 1059 |
|
|
xno2ms = xno2ms *rdsigs |
| 1060 |
|
|
|
| 1061 |
|
|
xn2o5ms = xn2o5ms*rdsigs |
| 1062 |
|
|
|
| 1063 |
|
|
hno3ms = hno3ms *rdsigs |
| 1064 |
|
|
|
| 1065 |
|
|
ch4ms = ch4ms *rdsigs |
| 1066 |
|
|
|
| 1067 |
|
|
ch2oms = ch2oms *rdsigs |
| 1068 |
|
|
|
| 1069 |
|
|
so2ms = so2ms *rdsigs |
| 1070 |
|
|
|
| 1071 |
|
|
h2so4ms = h2so4ms*rdsigs |
| 1072 |
|
|
|
| 1073 |
|
|
! === if hfc, pfc, and sf6 are included: |
| 1074 |
|
|
#ifdef INC_3GASES |
| 1075 |
|
|
! === 032698 |
| 1076 |
|
|
hfc134ams = hfc134ams*rdsigs |
| 1077 |
|
|
|
| 1078 |
|
|
pfcms = pfcms*rdsigs |
| 1079 |
|
|
|
| 1080 |
|
|
sf6ms = sf6ms*rdsigs |
| 1081 |
|
|
! === |
| 1082 |
|
|
#endif |
| 1083 |
|
|
|
| 1084 |
|
|
bcms = bcms*rdsigs |
| 1085 |
|
|
ocms = ocms*rdsigs |
| 1086 |
|
|
|
| 1087 |
|
|
c 062295 |
| 1088 |
|
|
c h2o2ms = h2o2ms*rdsigs |
| 1089 |
|
|
c |
| 1090 |
|
|
! |
| 1091 |
|
|
#endif |
| 1092 |
|
|
|
| 1093 |
|
|
BLDATA(I,J,4)=LMAX 6739. |
| 1094 |
|
|
DO 8180 L=1,LMAX 6740. |
| 1095 |
|
|
AJL(J,L,12)=AJL(J,L,12)+(THM-T(I,J,L))*PK(I,J,L)*P(I,J) 6741. |
| 1096 |
|
|
T(I,J,L)=THM 6742. |
| 1097 |
|
|
|
| 1098 |
|
|
#if ( defined CPL_CHEM ) |
| 1099 |
|
|
! |
| 1100 |
|
|
! --- 03/23/95 |
| 1101 |
|
|
! |
| 1102 |
|
|
cfc11(i,j,l) = cfc11ms |
| 1103 |
|
|
|
| 1104 |
|
|
cfc12(i,j,l) = cfc12ms |
| 1105 |
|
|
|
| 1106 |
|
|
xn2o(i,j,l) = xn2oms |
| 1107 |
|
|
|
| 1108 |
|
|
o3(i,j,l) = o3ms |
| 1109 |
|
|
|
| 1110 |
|
|
co(i,j,l) = coms |
| 1111 |
|
|
|
| 1112 |
|
|
zco2(i,j,l) = zco2ms |
| 1113 |
|
|
|
| 1114 |
|
|
xno(i,j,l) = xnoms |
| 1115 |
|
|
|
| 1116 |
|
|
xno2(i,j,l) = xno2ms |
| 1117 |
|
|
|
| 1118 |
|
|
xn2o5(i,j,l) = xn2o5ms |
| 1119 |
|
|
|
| 1120 |
|
|
hno3(i,j,l) = hno3ms |
| 1121 |
|
|
|
| 1122 |
|
|
ch4(i,j,l) = ch4ms |
| 1123 |
|
|
|
| 1124 |
|
|
ch2o(i,j,l) = ch2oms |
| 1125 |
|
|
|
| 1126 |
|
|
so2(i,j,l) = so2ms |
| 1127 |
|
|
|
| 1128 |
|
|
h2so4(i,j,l) = h2so4ms |
| 1129 |
|
|
|
| 1130 |
|
|
! === if hfc, pfc, and sf6 are included: |
| 1131 |
|
|
#ifdef INC_3GASES |
| 1132 |
|
|
! === 032698 |
| 1133 |
|
|
hfc134a(i,j,l) = hfc134ams |
| 1134 |
|
|
|
| 1135 |
|
|
pfc(i,j,l) = pfcms |
| 1136 |
|
|
|
| 1137 |
|
|
sf6(i,j,l) = sf6ms |
| 1138 |
|
|
! === |
| 1139 |
|
|
#endif |
| 1140 |
|
|
|
| 1141 |
|
|
bcarbon(i,j,l) = bcms |
| 1142 |
|
|
ocarbon(i,j,l) = ocms |
| 1143 |
|
|
|
| 1144 |
|
|
c 062295 |
| 1145 |
|
|
c h2o2(i,j,l) = h2o2ms |
| 1146 |
|
|
c |
| 1147 |
|
|
! |
| 1148 |
|
|
#endif |
| 1149 |
|
|
|
| 1150 |
|
|
8180 Q(I,J,L)=QMS 6743. |
| 1151 |
|
|
IF(POLE) GO TO 8300 6744. |
| 1152 |
|
|
C**** MIX MOMENTUM THROUGHOUT THE BOUNDARY LAYER AT NON-POLAR GRID BOXES6745. |
| 1153 |
|
|
ID(1)=I+(J-1)*IM 6748. |
| 1154 |
|
|
ID(2)=ID(1)+IM*JM*LM 6749. |
| 1155 |
|
|
ID(3)=I+J*IM 6752. |
| 1156 |
|
|
ID(4)=ID(3)+IM*JM*LM 6753. |
| 1157 |
|
|
if(J.eq.JPR)then |
| 1158 |
|
|
print *,'ID for J=',j |
| 1159 |
|
|
print *,(ID(k),k=1,4) |
| 1160 |
|
|
print *,'RA for J=',j |
| 1161 |
|
|
print *,(RA(k),k=1,4) |
| 1162 |
|
|
endif |
| 1163 |
|
|
DO 8240 K=1,4 6754. |
| 1164 |
|
|
UMS(K)=0. 6755. |
| 1165 |
|
|
DO 8220 L=1,LMAX 6756. |
| 1166 |
|
|
8220 UMS(K)=UMS(K)+UT(ID(K),1,L)*DSIG(L) 6757. |
| 1167 |
|
|
8240 UMS(K)=UMS(K)*RDSIGS 6758. |
| 1168 |
|
|
DO 8260 L=1,LMAX 6759. |
| 1169 |
|
|
AJL(J,L,38)=AJL(J,L,38)+(UMS(1)-UT(I,J,L))*.5* 6760. |
| 1170 |
|
|
* P(I,J)*RA(1) 6761. |
| 1171 |
|
|
AJL(J+1,L,38)=AJL(J+1,L,38)+(UMS(3)- 6762. |
| 1172 |
|
|
* UT(I,J+1,L))*P(I,J)*RA(3)*.5 6763. |
| 1173 |
|
|
DO 8260 K=1,4 6764. |
| 1174 |
|
|
if(J.eq.JPR)then |
| 1175 |
|
|
print *,'L=',L,' K=',K |
| 1176 |
|
|
print *,'ID(K)=',ID(K),' RA(K)=',RA(K) |
| 1177 |
|
|
print *,'UMS(K)=',UMS(K),' UT(ID(K),1,L)=',UT(ID(K),1,L) |
| 1178 |
|
|
endif |
| 1179 |
|
|
8260 U(ID(K),1,L)=U(ID(K),1,L)+(UMS(K)-UT(ID(K),1,L))*RA(K) 6765. |
| 1180 |
|
|
GO TO 8500 6766. |
| 1181 |
|
|
C**** MIX MOMENTUM THROUGHOUT THE BOUNDARY LAYER AT POLAR GRID BOXES 6767. |
| 1182 |
|
|
8300 JVPO=2 6768. |
| 1183 |
|
|
IF(J.EQ.JM) JVPO=JM 6769. |
| 1184 |
|
|
RAPO=2.*RAPVN(1) 6770. |
| 1185 |
|
|
DO 8360 IPO=1,IM 6771. |
| 1186 |
|
|
UMSPO=0. 6772. |
| 1187 |
|
|
VMSPO=0. 6773. |
| 1188 |
|
|
DO 8320 L=1,LMAX 6774. |
| 1189 |
|
|
UMSPO=UMSPO+UT(IPO,JVPO,L)*DSIG(L) 6775. |
| 1190 |
|
|
8320 VMSPO=VMSPO+VT(IPO,JVPO,L)*DSIG(L) 6776. |
| 1191 |
|
|
UMSPO=UMSPO*RDSIGS 6777. |
| 1192 |
|
|
VMSPO=VMSPO*RDSIGS 6778. |
| 1193 |
|
|
DO 8340 L=1,LMAX 6779. |
| 1194 |
|
|
U(IPO,JVPO,L)=U(IPO,JVPO,L)+(UMSPO-UT(IPO,JVPO,L))*RAPO 6780. |
| 1195 |
|
|
V(IPO,JVPO,L)=V(IPO,JVPO,L)+(VMSPO-VT(IPO,JVPO,L))*RAPO 6781. |
| 1196 |
|
|
8340 AJL(JVPO,L,38)=AJL(JVPO,L,38) 6782. |
| 1197 |
|
|
* +(UMSPO-UT(IPO,JVPO,L))*P(1,J)*RAPO 6783. |
| 1198 |
|
|
8360 CONTINUE 6784. |
| 1199 |
|
|
8500 IM1=I 6793. |
| 1200 |
|
|
do j=1,jm |
| 1201 |
|
|
I=1 |
| 1202 |
|
|
if(J.eq.JPR.or.J.eq.-12)then |
| 1203 |
|
|
print *,' J=',J,' after dry convection' |
| 1204 |
|
|
print *,'U(I,J,1)=',U(I,J,1),' V(I,J,1)=',V(I,J,1) |
| 1205 |
|
|
print *,'U(I,J+1,1)=',U(I,J+1,1),' V(I,J+1,1)=',V(I,J+1,1) |
| 1206 |
|
|
endif |
| 1207 |
|
|
enddo |
| 1208 |
|
|
9000 CONTINUE 6794. |
| 1209 |
jscott |
1.3 |
! print *,' From surf_ocean T2MZ' |
| 1210 |
|
|
! print *,T2MZ |
| 1211 |
jscott |
1.1 |
do 9001 J=1,JM |
| 1212 |
|
|
c TSURFD(J)=TSURFD(J)+(BLDATA(1,J,2)-273.16)/24. |
| 1213 |
jscott |
1.4 |
! TSURFD(J)=TSURFD(J)+(T2MZ(J)-273.16)/24. |
| 1214 |
|
|
TSURFD(J)=TSURFD(J)+(T2MZ(J)-273.16)/NCLMPERDAY |
| 1215 |
jscott |
1.1 |
T2ML(J)=0.0 |
| 1216 |
|
|
9001 continue |
| 1217 |
|
|
RETURN 6795. |
| 1218 |
|
|
990 FORMAT ('0PPBL',3I4,14F8.2) 6818. |
| 1219 |
|
|
991 FORMAT ('0SURFACE ',4I4,5F10.4,3F11.7) 6819. |
| 1220 |
|
|
992 FORMAT ('0',I2,10F10.4/23X,4F10.4,10X,2F10.4/ 6820. |
| 1221 |
|
|
* 33X,3F10.4,10X,2F10.4) 6821. |
| 1222 |
|
|
993 FORMAT ('0',I2,10F10.4/23X,7F10.4/33X,7F10.4) 6822. |
| 1223 |
|
|
994 FORMAT ('0',I2,11F10.4) 6823. |
| 1224 |
|
|
END 6824. |
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