#include "ctrparam.h" SUBROUTINE RADIA 5001. C**** 5002. C**** THIS SUBROUTINES ADDS THE RADIATION HEATING TO THE TEMPERATURES 5003. C**** 5004. #include "BD2G04.COM" #include "chem_para" #include "chem_com" COMMON U,V,T,P,Q 5006. COMMON/ADDALB/BVSURFA,XVSURFA,BNSURFA,XNSURFA COMMON/WORK1/CONV(IM0,JM0,LM0),PK(IM0,JM0,LM0),PREC(IM0,JM0), & TPREC(IM0,JM0), 5007. * COSZ1(IO0,JM0),COSZ2(IO0,JM0),COSZA(IO0,JM0), 5008. * TRINCG(IO0,JM0),BTMPW(IO0,JM0),SNFS(IO0,JM0,4),TNFS(IO0,JM0,4), 5009. * TRHRS(IO0,JM0,3),SRHRS(IO0,JM0,3),ALB(IO0,JM0,9) 5010. COMMON/WORK2/CLDSS(IM0,JM0,LM0),CLDMC(IM0,JM0,LM0), 5011. * TOTCLD(36) 5012. DIMENSION TRNFP0(JM0),TRNFP1(JM0),ALBJ(JM0,9) real ODATA2(JM0,2),GDATA2(JM0,14),BDATA2(JM0,2),FDATA2(JM0,2), * RQT2(JM0,3) common/SURRAD/TRSURF(JM0,4),SRSURF(JM0,4) common/FORAERSOL/FORSULF,FORBC logical FORSULF,FORBC C COMMON/WORK4/ IS BEING USED BY THE RADIATION ROUTINES 5013. C 5014. C RADCOM: CONTROL/INPUT PARAMETERS 5015. C 5016. COMMON/RADCOM/VADATA(11,4,3),DGLAT(46),DGLON(72),TMINSR,FULGAS(18)5017. A ,FRACSL,RATQSL,FOGTSL,PTLISO,TLGRAD,TKCICE,FGOLDU(18)5018. B ,FLONO3,FRAYLE,FCLDTR,FCLDSR,FALGAE,FMARCL,FEMTRA(6) 5019. C ,WETTRA,WETSRA,DMOICE,DMLICE,LICETK,NTRCE,FZASRA(6) 5020. D ,ID5(5),ITR(4),IMG(2),ILG(2),LAPGAS,KWVCON,NORMS0,NV 5021. E ,KEEPRH,KEEPAL,ISOSCT,IHGSCT,KFRACC,KGASSR,KAERSR 5022. F ,MARCLD,LAYTOP,LMR,LMRP,JMLAT,IMLON,KFORCE,LASTVC 5023. C 5024. C BASIC RADCOM INPUT DATA 5025. C 5026. G ,PLE(40),HLB(40),TLB(40),TLT(40),TL(40),U0GAS(40,9) 5027. H ,ULGAS(40,9),TRACER(40,4),RTAU(40),QL(40),RHL(40) 5028. I ,POCEAN,PEARTH,POICE,PLICE,AGESN,SNOWE,SNOWOI,SNOWLI 5029. J ,TGO,TGE,TGOI,TGLI,TS,WS,WEARTH,ZOICE,FSPARE(200) 5030. K ,S0,COSZ,PVT(11),BXA(153),SRBXAL(15,2),FRC(5),LUXGAS 5031. L ,JYEARR,JDAYR,JLAT,ILON,MEANAL,KALVIS,ISPARE(25),SGPS5032. C 5033. C BASIC RADCOM OUTPUT DATA 5034. C 5035. M ,TRDFLB(40),TRUFLB(40),TRNFLB(40),TRFCRL(40),TRSLCR 5036. N ,SRDFLB(40),SRUFLB(40),SRNFLB(40),SRFHRL(40),SRSLHR 5037. O ,SRIVIS,SROVIS,PLAVIS,SRINIR,SRONIR,PLANIR,SRXATM(4) 5038. P ,SRDVIS,SRUVIS,ALBVIS,SRDNIR,SRUNIR,ALBNIR,FSRNFG(4) 5039. Q ,SRTVIS,SRRVIS,SRAVIS,SRTNIR,SRRNIR,SRANIR,FTRUFG(4) 5040. R ,TRDFGW,TRUFGW,TRUFTW,BTEMPW,TRDFSL,TRUFSL,DTRUFG(4) 5041. S ,TRSLTS,TRSLTG,TRSLWV,TRSLBS,TTRUFG,LBOTCL,LTOPCL 5042. DIMENSION COE(39) 5043. LOGICAL POLE,DC25,HPRNT,WRCLD,CLDFEED 5044. #if ( defined OCEAN_3D ) #include "AGRID.h" #endif #if ( defined CLM ) #include "CLM.COM" #endif c common /ATCO2/atm_co2(jm0) common/conprn/HPRNT common/COMCLD/READGHG,PCLOUD,WRCLD,NWRCLD,NWRCL,INYEAR,JNDAY &,CFAEROSOL,ALFA,CFBC,cfvolaer common/ghstfor/GHSFALB,GHSF,ALBCF,FVOLADD,STRARFOR,S0FOR,CO2FOR, & CO2F,ghostfv(LM0+1),ghostf(LM0+1,JM0),ghflux(LM0+1,JM0) logical GHSFALB,GHSF,GSOEQ,STRARFOR,S0FOR,CO2FOR common/eqgso/GSOEQ common/cldfdb/coefcl(3),CLDFEED common/aexpc/AEXP,ISTRT1 common/ SNOWALB/FRSNALB,III common/ S0XR/S0RATE,CFS0X common/ BACKGRGHG/GHGBGR(5) COMMON/CO2TRND/ALFFOR,CO2TR,YEARGT,CO2IN,INYRAD dimension CLDSSF(JM0,LM0),CLDMCF(JM0,LM0) &,BSO4LAND(JM0),BSO4OCEAN(JM0),BSO4TOTAL(JM0) &,bcodmn(JM0,LM0,12) dimension DSWSRF(jm0),DLWSRF(jm0),DSWVIS(jm0),DSWNIR(jm0) integer PCLOUD common/TSUR/TSURFC(JM0,0:13),TSURFT(JM0),TSURFD(JM0),DTSURF(JM0) *,cfcld(JM0,3) CHARACTER*4 JMNTHF,JMLAST DATA JMLAST /'LAST'/ DATA TF/273.16/,TCIR/258.16/,STBO/.567257E-7/,IFIRST/1/,JDLAST/-9/5045. DATA IRFIRST /1/ C **** CLEAR SKY dimension SRHRCL(JM0),TRHRCL(JM0),ALBCL(JM0),SNP1CL(JM0), *SNP0CL(JM0),TRINCL(JM0),TRP0CL(JM0),TRP1CL(JM0) dimension RTAU0(LM0),TOTCLD0(LM0) common/clrsk/CLEAR(JM0),NCLR(JM0),AJCLR(JM0,12),BJCLR(JM0,12), * CJCLR(JM0,12) integer CLEAR C AJCLR C 1 SW INC AT P0 RD (AJ(1)) C 2 SW ABS BELOW P0 RD (AJ(2)) C 3 SW ABS BELOW P1 RD (AJ(3)) C 4 SW ABS AT Z0 RD (AJ(6)) C 5 SW INC AT Z0 RD (AJ(5)) C 6 LW INC AT Z0 RD (AJ(67)) C 7 NET LW AT Z0 SF (AJ(9)) C 8 NET LW AT P0 RD (AJ(7)) C 9 NET LW AT P1 RD (AJ(8)) C 10 NET RAD AT P0 DG (AJ(10)) C 11 NET RAD AT P1 DG (AJ(11)) C 12 NET RAD AT Z0 DG (AJ(12)) C **** CLEAR SKY C**** 5046. C**** FDATA 2 LAND COVERAGE (1) 5047. C**** 3 RATIO OF LAND ICE COVERAGE TO LAND COVERAGE (1) 5048. C**** 5049. C**** ODATA 1 OCEAN TEMPERATURE (C) 5050. C**** 2 RATIO OF OCEAN ICE COVERAGE TO WATER COVERAGE (1) 5051. C**** 5052. C**** GDATA 1 OCEAN ICE SNOW AMOUNT (KG/M**2) 5053. C**** 2 EARTH SNOW AMOUNT (KG/M**2) 5054. C**** 3 OCEAN ICE TEMPERATURE OF FIRST LAYER (C) 5055. C**** 4 EARTH TEMPERATURE OF FIRST LAYER (C) 5056. C**** 5 EARTH WATER OF FIRST LAYER (KG/M**2) 5057. C**** 6 EARTH ICE OF FIRST LAYER (KG/M**2) 5058. C**** 11 AGE OF SNOW (DAYS) 5059. C**** 12 LAND ICE SNOW AMOUNT (KG/M**2) 5060. C**** 13 LAND ICE TEMPERATURE OF FIRST LAYER (C) 5061. C**** 5062. C**** BLDATA 1 COMPOSITE SURFACE WIND MAGNITUDE (M/S) 5063. C**** 2 COMPOSITE SURFACE AIR TEMPERATURE (K) 5064. C**** 5 FREE 5065. C**** 5066. C**** VDATA 1-8 EARTH RATIOS FOR THE 8 VEGETATION TYPES (1) 5067. C**** 9 WATER FIELD CAPACITY OF FIRST LAYER (KG/M**2) 5068. C**** 5069. dimension GHGBGR0(5) IF(MODRD.EQ.0) IDACC(2)=IDACC(2)+1 5070. IF (IFIRST.NE.1) GO TO 50 5071. if(GHSF)then do j=1,jm ghflux(1,j)=ghostf(1,j) do l=2,lm0+1 ghflux(l,j)= ghflux(l-1,j)+ghostf(l,j) enddo enddo do l=1,lm0+1 print *,l,ghflux(l,1) enddo endif JDAYR=JNDAY JYEARR=INYEAR c GHGBGR(1)=GHGBGR0(1) c GHGBGR(2)=GHGBGR0(2) c GHGBGR(3)=GHGBGR0(3) c GHGBGR(4)=GHGBGR0(4)*1000. c GHGBGR(5)=GHGBGR0(5)*1000. c print *,'Background GHGs' print '(5E12.4)',GHGBGR nreadcld=0 nrbyyr=24*365/5 nrcldmax=20*nrbyyr c print *,' CLOUDS for ',nrcldmax/nrbyyr,' years' print *,'RADIA' KTREND=-CO2 JDAY00=-1 if(CLDFEED)then c print *,' radia.f coefcl=',coefcl print *,' for low and middle clouds',coefcl(1) print *,' for top clouds',coefcl(2) print *,' for MC clouds',coefcl(3) endif print *,' READGHG=',READGHG print *,' CFAEROSOL=',CFAEROSOL #if ( defined PREDICTED_BC) print *,'With black carbon forcing' print *,' CFBC=',CFBC nrdbc=0 read(769),bcodmn ! do nm=1,12 ! do l=1,lm ! do j=1,jm ! bcodmn(j,l,nm)=bcod(1,j,l) ! enddo ! enddo ! enddo #endif do j=1,jm BSO4TOTAL(j)=1.0 BSO4LAND(j)=1.0 BSO4OCEAN(j)=1.0 enddo print *,' separate caclulations for land and ocean' DC25=.TRUE. ! DC25=.FALSE. if(DC25)then print *,' with DC' else print *,' without DC' print *,' subroutine COSZR' end if if(abs(PCLOUD-3.).gt.1.5.and..NOT.WRCLD)IFIRST=0 5072. LMP1=LM+1 5072.1 DTCNDS=NCNDS*DT 5073. C**** SET THE CONTROL PARAMETERS FOR THE RADIATION 5074. JMLAT=JM 5074.1 if(JM.ne.24) then DO J=1,JMLAT DGLAT(J)=acos(COSP(J))*360./TWOPI if(J.le.JMLAT/2)DGLAT(J)=-DGLAT(J) END DO endif IMLON=IO 5074.2 LMR=LM+3 5075. COEX=.01*GRAV*KAPA/RGAS 5076. PSFMPT=PSF-PTOP 5077. DO 30 L=1,LM 5078. COE(L)=DTCNDS*COEX/DSIG(L) 5079. 30 PLE(L)=SIGE(L)*(PSF-PTOP)+PTOP 5080. PLE(LMP1)=PTOP 5081. PLE(LM+2)=.5*PTOP 5082. PLE(LMR)=.2*PTOP 5083. PLE(LMR+1)=1.E-5 5084. DO 40 LR=LMP1,LMR 5085. COE(LR)=DT*NRAD*COEX/(PLE(LR)-PLE(LR+1)) 5086. QL(LR)=.3E-5 5087. 40 RTAU(LR)=0. 5088. DPMICE=10. 5089. C S0X=1. 5089.1 KSTREND=S0RATE*100. print *,'S0RATE=',S0RATE,' KSTREND=',KSTREND print *,'From first call of radia CFS0X=',CFS0X #if ( defined FIXED_FOR ) print *,'Run with fixed forcing' #endif C if(GSOEQ)then if(KSTREND.ne.0)then print *,'Wrong setting of GSOEQ and KSTREND' print *,' GSOEQ=',GSOEQ,' KSTREND=',KSTREND c stop endif if(YEARGT.ne.1860)then print *,'Wrong setting of GSOEQ and YEARGT' print *,' GSOEQ=',GSOEQ,' YEARGT=',YEARGT stop endif C For an equilibrium run for 1860 conditions for GSO runs print *, & 'An equilibrium run for 1860 conditions for GSO runs' S0X=1365.3596/1367. print *,'Sconstant=',S0X*1367. RVOL=0.012 FVOL=0.0045 FGOLDU(1)=(RVOL+FVOL)/RVOL print *,'Additional STAER=',FVOL, & ' FGOLDU(1)=',FGOLDU(1) C endif if(CO2FOR)then print *,' Forcing due to ',CO2F,'xCO2 is calculated', * 'in stead of cloud forcing' endif if(S0FOR)then print *,' Forcing due to change in solar constant ', * 'is calculated in stead of cloud forcing' endif if(FORBC)then print *,' Forcing due to black carbon ', * 'is calculated in stead of cloud forcing' endif if(STRARFOR)then RVOL=0.012 FVOL=FVOLADD FGOLDU1=(RVOL+FVOL)/RVOL print *,'Additional STAER=',FVOL, & ' FGOLDU1=',FGOLDU1 endif if(GHSFALB)then Print *,' Run with ghost albedo forcing' print *,'ALBCF=',ALBCF endif if(GHSF)then Print *,' Run with ghost forcing' do l=1,lm+1 ghostfv(l)=0.0 do j=1,jm ghostfv(l)=ghostfv(l)+ghostf(l,j) enddo ghostfv(l)=ghostfv(l)/float(jm) enddo print *,' Ghost forcing DFS=',ghostfv(1) do l=LM+1,2,-1 print *,' Forsing at laeyr',l-1,'=',ghostfv(l) enddo c print *,' 2D ghost forcing' endif S0X=CFS0X*S0X S0X0=S0X print *,'Before CALL RADIA0' CALL RADIA0 (IO,JM,CO2,READGHG) 5090. print *,'After CALL RADIA0' INCHM=NRAD/NDYN 5091. C**** CLOUD LAYER INDICES USED FOR DIAGNOSTICS 5092. DO 43 L=1,LM 5093. LLOW=L 5094. IF (.5*(PLE(L+1)+PLE(L+2)).LT.786.) GO TO 44 5095. 43 CONTINUE 5096. 44 LMID1=LLOW+1 5097. DO 45 L=LMID1,LM 5098. LMID=L 5099. IF (.5*(PLE(L+1)+PLE(L+2)).LT.430.) GO TO 46 5100. 45 CONTINUE 5101. 46 LHI1=LMID+1 5102. LHI=LM 5103. IF (LHI1.GT.LHI) LHI=LHI1 5104. WRITE (6,47) LLOW,LMID1,LMID,LHI1,LHI 5105. 47 FORMAT (' LOW CLOUDS IN LAYERS 1-',I2,' MID LEVEL CLOUDS IN',5106. * ' LAYERS',I3,'-',I2,' HIGH CLOUDS IN LAYERS',I3,'-',I2) 5107. C**** NO RADIATION AVERAGING IJRA=1 JRA=1 IRA=1 5108. C**** RADIATION AVERAGING IN I 2 1 2 5109. C**** RADIATION AVERAGING IN I AND J 4 2 2 5110. JRA=(IJRA+2)/3 5111. IRA=IJRA/JRA 5112. 50 JALTER=MOD(NSTEP,NRAD*JRA)/NRAD 5113. JDAYR=JDAY JYEARR=JYEAR IALTER=MOD(NSTEP,NRAD*IJRA)/(NRAD*JRA) 5114. TNOW=JYEAR+(JDAY-.5)/365. 5127.1 IF (JDAY.NE.JDLAST.AND.KSTREND.NE.0) then IF (KSTREND.GT.0) then if(abs(CFS0X-1.0).gt.1.e3)then print *,'Wrong setting KSTREND=',KSTREND,' CFS0X=', & CFS0X endif S0X=S0X0*(1.+S0RATE/70.*(TNOW-INYEAR)) c print *,'From radia S0X0=',S0X0,' S0X=',S0X c print *,'S0X=',S0X,' TNOW=',TNOW ELSE call obssolar(S0X,TNOW) ENDIF ENDIF S0=S0X*1367./RSDIST 5115. S0R=S0 c print *,'S0=',S0 C**** CALCULATE AVERAGE COSINE OF ZENITH ANGLE FOR CURRENT COMP3 STEP 5116. C**** AND RADIATION PERIOD 5117. ROT1=TWOPI*TOFDAY/24. 5118. if(DC25)then ROT2=ROT1+TWOPI*DTCNDS/SDAY 5119. CALL COSZT (IO,JM,SIND,COSD,ROT1,ROT2,COSZ1) 5120. else ROT2=ROT1+TWOPI CALL COSZR (IO,JM,SIND,COSD,ROT1,ROT2,COSZ1) end if if(HPRNT)then print *,' radia TAU=',TAU print *,' CLDSS' print *,(CLDSS(1,7,L),L=1,LM) print *,' CLDMC' print *,(CLDMC(1,7,L),L=1,LM) endif cprint *,' form radia TAU=',TAU,'MODRD=',MODRD C IF(MODRD.NE.0) GO TO 840 5121. C ROT2=ROT1+TWOPI*NRAD*DT/SDAY 5122. CALL COSZS (IO,JM,SIND,COSD,ROT1,ROT2,COSZ2,COSZA) 5123. C**** 5124. C**** COMPUTE EARTH ALBEDOS AND OTHER PARAMETERS FOR BEGINNING OF DAY 5125. TNOW=JYEAR+(JDAY-.5)/365. 5127.1 KWRITE=0 if(JMONTH.ne.JMLAST) then KWRITE=1 print *,' FROM radia READGHG=',READGHG if(READGHG.eq.2) call tgases(CO2,JMONTH) c print *,(zco2(1,j,1) c & *28.97296245/44.0*1.e-3,j=1,jm) !ppb(m) to kg per volume base if(READGHG.eq.1) call rtgases(CO2,JMONTH) #if ( defined PREDICTED_BC) nrdbc=nrdbc+1 do l=1,lm do j=1,jm bcod(1,j,l)=bcodmn(j,l,nrdbc) enddo enddo if(nrdbc.eq.12)then nrdbc=0. endif #endif endif JMLAST=JMONTH IF (JDAY.NE.JDLAST.AND.KTREND.GT.0) & CALL FORGET(TNOW,KTREND,KWRITE) IF (JDAY.NE.JDLAST)then #ifdef PREDICTED_GASES call chemglobal(P) #endif #if ( defined PREDICTED_BC) call sulfr(BSO4LAND,BSO4OCEAN,1986.) do j=1,jm FLAND=FDATA(1,J,2) BSO4TOTAL(j)=BSO4LAND(j)*FLAND+BSO4OCEAN(j)*(1.-FLAND) enddo #endif CALL RCOMPT if(CLDFEED)then DTSURFAV=0. C do j=1,jm DTSURFAV=DTSURFAV+DTSURF(J)*DXYP(j) end do !j DTSURFAV=DTSURFAV/AREAG do j=1,jm do k=1,3 cfcld(j,k)=1.+coefcl(k)*DTSURFAV end do ! k end do ! j endif ENDIF JDLAST=JDAY 5129. IHOUR=1.5+TOFDAY 5130. if(CLDFEED)then if (KWRITE.eq.1)then print *,'cfcld' print 9456,cfcld print *,' DTSURF' print 9456,DTSURF print *,' DTSURFAV=',DTSURFAV 9456 format(12f6.2) endif C Save clouds predicted by model do k=1,LM do j=1,JM CLDSSF(j,k)=CLDSS(1,j,k) CLDMCF(j,k)=CLDMC(1,j,k) enddo enddo do k=1,LM if(k.le.5)then k1=1 else k1=2 endif do j=1,JM CLDSS(1,j,k)=cfcld(j,k1)*CLDSS(1,j,k) CLDMC(1,j,k)=cfcld(j,3)*CLDMC(1,j,k) enddo enddo endif C CB READING OF CLOUD if(abs(PCLOUD-3.).lt.1.5)then 910 continue if(nreadcld.eq.nrcldmax)go to 900 read(585,END=900)TFDAYF,JDATEF,JMNTHF,CLDSSF,CLDMCF,IRAND nreadcld=nreadcld+1 if(IFIRST.eq.1)then print *,' radia.f PCLOUD=',PCLOUD if(PCLOUD.eq.2)print *,' FIXED MC and SS CLOUDS' if(PCLOUD.eq.4)print *,' FIXED MC CLOUDS ONLY' if(PCLOUD.eq.3)print *,' FIXED SS CLOUDS ONLY' print *,TOFDAY,JDATE,JMONTH print *,TFDAYF,JDATEF,JMNTHF print *,' DTCNDS=',DTCNDS/3600. print *,' DT*NRAD=',DT*NRAD/3600. if(.not.WRCLD)IFIRST=0 endif if(abs(TOFDAY-TFDAYF).gt.1.e-3.or.JDATE.ne.JDATEF.or. * JMONTH.ne.JMNTHF)then print *,' RADIA, disagrement in clouds' print *,TOFDAY,JDATE,JMONTH print *,TFDAYF,JDATEF,JMNTHF stop endif go to 920 900 rewind 585 nreadcld=0 print *,' END OF file85' print *,JYEAR print *,TOFDAY,JDATE,JMONTH print *,' REWIND 85' go to 910 920 continue c if (KWRITE.eq.1)then c print *,'cfcld' c print 9456,cfcld c print *,' DTSURF' c print 9456,DTSURF c9456 format(12f6.2) c endif CALL RINIT (IRAND) do 930 k=1,LM do 930 j=1,JM if(PCLOUD.ne.4)CLDSS(1,j,k)=CLDSSF(j,k) if(PCLOUD.ne.3)CLDMC(1,j,k)=CLDMCF(j,k) 930 continue endif CE END OF READING OF CLOUD if(WRCLD)then if(NWRCLD.eq.1)then CALL RFINAL(IRAND) if(IFIRST.eq.1)print *,' SHORT CLOUDS RECORD' write(581)TOFDAY,JDATE,JMONTH,CLDSS,CLDMC,IRAND elseif(NWRCLD.eq.2)then if(IFIRST.eq.1)print *,' LONG CLOUDS RECORD' do 1150 k=1,14 do 1150 j=1,JM0 if(k.le.2)then ODATA2(j,k)=ODATA(1,j,k) BDATA2(j,k)=BLDATA(1,j,k) FDATA2(j,k)=FDATA(1,j,k+1) endif if(k.le.3)RQT2(j,k)=RQT(1,j,k) GDATA2(j,k)=GDATA(1,j,k) 1150 continue CALL RFINAL(IRAND) write(581)TOFDAY,JDATE,JMONTH,CLDSS,CLDMC,IRAND, * JDAY,JYEAR,T,Q,P, * ODATA2,BDATA2,FDATA2,GDATA2,RQT2 & ,CLDSSF,CLDMCF else print *,' NWRCLD=',NWRCLD stop endif IFIRST=0 endif C**** 5131. C**** MAIN J LOOP 5132. C**** 5133. DO 600 J=1,JM 5134. IF ((J-1)*(JM-J).NE.0) GO TO 140 5135. C**** CONDITIONS AT THE POLES 5136. POLE=.TRUE. 5137. MODRJ=0 5138. IMAX=1 5139. GO TO 160 5140. C**** CONDITIONS AT NON-POLAR POINTS 5141. 140 POLE=.FALSE. 5142. MODRJ=MOD(J+JALTER,JRA) 5143. IMAX=IM 5144. 160 XFRADJ=.2+1.2*COSP(J)*COSP(J) 5145. JLAT=J 5145.1 if(GSOEQ)then C RVOL=0.012 FVOL=0.0045 FGOLDU(1)=(RVOL+FVOL)/RVOL C endif IF(MODRJ.EQ.0) CALL RCOMPJ 5146. C**** 5147. C**** MAIN I LOOP 5148. C**** 5149. IM1=IM 5150. DO 500 I=1,IMAX 5151. MODRIJ=MODRJ+MOD(I+IALTER,IRA) 5152. IF(POLE) MODRIJ=0 5153. JR=J C**** DETERMINE FRACTIONS FOR SURFACE TYPES AND COLUMN PRESSURE 5155. PLAND=FDATA(I,J,2) 5156. PWATER=1.-PLAND POICE=ODATA(I,J,2)*(1.-PLAND) 5157. POCEAN=(1.-PLAND)-POICE 5158. if(POCEAN.LE.1.E-5)then POCEAN=0. POICE=PWATER endif PLICE=FDATA(I,J,3)*PLAND 5159. PEARTH=PLAND-PLICE 5160. SP=P(I,J) 5161. C**** 5162. C**** DETERMINE CLOUDS (AND THEIR OPTICAL DEPTHS) SEEN BY RADIATION 5163. C**** 5164. X=999999. 5164.1 c RANDSS=RANDU(X) 5165. c RANDMC=RANDU(X) 5166. CALL RANDUU(RANDSS,X) CALL RANDUU(RANDMC,X) if(HPRNT)then print *,' radia TAU=',TAU print *,' RANDSS=',RANDSS print *,' RANDMC=',RANDMC endif C CSS=0. 5167. CMC=0. 5168. DEPTH=0. 5169. LTOP=0 5169.1 DO 210 L=1,LM 5170. RTAU(L)=0. 5171. 210 TOTCLD(L)=0. 5172. DO 240 L=1,LM 5173. IF(CLDSS(I,J,L).LT.RANDSS) GO TO 220 5174. RTAUSS=.013333*(PTOP-100.+SIG(L)*SP) 5175. IF(RTAUSS.LT.0.) RTAUSS=0. 5176. IF (T(I,J,L)*PK(I,J,L).LT.TCIR) RTAUSS=.3333333 5177. RTAU(L)=RTAUSS 5178. CSS=1. 5179. AJL(J,L,28)=AJL(J,L,28)+CSS 5180. TOTCLD(L)=1. 5181. LTOP=L 5181.1 220 IF(CLDMC(I,J,L).LE.RANDMC) GO TO 240 5182. RTAUMC=DSIG(L)*SP*.08 5183. IF(RTAUMC.GT.RTAU(L)) RTAU(L)=RTAUMC 5184. CMC=1. 5185. AJL(J,L,29)=AJL(J,L,29)+CMC 5186. TOTCLD(L)=1. 5187. LTOP=L 5187.1 DEPTH=DEPTH+SP*DSIG(L) 5188. AJL(J,L,19)=AJL(J,L,19)+TOTCLD(L) 5189. 240 CONTINUE AJ(J,57)=AJ(J,57)+CSS*POCEAN 5190. BJ(J,57)=BJ(J,57)+CSS*PLAND 5191. CJ(J,57)=CJ(J,57)+CSS*POICE 5192. DJ(JR,57)=DJ(JR,57)+CSS*DXYP(J) 5193. AJ(J,58)=AJ(J,58)+CMC*POCEAN 5194. BJ(J,58)=BJ(J,58)+CMC*PLAND 5195. CJ(J,58)=CJ(J,58)+CMC*POICE 5196. DJ(JR,58)=DJ(JR,58)+CMC*DXYP(J) 5197. AIJ(I,J,17)=AIJ(I,J,17)+CMC 5198. AJ(J,80)=AJ(J,80)+DEPTH*POCEAN 5199. BJ(J,80)=BJ(J,80)+DEPTH*PLAND 5200. CJ(J,80)=CJ(J,80)+DEPTH*POICE 5201. DJ(JR,80)=DJ(JR,80)+DEPTH*DXYP(J) 5202. CLDCV=CMC+CSS-CMC*CSS 5203. cldd4tem(j)=cldd4tem(j)+CLDCV ncldd4tem(j)=ncldd4tem(j)+1 AJ(J,59)=AJ(J,59)+CLDCV*POCEAN 5204. BJ(J,59)=BJ(J,59)+CLDCV*PLAND 5205. CJ(J,59)=CJ(J,59)+CLDCV*POICE 5206. DJ(JR,59)=DJ(JR,59)+CLDCV*DXYP(J) 5207. C**** clear sky condinion CSS0=CSS CMC0=CMC do L=1,LM RTAU0(L)=RTAU(L) TOTCLD0(L)=TOTCLD(L) enddo if(CMC.le.0.and.CSS.le.0)then CLEAR(J)=1 else CLEAR(J)=0 endif if(STRARFOR.or.CO2FOR.or.S0FOR.or.FORBC)then CLEAR(J)=0 endif C**** 5247. C**** SET UP VERTICAL ARRAYS OMITTING THE I AND J INDICES 5248. C**** 5249. C**** EVEN PRESSURES 5250. DO 340 L=1,LM 5251. PLE(L)=SIGE(L)*SP+PTOP 5252. C**** TEMPERATURES 5253. TL(L)=T(I,J,L)*PK(I,J,L) 5254. C**** MOISTURE VARIABLES 5255. QL(L)=Q(I,J,L) 5256. 340 CONTINUE 5257. C**** 5258. C**** RADIATION, SOLAR AND THERMAL 5259. C**** 5260. DO 420 K=1,3 5261. 420 TL(LM+K)=RQT(I,J,K) 5262. COSZ=COSZA(I,J) 5263. TGO=ODATA(I,J,1)+TF 5264. TGOI=GDATA(I,J,3)+TF 5265. TGLI=GDATA(I,J,13)+TF 5266. TGE=GDATA(I,J,4)+TF 5267. TS=BLDATA(I,J,2) 5268. SNOWOI=GDATA(I,J,1) 5269. SNOWLI=GDATA(I,J,12) 5270. SNOWE=GDATA(I,J,2) 5271. AGESN=GDATA(I,J,11) 5272. c print *,'From radia J=',J,' TAU=',TAU,' TS=',TS c print *,TGO,TGOI,TGLI,TGE c print *,SNOWOI,SNOWLI,SNOWE,AGESN WEARTH=(GDATA(I,J,5)+GDATA(I,J,6))/(VDATA(I,J,9)+1.E-20) 5273. DO 430 K=1,8 5274. 430 PVT(K)=VDATA(I,J,K) 5275. WS=BLDATA(I,J,1) 5276. do 439 L=1,LM+1 SRHR(I,J,L)=0. TRHR(I,J,L)=0. if(L.le.4)then SNFS(I,J,L)=0. TNFS(I,J,L)=0. if(L.le.3)then SRHRS(I,J,L)=0. TRHRS(I,J,L)=0. endif endif 439 continue TRNFP0(J)=0. TRNFP1(J)=0. TRINCG(I,J)=0. BTMPW(I,J)=0. SRDAN=0. SRNAN=0. do 449 K=1,9 ALB(I,J,K)=0. ALBJ(J,K)=0. 449 continue do 499 ii=1,3 COSZ=COSZA(I,J) PLAND=FDATA(I,J,2) PWATER=1.-PLAND POICE=ODATA(I,J,2)*(1.-PLAND) POCEAN=(1.-PLAND)-POICE if(POCEAN.LE.1.E-5)then POCEAN=0. POICE=PWATER endif PLICE=FDATA(I,J,3)*PLAND PEARTH=PLAND-PLICE if(ii.eq.1)then BSO4BC=BSO4OCEAN(J)/BSO4TOTAL(J) PTYPE=POCEAN POICE=0. POCEAN=1. PLAND=0. PEARTH=0. PLICE=0. TGAL=0. else if(ii.eq.3)then BSO4BC=BSO4OCEAN(J)/BSO4TOTAL(J) PTYPE=POICE POICE=1. POCEAN=0. PLAND=0. PEARTH=0. PLICE=0. TGAL=TGOI else BSO4BC=BSO4LAND(J)/BSO4TOTAL(J) PTYPE=PLAND POCEAN=0. POICE=0. PWATER=0. PLICE=FDATA(I,J,3) PEARTH=1.-PLICE TGAL=TGE*PEARTH+TGLI*PLICE PLAND=1. endif if(PTYPE.lt.1.e-10)go to 499 if(ii.gt.1)then if(TGAL.lt.263.)then FRSNALB=0.30 elseif(TGAL.lt.273.)then FRSNALB=0.30-0.015*(TGAL-263.) else FRSNALB=0.15 endif endif !ii c FGOLDU(2)=XFRADJ*(1.-PEARTH) 5277. c FGOLDU(3)=XFRADJ*PEARTH 5278. FGOLDU(2)=XFRADJ*(1.-PLAND) FGOLDU(3)=XFRADJ*PLAND if(CO2FOR)then IF (KTREND.GT.0) THEN CALL FORGET(TNOW,KTREND,0) ELSE FULGAS(2)=CO2 ENDIF endif ! #if ( defined FIXED_FOR ) FULGAS(2)=1. #endif ! if(S0FOR)then S0=S0R endif CSS=CSS0 CMC=CMC0 do L=1,LM RTAU(L)=RTAU0(L) TOTCLD(L)=TOTCLD0(L) enddo Chemstry Model Patch 092295 c PTYPER=max(PTYPE,5.e-3) FAERSOL=PLAND/PTYPER*3.0*CFAEROSOL C Factor 3 is a "parameterization" for indirec aerosol effect c For normal setting CFAEROSOL=1.0 (default) c For hight forcing CFAEROSOL=0.5 c For low forcing CFAEROSOL=2.0 c c ========================== #if ( defined PREDICTED_BC) FBC=BSO4BC*CFBC #endif ILON=I 5278.1 JLAT=J 5278.2 if(GHSFALB)then BVSURFA=ALBCF XVSURFA=ALBCF BNSURFA=ALBCF XNSURFA=ALBCF else BVSURFA=0.0 XVSURFA=0.0 BNSURFA=0.0 XNSURFA=0.0 endif if(STRARFOR)then c if(j.gt.JM/2)then FGOLDU(1)=FGOLDU1 c else c FGOLDU(1)=1. c endif endif if(J.eq.-10)then print *,'From radia GHSFALB=',GHSFALB,' ALBCF=',ALBCF print *,'From radia BVSURFA=',BVSURFA endif c if(J.eq.1)then c print *,ii,PTYPE,PWATER,POCEAN,POICE,PLAND,PEARTH,PLICE c print *,(FGOLDU(if),if=1,5) c endif c print *,'S0 for real calculation=',S0 CALL RCOMPX 5279. if (IRFIRST.eq.1.and.READGHG.eq.1)then CALL WRITER(12) if(ii.ge.2)IRFIRST=0 endif IF(DMOD(TAU,365.*24.).EQ.0..and.J.eq.JM/2) then print *,' tau=',TAU,' J=',J CALL WRITER (1,0) endif c CALL WRITER (13) 5280. SRHR(I,J,1)=SRHR(I,J,1)+SRNFLB(1)*PTYPE c GHOST FORCINGS if(GHSF)then do LFR=1,lm+1 if(LFR.gt.1)then TRFCRL(LFR-1)=TRFCRL(LFR-1)-ghostf(LFR,J) TRNFLB(LFR)=TRNFLB(LFR)+ghflux(LFR,J) endif enddo endif c TRHR(I,J,1)=TRHR(I,J,1)+(STBO*(POCEAN*TGO**4+POICE*TGOI**4 * +PLICE*TGLI**4+PEARTH*TGE**4)-TRNFLB(1))*PTYPE if(GHSF)then TRHR(I,J,1)=TRHR(I,J,1)+ghostf(1,J)*PTYPE TRDFLB(1)=TRDFLB(1)+ghostf(1,J) endif C ***** TRSURF(J,ii)=STBO*(POCEAN*TGO**4+POICE*TGOI**4 * +PLICE*TGLI**4+PEARTH*TGE**4)-TRNFLB(1) if(GHSF)then TRSURF(J,ii)=TRSURF(J,ii)+ghostf(1,J) endif SRSURF(J,ii)=SRNFLB(1) DO 440 L=1,LM 5284. SRHR(I,J,L+1)=SRHR(I,J,L+1)+SRFHRL(L)*PTYPE 440 TRHR(I,J,L+1)=TRHR(I,J,L+1)-TRFCRL(L)*PTYPE DO 450 LR=1,3 5287. SRHRS(I,J,LR)=SRHRS(I,J,LR)+SRFHRL(LM+LR)*PTYPE 450 TRHRS(I,J,LR)=TRHRS(I,J,LR)-TRFCRL(LM+LR)*PTYPE DO 460 K=1,4 5290. SNFS(I,J,K)=SNFS(I,J,K)+SRNFLB(K+LM)*PTYPE 460 TNFS(I,J,K)=TNFS(I,J,K)+(TRNFLB(K+LM)-TRNFLB(1))*PTYPE TRNFP0(J)=TRNFP0(J)+TRNFLB(4+LM)*PTYPE TRNFP1(J)=TRNFP1(J)+TRNFLB(1+LM)*PTYPE TRINCG(I,J)=TRINCG(I,J)+TRDFLB(1)*PTYPE BTMPW(I,J)=BTMPW(I,J)+(BTEMPW-TF)*PTYPE c ALB(I,J,1)=SRNFLB(1)/(SRDFLB(1)+1.E-20) 5295. SRDAN=SRDAN+SRDFLB(1)*PTYPE SRNAN=SRNAN+SRNFLB(1)*PTYPE ALB(I,J,2)=ALB(I,J,2)+PLAVIS*PTYPE ALB(I,J,3)=ALB(I,J,3)+PLANIR*PTYPE ALB(I,J,4)=ALB(I,J,4)+ALBVIS*PTYPE ALB(I,J,5)=ALB(I,J,5)+ALBNIR*PTYPE ALB(I,J,6)=ALB(I,J,6)+SRRVIS*PTYPE ALB(I,J,7)=ALB(I,J,7)+SRRNIR*PTYPE ALB(I,J,8)=ALB(I,J,8)+SRAVIS*PTYPE ALB(I,J,9)=ALB(I,J,9)+SRANIR*PTYPE ALB1=SRNFLB(1)/(SRDFLB(1)+1.E-20) C ********** ALBJ(J,2)=PLAVIS ALBJ(J,3)=PLANIR ALBJ(J,4)=ALBVIS ALBJ(J,5)=ALBNIR ALBJ(J,6)=SRRVIS ALBJ(J,7)=SRRNIR ALBJ(J,8)=SRAVIS ALBJ(J,9)=SRANIR ALBJ(J,1)=SRNFLB(1)/(SRDFLB(1)+1.E-20) C ********* COSZ=COSZ2(I,J) do L=LM,1,-1 AJL(J,L,43)=AJL(J,L,43)-TRNFLB(L+1)*PTYPE AJL(J,L,42)=AJL(J,L,42)+(SRNFLB(L+1)*COSZ)*PTYPE enddo if(ii.eq.2)then #if ( defined CLM ) C for TEM CLM DSWSRF(j)=SRDFLB(1) DLWSRF(j)=TRSURF(J,2) DSWVIS(j)=SRDVIS DSWNIR(j)=SRDNIR C for TEM CLM #endif PLAND=PTYPE BJ(J,1)=BJ(J,1)+(S0*COSZ)*PLAND BJ(J,2)=BJ(J,2)+(SRNFLB(4+LM)*COSZ)*PLAND c BSNFS1=BSNFS1+(SRNFLB(1+LM)*COSZ)*PLAND c BJ(J,5)=BJ(J,5)+(SRNFLB(1)*COSZ/(ALB1+1.E-20))*PLAND BJ(J,5)=BJ(J,5)+(SRDFLB(1)*COSZ)*PLAND BJ(J,6)=BJ(J,6)+(SRNFLB(1)*COSZ)*PLAND BJ(J,55)=BJ(J,55)+(BTEMPW-TF)*PLAND BJ(J,67)=BJ(J,67)+TRDFLB(1)*PLAND BJ(J,70)=BJ(J,70)-(TRNFLB(4+LM)-TRNFLB(1))*PLAND BJ(J,7)=BJ(J,7)-TRNFLB(4+LM)*PLAND BJ(J,8)=BJ(J,8)-TRNFLB(1+LM)*PLAND BJ(J,3)=BJ(J,3)+(SRNFLB(1+LM)*COSZ)*PLAND BJ(J,71)=BJ(J,71)-(TRNFLB(1+LM)-TRNFLB(1))*PLAND DO 761 K=2,9 BJ(J,K+70)=BJ(J,K+70)+(S0*COSZ)*ALBJ(J,K)*PLAND 761 CONTINUE else if(ii.eq.1)then POCEAN=PTYPE AJ(J,1)=AJ(J,1)+(S0*COSZ)*POCEAN AJ(J,2)=AJ(J,2)+(SRNFLB(4+LM)*COSZ)*POCEAN AJ(J,5)=AJ(J,5)+(SRDFLB(1)*COSZ)*POCEAN AJ(J,6)=AJ(J,6)+(SRNFLB(1)*COSZ)*POCEAN AJ(J,55)=AJ(J,55)+(BTEMPW-TF)*POCEAN AJ(J,67)=AJ(J,67)+TRDFLB(1)*POCEAN AJ(J,70)=AJ(J,70)-(TRNFLB(4+LM)-TRNFLB(1))*POCEAN AJ(J,7)=AJ(J,7)-TRNFLB(4+LM)*POCEAN AJ(J,8)=AJ(J,8)-TRNFLB(1+LM)*POCEAN AJ(J,3)=AJ(J,3)+(SRNFLB(1+LM)*COSZ)*POCEAN AJ(J,71)=AJ(J,71)-(TRNFLB(1+LM)-TRNFLB(1))*POCEAN #if ( defined OCEAN_3D ) solarinc_ocean(J)=solarinc_ocean(J)+SRDFLB(1)*COSZ solarnet_ocean(J)=solarnet_ocean(J)+SRNFLB(1)*COSZ navrado(j)=navrado(j)+1 #endif C DO K=2,9 AJ(J,K+70)=AJ(J,K+70)+(S0*COSZ)*ALBJ(J,K)*POCEAN END DO C else POICE=PTYPE CJ(J,1)=CJ(J,1)+(S0*COSZ)*POICE CJ(J,2)=CJ(J,2)+(SRNFLB(4+LM)*COSZ)*POICE CJ(J,5)=CJ(J,5)+(SRDFLB(1)*COSZ)*POICE CJ(J,6)=CJ(J,6)+(SRNFLB(1)*COSZ)*POICE CJ(J,55)=CJ(J,55)+(BTEMPW-TF)*POICE CJ(J,67)=CJ(J,67)+TRDFLB(1)*POICE CJ(J,70)=CJ(J,70)-(TRNFLB(4+LM)-TRNFLB(1))*POICE CJ(J,7)=CJ(J,7)-TRNFLB(4+LM)*POICE CJ(J,8)=CJ(J,8)-TRNFLB(1+LM)*POICE CJ(J,3)=CJ(J,3)+(SRNFLB(1+LM)*COSZ)*POICE CJ(J,71)=CJ(J,71)-(TRNFLB(1+LM)-TRNFLB(1))*POICE #if ( defined OCEAN_3D ) solarinc_ice(J)=solarinc_ice(J)+SRDFLB(1)*COSZ solarnet_ice(J)=solarnet_ice(J)+SRNFLB(1)*COSZ navrad(j)=navrad(j)+1 #endif C DO K=2,9 CJ(J,K+70)=CJ(J,K+70)+(S0*COSZ)*ALBJ(J,K)*POICE END DO endif if(CLEAR(J).eq.0)then PLAND=FDATA(I,J,2) PWATER=1.-PLAND POICE=ODATA(I,J,2)*(1.-PLAND) POCEAN=(1.-PLAND)-POICE if(POCEAN.LE.1.E-5)then POCEAN=0. POICE=PWATER endif PLICE=FDATA(I,J,3)*PLAND PEARTH=PLAND-PLICE if(ii.eq.1)then PTYPE=POCEAN POICE=0. POCEAN=1. PLAND=0. PEARTH=0. PLICE=0. else if(ii.eq.3)then PTYPE=POICE POICE=1. POCEAN=0. PLAND=0. PEARTH=0. PLICE=0. else PTYPE=PLAND POCEAN=0. POICE=0. PWATER=0. PLICE=FDATA(I,J,3) PEARTH=1.-PLICE PLAND=1. endif COSZ=COSZA(I,J) if(STRARFOR)then FGOLDU(1)=1.0 elseif(CO2FOR)then FULGAS(2)=CO2F elseif(S0FOR)then c print *,'For S0FOR ',S0X0,CFS0X,S0X S0=S0X0/CFS0X*1367./RSDIST c print *,'S0 for forcing calculation=',S0 elseif(FORBC)then FBC=0.0 else CSS=0. CMC=0. DEPTH=0. LTOP=0. do 1210 L=1,LM RTAU(L)=0. TOTCLD(L)=0. 1210 continue endif 568 continue CALL RCOMPX endif SRHRCL(J)=SRNFLB(1) TRHRCL(J)=-TRNFLB(1) ALBCL(J)=SRNFLB(1)/(SRDFLB(1)+1.e-20) SNP1CL(J)=SRNFLB(LM+1) SNP0CL(J)=SRNFLB(LM+4) TRINCL(J)=TRDFLB(1) TRP0CL(J)=TRNFLB(LM+4) TRP1CL(J)=TRNFLB(LM+1) COSZ=COSZ2(I,J) do L=LM,1,-1 AJL(J,L,46)=AJL(J,L,46)-TRNFLB(L+1)*PTYPE AJL(J,L,45)=AJL(J,L,45)+(SRNFLB(L+1)*COSZ)*PTYPE enddo C ******* NCLR(J)=NCLR(J)+1 SRHE5=SRHRCL(J)*COSZ/(ALBCL(J)+1.E-20) if(ii.eq.1)then POCEAN=PTYPE AJCLR(J,1)=AJCLR(J,1)+(S0*COSZ)*POCEAN AJCLR(J,2)=AJCLR(J,2)+(SNP0CL(J)*COSZ)*POCEAN AJCLR(J,4)=AJCLR(J,4)+(SRHRCL(J)*COSZ)*POCEAN AJCLR(J,5)=AJCLR(J,5)+SRHE5*POCEAN AJCLR(J,6)=AJCLR(J,6)+TRINCL(J)*POCEAN AJCLR(J,8)=AJCLR(J,8)-TRP0CL(J)*POCEAN AJCLR(J,9)=AJCLR(J,9)-TRP1CL(J)*POCEAN AJCLR(J,3)=AJCLR(J,3)+(SNP1CL(J)*COSZ)*POCEAN AJCLR(J,7)=AJCLR(J,7)+TRHRCL(J)*POCEAN else if(ii.eq.2)then PLAND=PTYPE BJCLR(J,1)=BJCLR(J,1)+(S0*COSZ)*PLAND BJCLR(J,2)=BJCLR(J,2)+(SNP0CL(J)*COSZ)*PLAND BJCLR(J,4)=BJCLR(J,4)+(SRHRCL(J)*COSZ)*PLAND BJCLR(J,5)=BJCLR(J,5)+SRHE5*PLAND BJCLR(J,6)=BJCLR(J,6)+TRINCL(J)*PLAND BJCLR(J,8)=BJCLR(J,8)-TRP0CL(J)*PLAND BJCLR(J,9)=BJCLR(J,9)-TRP1CL(J)*PLAND BJCLR(J,3)=BJCLR(J,3)+(SNP1CL(J)*COSZ)*PLAND BJCLR(J,7)=BJCLR(J,7)+TRHRCL(J)*PLAND else POICE=PTYPE CJCLR(J,1)=CJCLR(J,1)+(S0*COSZ)*POICE CJCLR(J,2)=CJCLR(J,2)+(SNP0CL(J)*COSZ)*POICE CJCLR(J,4)=CJCLR(J,4)+(SRHRCL(J)*COSZ)*POICE CJCLR(J,5)=CJCLR(J,5)+SRHE5*POICE CJCLR(J,6)=CJCLR(J,6)+TRINCL(J)*POICE CJCLR(J,8)=CJCLR(J,8)-TRP0CL(J)*POICE CJCLR(J,9)=CJCLR(J,9)-TRP1CL(J)*POICE CJCLR(J,3)=CJCLR(J,3)+(SNP1CL(J)*COSZ)*POICE CJCLR(J,7)=CJCLR(J,7)+TRHRCL(J)*POICE endif C ********* 499 continue ALB(I,J,1)=SRNAN/(SRDAN+1.E-20) 500 IM1=I 5304. C**** 5305. C**** END OF MAIN LOOP FOR I INDEX 5306. C**** 5307. 600 CONTINUE 5345. C**** 5346. C**** END OF MAIN LOOP FOR J INDEX 5347. C**** 5348. C**** ACCUMULATE THE RADIATION DIAGNOSTICS 5394. C**** 5395. 700 DO 780 J=1,JM 5396. DXYPJ=DXYP(J) 5397. IMAX=IM 5398. IF(J.EQ.1.OR.J.EQ.JM) IMAX=1 5399. DO 720 L=1,LM 5400. ASRHR=0. 5401. ATRHR=0. 5402. DO 710 I=1,IMAX 5403. ASRHR=ASRHR+SRHR(I,J,L+1)*COSZ2(I,J) 5404. 710 ATRHR=ATRHR+TRHR(I,J,L+1) 5405. AJL(J,L,9)=AJL(J,L,9)+ASRHR 5406. 720 AJL(J,L,10)=AJL(J,L,10)+ATRHR 5407. ASNFS1=0. 5408. BSNFS1=0. 5409. CSNFS1=0. 5410. ATNFS1=0. 5411. BTNFS1=0. 5412. CTNFS1=0. 5413. DO 770 I=1,IMAX 5414. SP=P(I,J) 5415. COSZ=COSZ2(I,J) 5416. PLAND=FDATA(I,J,2) 5417. PWATER=1.-PLAND POICE=ODATA(I,J,2)*(1.-PLAND) 5418. POCEAN=(1.-PLAND)-POICE 5419. if(POCEAN.LE.1.E-5)then POCEAN=0. POICE=PWATER endif JR=J DO 740 LR=1,3 5421. ASJL(J,LR,3)=ASJL(J,LR,3)+SRHRS(I,J,LR)*COSZ 5422. 740 ASJL(J,LR,4)=ASJL(J,LR,4)+TRHRS(I,J,LR) 5423. DJ(JR,1)=DJ(JR,1)+(S0*COSZ)*DXYPJ 5440. DJ(JR,2)=DJ(JR,2)+(SNFS(I,J,4)*COSZ)*DXYPJ 5444. DJ(JR,3)=DJ(JR,3)+(SNFS(I,J,1)*COSZ)*DXYPJ 5448. DJ(JR,5)=DJ(JR,5)+(SRHR(I,J,1)*COSZ/(ALB(I,J,1)+1.E-20))*DXYPJ 5452. DJ(JR,6)=DJ(JR,6)+(SRHR(I,J,1)*COSZ)*DXYPJ 5456. DJ(JR,55)=DJ(JR,55)+BTMPW(I,J)*DXYPJ 5460. DJ(JR,67)=DJ(JR,67)+TRINCG(I,J)*DXYPJ 5464. DJ(JR,70)=DJ(JR,70)-TNFS(I,J,4)*DXYPJ 5468. DJ(JR,71)=DJ(JR,71)-TNFS(I,J,1)*DXYPJ 5472. 770 CONTINUE 5485. 780 CONTINUE 5492. C**** 5504. C**** UPDATE THE TEMPERATURES BY RADIATION 5505. C**** 5506. 800 DO 820 J=1,JM 5507. IMAX=IM 5508. IF(J.EQ.1.OR.J.EQ.JM) IMAX=1 5509. DO 820 LR=1,3 5510. DO 820 I=1,IMAX 5511. 820 RQT(I,J,LR)=RQT(I,J,LR)+(SRHRS(I,J,LR)*COSZ2(I,J) 5512. * +TRHRS(I,J,LR))*COE(LR+LM) 5513. 840 DO 860 J=1,JM 5514. #if ( defined HR_DATA ) dswhr(j)=DSWSRF(j)*COSZ1(1,j) dlwhr(j)=DLWSRF(j) #endif #if ( defined CLM ) dsw4clm(j)=DSWSRF(j)*COSZ1(1,j) dlw4clm(j)=DLWSRF(j) swinr4clm(j)=DSWNIR(j)*COSZ1(1,j) swvis4clm(j)=DSWVIS(j)*COSZ1(1,j) c For TEM swtd4tem(j)=swtd4tem(j)+S0*COSZ1(1,j) swsd4tem(j)=swsd4tem(j)+DSWSRF(j)*COSZ1(1,j) nradd4tem(j)=nradd4tem(j)+1 #endif IMAX=IM 5515. IF(J.EQ.1.OR.J.EQ.JM) IMAX=1 5516. if(HPRNT)then if(J.eq.1)then print *,' radia TAU=',TAU print *,' Before 860' print *,(T(1,1,L),L=1,LM) endif endif DO 860 L=1,LM 5517. DO 860 I=1,IMAX 5518. 860 T(I,J,L)=T(I,J,L)+(SRHR(I,J,L+1)*COSZ1(I,J)+TRHR(I,J,L+1)) 5519. * *COE(L)/(P(I,J)*PK(I,J,L)) 5520. if(HPRNT)then print *,' radia TAU=',TAU print *,' after 860' print 'B66',T(1,1,1) print *,'COSZ1(1,1)',COSZ1(1,1),' COE(1)=',COE(1) print *,'SRHR' print *,(SRHR(1,1,L+1),L=1,LM) print *,'TRHR' print *,(TRHR(1,1,L+1),L=1,LM) print *,'T' print *,(T(1,1,L),L=1,LM) endif c if(ncallclm.ge.9)stop RETURN 5521. END 5522.