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Revision 1.7 - (show annotations) (download)
Thu Aug 2 15:48:07 2007 UTC (17 years, 11 months ago) by jscott
Branch: MAIN
Changes since 1.6: +4 -2 lines 
fix problem with double conversion that was screwing up atmos clock
1 c source 2007 sokolov users 76203 Apr 25 15:29 atmosphere.F
2
3 #include "ctrparam.h"
4
5 ! ==========================================================
6 !
7 ! Atmosphere.F: Former main program of the MIT Global Climate and
8 ! Biogeochemistry Model.
9 !
10 ! ----------------------------------------------------------
11 !
12 ! Repacking Note: This version is combined with main.f of
13 ! several originally separated model versions such as
14 ! CliChem 3.0, CliChemNem, as well as MODEL24x11.
15 !
16 ! The chemistry module, ocean CO2 module,
17 ! and TEM module are all controlled by cpp now.
18 !
19 ! Chien Wang
20 ! MIT Joint Program for the Science and Policy
21 ! of Global Change
22 !
23 ! ----------------------------------------------------------
24 !
25 ! Revision History:
26 !
27 ! When Who What
28 ! ---- ---------- -------
29 ! 073100 Chien Wang Created from CliChem3.0 and MODEL24x11
30 ! 100500 Andrei Converted to subroutine. When called first
31 ! time does only initialization.
32 ! Creates monthly data for TEM
33 !
34 ! ==========================================================
35
36
37 SUBROUTINE ATMOSPHERE(DTATM,mndriver)
38 C**** MD2G04 BD2G04 MD2G04 01/02/93 0.1
39 C**** OPT(3) 0.2
40 C**** 0.3
41 C**** Dynamics and physics programs for 2-D model. 0.4
42 C**** Like D2G04 but run on work station. 0.5
43
44 #include "BD2G04.COM" 1.
45 #include "ODIFF.COM"
46 #include "run.COM" 1.
47
48 #include "chem_para"
49 #include "chem_com"
50
51 #if ( defined CPL_CHEM )
52 !
53 #include "chem_tmp"
54 integer hrcnt, cnt3hr(8) ! for ozone impact
55 real sfc3hro3(nlat,8)
56 creal*4 sfc3hro3(nlat,8)
57 !
58 #endif
59
60 COMMON/INTA/COE1(01,01,01),COE2(01,01,01) 1.1
61 c DIMENSION ACO(36,01),BSI(36,01),CCO(36,01),DSI(36,01) 1.2
62 COMMON/SPEC1/ 1.3
63 * XA(IM0,JM0),XB(IM0,JM0),YA(IM0,JM0),YB(IM0,JM0),ZA(IM0,JM0)
64 &,ZB(IM0,JM0) 1.4
65 COMMON/SPEC2/KM,KINC,COEK,C3LAND(IO0,JM0),C3OICE(IO0,JM0) 1.5
66 * ,C3LICE(IO0,JM0),WMGE(IO0,JM0),TSSFC(1,JM0,4) 1.6
67 COMMON/EPARA/VTH(JM0,LM0),WTH(JM0,LM0),VU(JM0,LM0),VV(JM0,LM0)
68 &,DQSDT(JM0,LM0) 1.7
69 * ,DWV(JM0),PHIT(JM0,LM0),TPRIM2(JM0,LM0),WU(JM0,LM0),CKS,CKN 1.8
70 * ,WQ(JM0,LM0),VQ(JM0,LM0),MRCHT 1.9
71 COMMON U,V,T,P,Q 2.
72 COMMON/WORK1/WORKX(IM0,JM0,LM0),UT(IM0,JM0,LM0),VT(IM0,JM0,LM0), 3.
73 * TT(IM0,JM0,LM0),PT(IM0,JM0),QT(IM0,JM0,LM0) 4.
74 COMMON/WORK2/UX(IM0,JM0,LM0),VX(IM0,JM0,LM0),TX(IM0,JM0,LM0)
75 &,PX(IM0,JM0) 5.
76 COMMON/OLDZO/ZMLOLD(IO0,JM0)
77 C COMMON/KEYS/KEYNR(42,50) 8.
78 CHARACTER C*4,CYEAR*4,CMMND*80 8.1
79 DIMENSION C(39),JC(100),RC(161) 8.2
80 EQUIVALENCE (JC(1),IM),(C(1),XLABEL(1),LABEL1),(RC(1),TAU) 8.3
81 CHARACTER*8 LABSSW,LABEL1,OFFSSW/'XXXXXXXX'/ 8.4
82 LOGICAL EVENT,wr25,HPRNT,TRANSR,LHORDIF 9.
83 & ,CONTRR,OBSFOR,FIRST,NOCLM
84 common/conprn/HPRNT,JPR,LPR
85 common/wrcom/wr25,TRANSR,CONTRR,OBSFOR
86 COMMON/CWMG/WMGEA(JM0),NWMGEA(JM0),RIGA(JM0),DTAV(JM0),DQAV(JM0),
87 *Z0AV(JM0),WSAV(JM0),WS0AV(JM0),TAUAV(JM0)
88 COMMON/OCN/TG3M(1,JM0,12),RTGO(1,JM0,lmo),STG3(1,JM0),DTG3(1,JM0)
89 common/SURRAD/TRSURF(JM0,4),SRSURF(JM0,4)
90 dimension RTGOAV(JM0,lmo)
91 common/tprmtg/tprmg(JM0),ntprmg(JM0)
92 common/aexpc/AEXP,ISTRT1,ISTRTCHEM,LYEAREM
93 common/mixlr/Z1OAV(JM0),NZ1OAV(JM0)
94 common/flxio/FLIO(JM0),NFLIO(JM0)
95 common/surps/srps(JM0+3),nsrps
96 c character *19 buf
97 c character *8 buf1
98 character *120 file1,file2,plotfl,nwrfl,qffile,clfile
99 CHARACTER*4 AMONTH(12),JMONTHPR
100 common/files/file1,file2,flotfl,nwrfl,qffile,clfile
101 common/PRNT1/NCOMP
102 common/Dscale/DWAV0(JM0)
103 COMMON/CO2TRND/ALFFOR,CO2TR
104 COMMON/FRMIC/ FRMDICE(JM0)
105 common/ BACKGRGHG/GHGBGR(5)
106 DATA AMONTH/'JAN','FEB','MAR','APR','MAY','JUNE','JULY'
107 & ,'AUG','SEP','OCT','NOV','DEC'/
108 dimension fluxnep(jm0)
109 logical odifcarbon
110
111 #if ( defined CLM )
112 # include "CLM.h"
113 # if ( defined CPL_TEM )
114 C For TEM
115 # include "TEM.h"
116 # endif
117 #endif
118
119 #if ( defined CPL_OCEANCO2 )
120 #include "OCM.h"
121 common /Garyflux/pC_atm(jm0),wind_amp,fluxco2(jm0)
122 # if ( defined ML_2D )
123 common/Garyclim/tggary(jm0),wsgary(jm0),areaml(jm0),arsrf(jm0)
124 common/Garydiff/depthml(jm0),edzcar(jm0),dzg(lmo),dzog(lmo-1),
125 &Rco2(jm0,lmo),edohd(lmo),zg(lmo),focean(jm0)
126 common /Garychem/Hg(jm0)
127 common/qfl/QFLUX(JM0,0:13),ZOAV(JM0),QFLUXT(JM0)
128 common /Garyvdif/iyearocm,vdfocm,acvdfc
129 common /Garyvlog/odifcarbon,ocarcont
130 common /Garykvct/cfkvct,edzcart(jm0)
131 # endif
132 #endif
133
134 INTEGER dtatm, mndriver !routine arguments jrs
135
136 #if ( defined OCEAN_3D || defined ML_2D )
137 #include "AGRID.h"
138 Cjrs elimated COM file/moved elsewhere#include "HRD4OCN.COM"
139 dimension oimeltt(jm0),dhdtav(jm0),devdtav(jm0)
140 #endif
141
142 C **** CLEAR SKY
143 common/clrsk/CLEAR(JM0),NCLR(JM0),AJCLR(JM0,12),BJCLR(JM0,12),
144 * CJCLR(JM0,12)
145 ! common/TSUR/TSURFC(JM0,0:13),TSURFT(JM0),TSURFD(JM0),DTSURF(JM0)
146 #include "TSRF.COM"
147 real TSURFW(JM0),TLANDW(JM0)
148 integer CLEAR
149
150 common /ATCO2/atm_co2(jm0)
151
152 #if ( defined CPL_NEM )
153 C For Emission
154 c === 031097
155 real ECH4COR(JM0),ECH4PY(JM0,12), ECH4OUT(JM0),EPJT(JM0)
156 &,ECH4CTR(JM0)
157 real EN2OCOR(JM0),EN2OPY(JM0,12), EN2OOUT(JM0),EPJTN2O(JM0)
158 &,EN2OCTR(JM0)
159 c ECH4CHIEN and EN2OCHIEN are used in chemistry model
160 common/EMFORCHIEN/ECH4CHIEN(JM0),EN2OCHIEN(JM0)
161 C For Emission
162 #endif
163 dimension NDAYMN(12)
164 data NDAYMN /31,28,31,30,31,30,31,31,30,31,30,31/
165 INTEGER JDOFM(13)
166 DATA JDOFM/0,31,59,90,120,151,181,212,243,273,304,334,365/
167 DATA FIRST/.TRUE./
168 SAVE
169
170 C AJCLR
171 C 1 SW INC AT P0 RD (AJ(1))
172 C 2 SW ABS BELOW P0 RD (AJ(2))
173 C 3 SW ABS BELOW P1 RD (AJ(3))
174 C 4 SW ABS AT Z0 RD (AJ(6))
175 C 5 SW INC AT Z0 RD (AJ(5))
176 C 6 LW INC AT Z0 RD (AJ(67))
177 C 7 NET LW AT Z0 SF (AJ(9))
178 C 8 NET LW AT P0 RD (AJ(7))
179 C 9 NET LW AT P1 RD (AJ(8))
180 C 10 NET RAD AT P0 DG (AJ(10))
181 C 11 NET RAD AT P1 DG (AJ(11))
182 C 12 NET RAD AT Z0 DG (AJ(12))
183 C **** CLEAR SKY
184 INTFX(XTAU)=INT(XTAU*XINT+.5) 10.
185 EVENT(XTAU)=MOD(ITAU,INTFX(XTAU)).LT.IDTHR 11.
186
187 !
188 ! --- assign input and output files
189 ! Note: Due to historical reasons, no all files are
190 ! assigned here - in case you want to search
191 ! something use
192 ! grep -i "needed characters" *.F
193 !
194 ! You have my sympathy.
195 !
196 ! Chien 080400
197 !
198
199 !#include "assign.inc"
200 c
201 if(FIRST) then
202 c
203 CALL CLOCKS (MNOW) 12.
204 C CALL ERRSET (206,1,0,0,0,301) 13.
205 C CALL ERRSET (208,256,-1) 14.
206 MBEGIN=MNOW 14.1
207 c CALL HARMO(36,1,24,ACO,BSI,CCO,DSI,1) 14.5
208 IPFLAG=0 15.
209 C CALL ENQJOB 16.
210 CALL INPUT 17.
211
212 #if ( defined CPL_CHEM )
213 !
214 ! --- Chemistry model
215 ! --- Set year and month index:
216 !
217 myyear = 1 !year from starting point
218 myyear = JYEAR-1976 !year from starting point
219 ! myyear = JYEAR-1891 !year from starting point
220 print *,'Emissioms for ',nchemyr,' year'
221 myyearlast = min(LYEAREM-1976,nchemyr) !last year of emission
222 ! myyearlast = min(LYEAREM-1891,nchemyr) !last year of emission
223 ! myyear = min(myyear,nchemyr)
224 myyear = min(myyear,myyearlast)
225 mymonth = 1 !month
226
227 ihaha = 1
228 ievenodd = 0 ! even hour 0
229 ! odd hour 1
230
231 call chembudget (p)
232 !
233 ! --- Set cfcnsf = 0.0
234 !
235 do k=1,nlev
236 cfcnsf(k) = 0.0
237 enddo
238 print *,'First year of emissions ', myyear
239 ! print *,'Emission will be fixed at year ',LYEAREM
240 print *,'Emission will be fixed at year ',1976+myyearlast
241 ! print *,'Emission will be fixed at year ',1891+myyearlast
242 !
243 #endif
244
245 C
246 KDISK0=500+KDISK
247 ndaa=3
248 c LHORDIF=.false.
249 LHORDIF=.true.
250 if(.not.LHORDIF)print *,' NO HOR. DIFFUSION for Q'
251 if(LHORDIF)print *,' HOR. DIFFUSION for Q after COND'
252 print *,' RADIATION EVERY ',NRAD/NDYN,' HOURS'
253
254 odifcarbon=.false.
255 #if ( defined CPL_OCEANCO2 && defined ML_2D )
256 odifcarbon=.true.
257 wind_amp=1.
258 dtco2=3600.*24.
259 c ncallgary=0
260 do j=1,jm
261 areaml(j)=dxyp(j)*(1-FDATA(1,J,2))
262 focean(j)=(1-FDATA(1,J,2))
263 DEPTHML(j)=ZOAV(j)
264 end do ! j
265 print *,' RCO2'
266 ! print 5001,((Rco2(j,k),j=1,jm),k=1,LMO)
267 print 5001,((Rco2(j,k)*1.e2,j=1,jm),k=1,LMO)
268 dzog(1)=10./SQRT(1.7010587)
269 dzg(2)=10.
270 do l=2,lmo-1
271 dzog(L)=dzog(L-1)*1.7010587
272 dzg(L+1)=dzg(L)*1.7010587
273 end do
274 zg(1)=50.
275 dzg(1)=100.
276 do l=2,lmo
277 zg(l)=zg(l-1)+0.5*(dzg(l-1)+dzg(l))
278 end do
279 do l=1,lmo
280 c edohd(l)=2.5e4/(zg(l)/zg(1))**1.0
281 C New coefficients for horizontal diffusion 11/16/00
282 edohd(l)=1.55e4-9.231e3*(atan((zg(l)-300)/50))
283 end do
284 #endif
285
286
287 #if ( defined CPL_CHEM )
288 !
289 ! --- Initialization of chemistry model:
290 !
291 c call cheminit(ISTRT1,T,q)
292 c 11/30/2000 ISTRTCHEM for restart of chemistry model
293 call cheminit(ISTRTCHEM,T,q)
294 c print *,'H2SO4 after cheminit ',h2so4(1,33,1)
295
296
297 !
298 ! --- tmp output
299 !
300 copen(124,file='OUTPUT/hro3',form='unformatted',
301 c & status='unknown')
302 hrcnt = 1
303 cnt3hr(:) = 0
304 sfc3hro3(:,:) = 0.0
305 !
306 #endif
307
308 print *,' IRAND=',IRAND
309 print *,' NCNDS=',NCNDS
310 print *,' after INPUT MRCHT=',MRCHT
311 JDAY00=JDAY-1
312 AEXP4=AEXP
313 TAU4=TAU
314 print *,' ISTRT1=',ISTRT1
315 if(ISTART.eq.2.or.ISTRT1.eq.0)then
316 nwr=1
317 WRITE (546) AEXP4,TAU4,XLABEL
318 write(547)AEXP,nwr
319 elseif(ISTART.eq.10)then
320 read(547)AEXPX,nwr
321 print *,' NWR=',nwr
322 if(abs(AEXPX-AEXP).gt.0.05)then
323 print *,' DISAGREEMENT BETWEEN AEXPX AND AEXP FILE 47'
324 print *,' AEXPX=',AEXPX,' AEXP=',AEXP
325 stop
326 endif
327 READ (546) AEXP4
328 if(abs(AEXP4-AEXP).gt.0.05)then
329 print *,' DISAGREEMENT BETWEEN AEXP4 AND AEXP FILE 46'
330 print *,' AEXP4=',AEXP4,' AEXP=',AEXP
331 stop
332 endif
333 C***
334 do 245 nr=1,nwr-1
335 READ (546)
336 245 continue
337 endif
338 WRITE(503) OFFSSW 17.1
339 REWIND 503 17.2
340 c CALL FRTR0(IO) 18.
341 KBGN=KINC+1 18.5
342 KM2=KM*2-1 18.51
343 KM3=KM2 18.52
344 KB1=3 18.53
345 KB2=5 18.54
346 KB3=5 18.55
347 IS=IM 18.56
348 IF(KM.EQ.1) IS=1 18.57
349 FIO=IO 18.58
350 JMM2=JM-2 18.59
351 HR24=24. 18.6
352 HR12=12. 18.61
353 MSTART=MNOW+MDYN+MCNDS+MRAD+MSURF+MDIAG+MELSE 19.
354 LMT3P1=LM*3+1 20.
355 C**** INITIALIZE TIME PARAMETERS 21.
356 DTHR=DT/3600. 22.
357 IDTHR=INTFX(DTHR) 23.
358 DTFS=DT*2./3. 24.
359 DTLF=2.*DT 25.
360 NDYNO=MOD(NDYN,2) 26.
361 I24=INTFX(24.) 27.
362 NSTEP0=.5+TAUI/DTHR 28.
363 NSTEP=INT(.5+TAU/DTHR)-NSTEP0 29.
364 NSTEP1=NSTEP 29.5
365 NSTEP2=NSTEP 29.6
366 MRCHT=0. 29.7
367 ITAU=(NSTEP+NSTEP0)*IDTHR 30.
368 cjrs changed to dfloat 8/2/07
369 TAU=DFLOAT(ITAU)/XINT 31.
370 IDAY=1+ITAU/I24 32.
371 TOFDAY=(ITAU-(IDAY-1)*I24)/XINT 33.
372 ! if(ISTART.eq.2.or.ISTRT1.eq.0.and..not.CONTRR)then
373 ! do 458 j=1,JM
374 ! TSURFD(j)=0.
375 ! TSURFT(j)=0.
376 ! 458 continue
377 ! endif
378 if(JDATE.eq.100)then
379 print *,JDATE,JMONTH,JYEAR
380 print *,' main before daily0'
381 print *,' T1 ocean'
382 print 5001,(ODATA(1,j,1),j=1,JM0)
383 print *,' T2 ocean'
384 print 5001,(ODATA(1,j,4),j=1,JM0)
385 print *,' T3 ocean'
386 print 5001,(ODATA(1,j,5),j=1,JM0)
387 print *,' sea ice'
388 print 5002,(ODATA(1,j,2),j=1,JM0)
389 endif
390 CALL DAILY_NEW0 34.
391 print *,' Main after DAILYNEW0 JYEAR=',JYEAR
392 print *,"DT2MGL"
393 print *,DT2MGL
394 print *,"DT2MLD"
395 print *,DT2MLD
396 #if( !defined OCEAN_3D&& !defined ML_2D )
397 CALL DAILY_OCEAN
398 print *,' AFTER DAILY_OCEAN IDAY=',IDAY,' IYEAR=',IYEAR
399 print *,' JYEAR=',JYEAR,' JDAY=',JDAY
400 print *,' JDATE=',JDATE,' JMONTH=',JMONTH
401 #endif
402 if(JDATE.eq.100)then
403 print *,JDATE,JMONTH,JYEAR
404 print *,' main after daily0'
405 print *,' T1 ocean'
406 print 5001,(ODATA(1,j,1),j=1,JM0)
407 print *,' T2 ocean'
408 print 5001,(ODATA(1,j,4),j=1,JM0)
409 print *,' T3 ocean'
410 print 5001,(ODATA(1,j,5),j=1,JM0)
411 print *,' sea ice'
412 print 5002,(ODATA(1,j,2),j=1,JM0)
413 endif
414 c print *,' Z12O'
415 c print *,(Z12O(1,j),j=1,JM0)
416 c99 CONTINUE 34.993
417 CALL CLOCKS (MLAST) 35.
418 MINC=MNOW-MLAST 36.
419 MELSE=MELSE+MINC 37.
420 PERCNT=100.*MELSE/(MSTART-MLAST+1.E-5) 38.
421 c WRITE (6,901) IDAY,TOFDAY,JDATE,JMONTH,MINC,MELSE,PERCNT,TAU 39.
422 DOPK=1. 40.
423 MODD5K=1000 41.
424 IF(TAU.GE.TAUE) GO TO 820 42.
425 HPRNT=.TRUE.
426 HPRNT=.FALSE.
427 JPR=7
428 JPR=1
429 JPR=14
430 LPR=1
431 print *,' MAIN MRCHT=',MRCHT
432 c
433 c print *,' TAUE=',TAUE
434 TAUEM=TAUE
435 FIRST=.FALSE.
436 C
437 c TAU for coupler
438 c
439 TAUATM=TAU
440 MONTHATM=JMONTH
441 JDATEATM=JDATE
442 JYEARATM=JYEAR
443 C
444 #if ( defined CPL_OCEANCO2 )
445 do j=1,jm
446 fluxco2(j)=0.0
447 enddo
448 #endif
449 #if ( defined CPL_CHEM) && ( defined CPL_TEM )
450 C For TEM
451 if(ISTRT1.eq.0) then
452 c New run
453 c Reading from flin_nep
454 read(537)adupt,temco2
455 else
456 c Restart of the run
457 c Reading from last_nep
458 read(367)adupt,temco2
459 ! & ,temch4,temn2o
460 rewind 367
461 endif
462 !
463 ! adupt= 1.459814341652516
464 ! adupt= 0.9078891180588442
465 ! adupt= 0.25
466 ! adupt= -0.1123070421398009
467 !
468 ! adupt= adupt+0.9 ! for vs23
469
470 aduptd=adupt/(365.*JM)
471 temnepgl=0.0
472 do j=1,jm
473 temnepgl=temnepgl+temco2(j)
474 enddo
475 print *,'ADNEP=',adupt
476 print *,'Initial NEP=',adupt+temnepgl*1.e-3
477 temup0=0.0
478 #endif
479 #if (!defined OCEAN_3D && !defined ML_2D)
480 if(TRANSR)then
481 if(LMO.eq.11) then
482 call ODIFS
483 elseif(LMO.eq.12) then
484 call ODIFS12
485 else
486 Print *,' Wrong LMO',LMO
487 stop
488 endif
489 endif
490 #endif
491 !#if (defined PREDICTED_GASES)
492 #if (defined CPL_TEM || defined CPL_OCEANCO2 )
493 if(OBSFOR) then
494 call obsco2(iyear,imontha)
495 mnobco2=imonth
496 endif
497 #endif
498 !#endif
499 CJRS removed below from ocean_3d
500 #ifdef ML_2D
501 do j=1,jm
502 do i=1,io
503 CLAND4OCEAN(i,j)= C3LAND(I,J)
504 enddo
505 enddo
506 IDAYM=IDAY
507 JDAYM=JDAY
508 JDATEM=JDATE
509 JMONTHM=JMONTH
510 JYEARM=JYEAR
511 TAUML=TAU
512 TOFDAYML=TOFDAY
513 KOCEANM=KOCEAN
514 #endif
515 #if (defined OCEAN_3D || defined ML_2D)
516 do l=1,lm
517 sigfl(l)=sig(l)
518 enddo
519 print *,'SIGFL'
520 print *,sigfl
521 #endif
522 #if ( defined CPL_CHEM )
523 do j=1,jm
524 atm_co2(j)=zco2(1,j,1)
525 & *28.97296245/44.0*1.e-9
526 !ppb(m) to kg per volume base
527 & *1.e6
528 enddo
529 #else
530 if(.not.OBSFOR) then
531 CFF=1.
532 if (CO2.gt.0.0)CFF=CO2
533 do j=1,jm
534 atm_co2(j)=CFF*GHGBGR(1)
535 enddo
536 endif
537 #endif
538 #if (defined CPL_TEM || defined CPL_OCEANCO2 )
539 print *,'ATM_CO2'
540 print *,atm_co2
541 #endif
542 JDAYLAST=-1
543 ncallclm=0
544 NOCLM=.true.
545 #if ( defined CLM )
546 NOCLM=.false.
547 #endif
548 print *,' atmosphere DTATM=',DTATM
549 print *,' It is running'
550 print *,'End of atmospheric model initialization'
551 print *,' '
552 print *,' '
553 print *,' JMONTHM= ',JMONTHM
554 print *,' TOFDAYML= ',TOFDAYML
555 print *,' '
556 return
557 endif ! first
558 C**** 43.
559 C**** MAIN LOOP 44.
560 C**** 45.
561 C
562 cprint *,' atmosphere TAU=',tau
563 TAUE=TAU+DTATM
564 c HPRNT=TAU.ge.17520.0.and.TAU.lt.17545.0
565 c print *,' TAUE=',TAUE
566 #if ( defined OCEAN_3D || defined ML_2D)
567 do j=1,jm0
568 tauu(j)=0.
569 tauv(j)=0.
570 precip(j)=0.
571 evao(j)=0.
572 evai(j)=0.
573 hfluxo(j)=0.
574 hfluxi(j)=0.
575 dhfodtg(j)=0.
576 devodtg(j)=0.
577 dhfidtg(j)=0.
578 devidtg(j)=0.
579 dhfodtgeq(j)=0.
580 devodtgeq(j)=0.
581 dhfidtgeq(j)=0.
582 devidtgeq(j)=0.
583 tempr(j)=0.
584 cjrs change var name to arunoff
585 arunoff(j)=0.
586 solarinc_ice(j)=0.
587 solarnet_ice(j)=0.
588 solarinc_ocean(j)=0.
589 solarnet_ocean(j)=0.
590 Cjrs not used anymore (?) surfpr(j)=0.
591 naveo(j)=0.
592 navei(j)=0.
593 navrad(j)=0.
594 navrado(j)=0.
595 c
596 ps4ocean(j)=0.
597 do l=1,lm
598 qyz4ocean(j,l)=0.
599 tyz4ocean(j,l)=0.
600 enddo
601 c
602 enddo
603 #endif
604 #ifdef OCEAN_3D
605 C get data from atm-ocean common block
606 do j=1,jm0
607 ODATA(1,j,1)=mmsst(j)
608 ODATA(1,j,2)=mmfice(j)
609 GDATA(1,j,3)=mmtice(j)
610 GDATA(1,j,1)=mmsnowm(j)
611 ODATA(1,j,3)=mmicem(j)
612 GDATA(1,j,7)=0.5*(mmtice2(j)+mmtice1(j))
613 # ifdef CPL_OCEANCO2
614 fluxco2(j)=fluxco2(j) + dtatm*3600.*mmco2flux(j)
615 # endif
616 enddo
617 #endif
618 WLMMAX=0.0
619 C
620 100 IF(.NOT.EVENT(TAUT)) GO TO 200 46.
621 c HPRNT=TAU.ge.17520.00
622 NSTEP1=NSTEP 46.5
623 C**** WRITE RESTART INFORMATION ONTO DISK 47.
624 120 CALL RFINAL (IRAND) 48.
625 IF(NSTEP.EQ.NSTEP2) GO TO 116 48.3
626 DO 115 K=1,22 48.5
627 DO 115 J=1,JM 48.6
628 DO 115 I=2,IO 48.7
629 115 GDATA(I,J,K)=GDATA(1,J,K) 48.9
630 116 CONTINUE 48.91
631 if(wr25.and.ISTART.eq.2)then
632 print *,' main write'
633 print *,' T1 ocean'
634 print 5001,(ODATA(1,j,1),j=1,JM0)
635 print *,' T2 ocean'
636 print 5001,(ODATA(1,j,4),j=1,JM0)
637 print *,' T3 ocean'
638 print 5001,(ODATA(1,j,5),j=1,JM0)
639 REWIND KDISK0 49.
640 if(TRANSR)then
641 WRITE(KDISK0) AEXP,TAU,JC,C,RC,KEYNR,U,V,T,P,Q,ODATA,GDATA,BLDATA, 50.
642 * RQT,SRHR,TRHR,(AJ(K,1),K=1,KACC),TAU,TSSFC,CKS,CKN,WMGE,TPRIM2 51.
643 * ,MRCHT,TRSURF,SRSURF,TLANDW,TSURFW,DWAV0
644 * ,TG3M,RTGO,STG3,DTG3
645 print *,' STG3'
646 print 5001,(STG3(1,j),j=1,JM0)
647 print *,' DTG3/356'
648 print 5001,(DTG3(1,j)/365.,j=1,JM0)
649 print *,' RTGO'
650 print 5001,((RTGO(1,j,k),j=1,JM0),k=1,lmo)
651 5001 format(23f6.1)
652 5002 format(23f6.3)
653 else
654 WRITE(KDISK0) AEXP,TAU,JC,C,RC,KEYNR,U,V,T,P,Q,ODATA,GDATA,BLDATA, 50.
655 * RQT,SRHR,TRHR,(AJ(K,1),K=1,KACC),TAU,TSSFC,CKS,CKN,WMGE,TPRIM2 51.
656 * ,MRCHT,TRSURF,SRSURF,TLANDW,TSURFW,DWAV0
657 endif
658 REWIND KDISK0 52.
659 end if ! ISTART.eq.2
660 CALL CLOCKS (MNOW) 53.
661 MINC=MLAST-MNOW 54.
662 MELSE=MELSE+MINC 55.
663 PERCNT=100.*MELSE/(MSTART-MNOW+1.E-5) 56.
664 MLAST=MNOW 59.
665 C**** TEST FOR TERMINATION OF RUN 60.
666 200 READ (503,END=210) LABSSW 61.
667 c HPRNT=TAU.gt.45.0.and.TAU.lt.60.0
668 c HPRNT=TAU.gt.470.0.and.TAU.lt.550.0
669 NCOMP=0
670 210 REWIND 503 61.1
671 IF(LABSSW.EQ.LABEL1) KSS6=1 61.2
672 IF(KSS6.EQ.1) GO TO 800 62.
673 IF(TAU+.06125.GE.TAUE) GO TO 820 63.
674 JDAY00=JDAY
675 C**** IF TIME TO ZERO OUT DIAGNOSTIC ACCUMULATING ARRAYS, DO SO 64.
676 C**** (NORMALLY DONE AT THE BEGINNING OF A MONTH) 65.
677 IF (TAU.EQ.TAUI) GO TO 260 66.
678 IF(.NOT.EVENT(24.)) GO TO 290 67.
679 DO 250 K=1,13 68.
680 IF(JDAY.EQ.NDZERO(K)) GO TO 260 69.
681 250 CONTINUE 70.
682 GO TO 290 71.
683 260 CONTINUE
684 TAU0=TAU 72.
685 IDAY0=IDAY 73.
686 TOFDY0=TOFDAY 74.
687 JDATE0=JDATE 75.
688 JMNTH0=JMONTH 76.
689 JYEAR0=JYEAR 77.
690 DO 270 I=1,12 78.
691 270 IDACC(I)=0 79.
692 NODIFS=0
693 nsrps=0.
694 DO 280 K=1,KACC 80.
695 280 AJ(K,1)=0. 81.
696 do 5280 j=1,JM
697 tprmg(j)=0.
698 ntprmg(j)=0.
699 Z1OAV(j)=0.
700 NZ1OAV(j)=0
701 NFLIO(J)=0
702 FLIO(J)=0.
703 NCLR(J)=0
704 do 5282 k=1,lmo
705 RTGOAV(j,k)=0.
706 5282 continue
707 do 5281 n=1,12
708 AJCLR(J,n)=0.
709 BJCLR(J,n)=0.
710 CJCLR(J,n)=0.
711 5281 continue
712 5280 continue
713 do 5286 j=1,jm+3
714 srps(j)=0.
715 5286 continue
716
717 c#if ( defined CPL_OCEANCO2 && defined ML_2D )
718 c call zerogary(ncallgary)
719 c call zerogary
720 c#endif
721
722 CALL DIAG9A (1) 82.
723
724 #if ( defined CPL_NEM )
725 C For Emission
726 c === 031097
727 DO 5655 MONTH=1,12
728 IF(JDAY.LE.JDOFM(MONTH+1)) GO TO 5656
729 5655 CONTINUE
730 5656 MNHTEM=MONTH-1
731 if(MNHTEM.eq.0)MNHTEM=12
732 do J=1,JM
733 c ECH4CHIEN(J)=temch4(J)/NDAYMN(MNHTEM)/1000.
734 c EN2OCHIEN(J)=temn2o(J)/NDAYMN(MNHTEM)/1000.
735
736 ECH4CHIEN(J)=temch4(J)/NDAYMN(MNHTEM)
737 EN2OCHIEN(J)=temn2o(J)/NDAYMN(MNHTEM)
738
739 enddo
740
741 C For Emission
742 #endif
743
744 290 CONTINUE 83.
745 C**** 84.
746 C**** INTEGRATE DYNAMIC TERMS 85.
747 if(HPRNT)then
748 print *,' main before comp1 1',' TAU=',TAU,JDATE,JMONTH
749 #include "PRNT.COM"
750 print *,' GDATA(1,7,5)=',GDATA(1,7,5),' GDATA(1,7,6)='
751 * ,GDATA(1,7,6)
752 endif
753 C**** 86.
754 MODD5D=MOD(NSTEP,NDA5D) 87.
755 IF(MODD5D.EQ.0) CALL DIAG5A (2,0) 88.
756 c IF(NDYNO.EQ.1) then
757 c print *,NDYNO
758 c print *,jm,im,LMT3P1
759 c endif
760 DO 310 J=1,JM 89.
761 DO 300 L=1,LMT3P1 90.
762 DO 300 I=1,IM 91.
763 UX(I,J,L)=U(I,J,L) 92.
764 300 UT(I,J,L)=U(I,J,L) 93.
765 DO 310 L=1,LM 94.
766 DO 310 I=1,IM 95.
767 310 QT(I,J,L)=Q(I,J,L) 96.
768 if(HPRNT)then
769 print *,' main before comp1 2',' TAU=',TAU
770 #include "PRNT.COM"
771 print *,' GDATA(1,7,5)=',GDATA(1,7,5),' GDATA(1,7,6)='
772 * ,GDATA(1,7,6)
773 endif
774 C**** INITIAL FORWARD STEP, QX = Q + .667*DT*F(Q) 97.
775 NS=0 98.
776 MRCH=0 99.
777 CALL COMP1 (UX,VX,TX,PX,Q,U,V,T,P,Q,DTFS,NS) 100.
778 if(HPRNT)then
779 print *,' main after comp1',' TAU=',TAU,' MRCH=',MRCH
780 #include "PRNT.COM"
781 endif
782 C
783 IF(NDYNO.EQ.1) GO TO 320 101.
784 C**** INITIAL BACKWARD STEP IS ODD, QT = QT + DT*F(QX) 102.
785 MRCH=-1 103.
786 CALL COMP1 (UT,VT,TT,PT,QT,UX,VX,TX,PX,Q,DT,NS) 104.
787 if(HPRNT)then
788 print *,' main after comp1',' TAU=',TAU,' MRCH=',MRCH
789 #include "PRNT.COM"
790 endif
791 C
792 GO TO 360 105.
793 C**** INITIAL BACKWARD STEP IS EVEN, Q = Q + DT*F(QX) 106.
794 320 NS=1 107.
795 MODD5K=MOD(NSTEP+NS-NDYN+NDA5K,NDA5K) 108.
796 MRCH=1 109.
797 CALL COMP1 (U,V,T,P,Q,UX,VX,TX,PX,QT,DT,NS) 110.
798 if(HPRNT)then
799 print *,' main after comp1',' TAU=',TAU,' MRCH=',MRCH
800 #include "PRNT.COM"
801 endif
802 C
803 CD DIAGA SHOULD BE CALLED HERE BUT THEN ARRAYS MUST BE CHANGED 111.
804 c
805 c
806 C**** ODD LEAP FROG STEP, QT = QT + 2*DT*F(Q) 112.
807 340 MRCH=-2 113.
808 CALL COMP1 (UT,VT,TT,PT,QT,U,V,T,P,Q,DTLF,NS) 114.
809 if(HPRNT)then
810 print *,' main after comp1',' TAU=',TAU,' MRCH=',MRCH
811 #include "PRNT.COM"
812 endif
813 C
814 C**** EVEN LEAP FROG STEP, Q = Q + 2*DT*F(QT) 115.
815 360 NS=NS+2 116.
816 MODD5K=MOD(NSTEP+NS-NDYN+NDA5K,NDA5K) 117.
817 MRCH=2 118.
818 CALL COMP1 (U,V,T,P,Q,UT,VT,TT,PT,QT,DTLF,NS) 119.
819 if(HPRNT)then
820 print *,' main after comp1',' TAU=',TAU,' MRCH=',MRCH
821 #include "PRNT.COM"
822 endif
823 C
824 IF(NS.LT.NDYN) GO TO 340 122.
825 c IF(MOD(NSTEP+NS-NDYN+NDAA,NDAA).LT.MRCH) THEN 120.
826 CALL DIAGA (UT,VT,TT,PT,QT,NOCLM) 121.
827 if(HPRNT)then
828 print *,' main after DIAGA',' TAU=',TAU,' MRCH=',MRCH
829 #include "PRNT.COM"
830 endif
831 c ENDIF
832 c IF(NS.LT.NDYN) GO TO 340 122.
833 DOPK=1. 123.
834 CALL CLOCKS (MNOW) 124.
835 MINC=MLAST-MNOW 125.
836 MDYN=MDYN+MINC 126.
837 MLAST=MNOW 127.
838 PERCNT=100.*MDYN/(MSTART-MNOW+1.E-5) 128.
839 C 130.
840 CALL DIAG9A (2) 131.
841 C**** 133.
842 C**** INTEGRATE SOURCE TERMS 134.
843 C**** 135.
844 #if (!defined PREDICTED_GASES)
845 #if (defined CPL_TEM || defined CPL_OCEANCO2 )
846 if(OBSFOR) then
847 if(JMONTH.ne.AMONTH(mnobco2)) then
848 mnobco2=mnobco2+1
849 if(mnobco2.eq.13)mnobco2=1
850 call obsco2(jyear,mnobco2)
851 endif
852 endif
853 #endif
854 #endif
855 C
856 C
857 MODRD=MOD(NSTEP,NRAD) 136.
858 MODD5S=MOD(NSTEP,NDA5S) 137.
859 IF(MODD5S.EQ.0) IDACC(8)=IDACC(8)+1 138.
860 C 139.
861 C**** CONDENSTATION, SUPER SATURATION AND MOIST CONVECTION 140.
862 if(HPRNT)then
863 print *,' main before conds',' TAU=',TAU
864 #include "PRNT.COM"
865 endif
866
867
868 #if ( defined CPL_CHEM )
869 !
870 ! ===== Calculate airmass at grid point
871 ! ===== Chien Wang, 092395
872 !
873
874 call chemairmass(p4chem0)
875
876 !
877 ! === Calculating total mass of tracers
878 ! === with long residence times:
879 !
880 call chemmass1(cfc11, cfc11mass)
881 call chemmass1(cfc12, cfc12mass)
882 call chemmass1(xn2o, xn2omass)
883 call chemmass1(zco2, zco2mass)
884 call chemmass1(ch4, ch4mass)
885
886 ! === if hfc, pfc, and sf6 are included:
887 #ifdef INC_3GASES
888 ! === 032698
889 call chemmass1(hfc134a, hfc134amass)
890 call chemmass1(pfc, pfcmass)
891 call chemmass1(sf6, sf6mass)
892 ! ===
893 #endif
894
895 !
896 ! === Calculating advection and eddy diffusion:
897 !
898 call chemadv0 (dt)
899
900 !
901 ! === Calculate total n-s transport amount
902 ! === of cfc11 - temperary:
903 !
904 dth = 3600.0 ! for relexible setting of dt dt * 3.0
905 ! call chemtmp1 (dth,airmass0,p,pvv,cfc11)
906
907 ! === Readjust mass of tracers, 1:
908 !
909 ! -----------------------------
910 ! Use tropospheric life time (yr) to calculate mass
911 ! loss of tracers and at the same time compensate
912 ! all the numerical loss back to tracer's mass
913 ! which equavalent to use adjcoe = 1.0 for
914 ! chemmass2.f
915 !
916 ! Chien Wang, September 12,1995
917 ! ------------------------------
918
919 ! === 092595 update p
920
921 call chemairmass(p4chem1)
922
923 call chemmass6(46.0, 1.0, cfc11,cfc11mass)
924 call chemmass6(120.0,1.0, cfc12,cfc12mass)
925
926 ! === 102596
927 ! === close tau type of ocean uptake of co2:
928
929 call chemmass66(1.0, 1.0,zco2,zco2mass)
930
931 call chemmass6(150.0,1.0,xn2o,xn2omass)
932 call chemmass2(1.0,ch4, ch4mass )
933
934 ! === if hfc, pfc, and sf6 are included:
935 #ifdef INC_3GASES
936 ! === 032698
937 ! call chemmass6(14.6, 1.0,hfc134a, hfc134amass)
938 call chemmass2(1.0, hfc134a, hfc134amass)
939 call chemmass6(10000.0,1.0,pfc,pfcmass)
940 call chemmass6(3200.0, 1.0,sf6,sf6mass)
941 ! ===
942 #endif
943
944 !
945 ! === Calculate tropospheric gaseous reactions
946 ! === every nhr_for_chem hours:
947 !
948 dt_chem_h = dth*float(nhr_for_chem)
949 if(ievenodd.eq.0) then
950 call chemtrop0(0, T, q, dt_chem_h, 1)
951
952 c print *,'H2SO4 after chemtrop0 ',h2so4(1,33,1)
953 c print *,'SVIOD after chemtrop0 ',SVIOD(1,33,1)
954
955 !
956 ! --- tmp output
957 !
958 cnt3hr(hrcnt) = cnt3hr(hrcnt) + 1
959 sfc3hro3(1:nlat,hrcnt) = sfc3hro3(1:nlat,hrcnt)
960 & + (o3(1,1:nlat,1))*29.0/48.0
961
962 hrcnt = hrcnt + 1
963 if (hrcnt .gt. 8 ) hrcnt = 1
964 end if
965
966 ievenodd = ievenodd + 1
967 if(ievenodd.ge.nhr_for_chem) ievenodd = 0
968
969 !
970 ! === Calculating stratospheric processes:
971 ! === 092595
972 ! === adjust startospheric loss to whole global:
973 !
974 call chemmass1(cfc11, cfc11mass)
975 call chemmass1(cfc12, cfc12mass)
976 call chemmass1(xn2o, xn2omass)
977
978 call chemstrat (dt)
979
980 call chemmass2(1.0,cfc11,cfc11mass)
981 call chemmass2(1.0,cfc12,cfc12mass)
982 call chemmass2(1.0,xn2o, xn2omass)
983
984 !
985 ! === Get total mass of chemically active species:
986 !
987 ! call chemairmass(p)
988 ! write(6,*)"P before 2nd", p
989 c print *,'H2SO4 after chemairmass ',h2so4(1,33,1)
990
991 call chemmass1(cfc11, cfc11mass)
992 call chemmass1(cfc12, cfc12mass)
993 call chemmass1(xn2o, xn2omass)
994 call chemmass1(zco2, zco2mass)
995 call chemmass1(ch4, ch4mass)
996
997 ! === if hfc, pfc, and sf6 are included:
998 #ifdef INC_3GASES
999 ! === 032698
1000 call chemmass1(hfc134a, hfc134amass)
1001 call chemmass1(pfc, pfcmass)
1002 call chemmass1(sf6, sf6mass)
1003 ! ===
1004 #endif
1005
1006 #endif
1007
1008 c print *,'H2SO4 before CONDSE ',h2so4(1,33,1)
1009 CALL CONDSE(mndriver) 141.
1010 c print *,'H2SO4 after CONDSE ',h2so4(1,33,1)
1011
1012 #if ( defined CPL_CHEM )
1013 !
1014 ! === Calculate emission once per hour:
1015 !
1016 ! timeinhr=1./(365.*24.) !hourly emission
1017 ! call chememission(timeinhr)
1018 !
1019 !
1020 ! === Print hourly
1021 !
1022 ! call chemprt
1023 !
1024 ! ==============================================
1025 #endif
1026
1027 if(HPRNT)then
1028 print *,' main after conds',' TAU=',TAU
1029 #include "PRNT.COM"
1030 endif
1031 #if ( !defined CLM )
1032 CALL PRECIP_LAND(mndriver) 142.
1033 if(HPRNT)then
1034 print *,' main after preci',' TAU=',TAU
1035 #include "PRNT.COM"
1036 endif
1037 #endif
1038 CALL CLOCKS (MNOW) 143.
1039 MINC=MLAST-MNOW 144.
1040 MCNDS=MCNDS+MLAST-MNOW 145.
1041 MLAST=MNOW 146.
1042 C 147.
1043 CALL DIAG9A (3) 148.
1044 C**** RADIATION, SOLAR AND THERMAL 149.
1045 if(HPRNT)then
1046 print *,' main before radia',' TAU=',TAU
1047 #include "PRNT.COM"
1048 print *,' IRAND=',IRAND
1049 endif
1050 #if ( defined PREDICTED_GASES || defined PREDICTED_AEROSOL )
1051 call radia_chem
1052 #else
1053 if(OBSFOR) then
1054 CALL RADIAGSO
1055 else
1056 CALL RADIA
1057 endif
1058 #endif
1059 if(HPRNT)then
1060 print *,' main after radia',' TAU=',TAU
1061 #include "PRNT.COM"
1062 endif
1063 CALL CLOCKS (MNOW) 151.
1064 MINC=MINC+MLAST-MNOW 152.
1065 MRAD=MRAD+MLAST-MNOW 153.
1066 MLAST=MNOW 154.
1067 if(HPRNT)then
1068 print *,' main before diag9a',' TAU=',TAU
1069 #include "PRNT.COM"
1070 endif
1071 C 155.
1072 CALL DIAG9A (4) 156.
1073 if(HPRNT)then
1074 print *,' main after diag9a',' TAU=',TAU
1075 #include "PRNT.COM"
1076 endif
1077 C**** SURFACE INTERACTION AND GROUND CALCULATION 157.
1078
1079 #if ( defined CLM )
1080 if(HPRNT)then
1081 print *,' main before surf4clm',' TAU=',TAU
1082 #include "PRNT.COM"
1083 endif
1084 CALL SUR4CLM
1085 if(HPRNT)then
1086 print *,' main after surf4clm',' TAU=',TAU
1087 #include "PRNT.COM"
1088 endif
1089 i=1
1090 do j=1,jm
1091 pcpl4clm(i,j)=pcpl4clm(i,j)*prlnd2total(j,mndriver)
1092 pcpc4clm(i,j)=pcpc4clm(i,j)*prlnd2total(j,mndriver)
1093 enddo
1094 ! print *,' main after surf4clm',' TAU=',TAU
1095 ! print ('2(12f7.2,/,11f7.2,/)'),ps4clm,pcpl4clm,
1096 ! & pcpc4clm,tpr4clm,
1097 ! & tsl4clm,
1098 ! & qs4clm,ws4clm
1099 ! & ,us4clm,vs4clm,
1100 ! & dsw4clm,
1101 ! & dlw4clm,pco24clm
1102 ! & ,swinr4clm,swvis4clm
1103 #if ( defined DATA4TEM )
1104 c if(JYEAR.gt.20)then
1105 write (935),ps4clm,pcpl4clm,
1106 & pcpc4clm,tpr4clm,
1107 & tsl4clm,
1108 & qs4clm,ws4clm
1109 & ,us4clm,vs4clm,
1110 & dsw4clm,
1111 & dlw4clm,pco24clm
1112 & ,swinr4clm,swvis4clm
1113 c endif
1114 #endif
1115
1116 ncallclm=ncallclm+1
1117 c print *,'before clm4mit2d ncallclm=',ncallclm
1118 if(HPRNT)then
1119 print *,' main before clm4mit2d',' TAU=',TAU
1120 #include "PRNT.COM"
1121 endif
1122 call clm4mit2d
1123 if(HPRNT)then
1124 print *,' main after clm4mit2d',' TAU=',TAU
1125 #include "PRNT.COM"
1126 endif
1127
1128 c if(JYEAR.gt.20)then
1129 ! write (934),tau,tsoiclm,snwdclm,snwcclm,
1130 ! & lwuclm,tref2mclm,tflxclm,tgndclm,
1131 ! & lhfclm,shfclm,tauxclm,tauyclm,
1132 ! & asdirclm,aldirclm,asdifclm,aldifclm,
1133 ! & sroclm,ssrclm,glrclm
1134 ! &,h2olclm,h2oiclm
1135 c endif
1136 ! print *,' main after clm4mit2d',' TAU=',TAU
1137 ! print ('2(12f7.2,/,11f7.2,/)'),tsoiclm,snwdclm,snwcclm,
1138 ! & lwuclm,tref2mclm,tflxclm,tgndclm,
1139 ! & lhfclm,shfclm,tauxclm,tauyclm,
1140 ! & asdirclm,aldirclm,asdifclm,aldifclm
1141
1142 CALL SURF_CLM
1143 CALL SURF_OCEAN
1144 CALL GR_CLM
1145 if(HPRNT)then
1146 print *,' main after surfc',' TAU=',TAU
1147 #include "PRNT.COM"
1148 endif
1149 #else
1150 ! CALL SURF_LAND
1151 ! CALL SURF_OCEAN
1152 CALL SURFCE ! 07/14/2006
1153 if(HPRNT)then
1154 print *,' main after surfc',' TAU=',TAU
1155 #include "PRNT.COM"
1156 endif
1157 CALL GRLAND 159.
1158 #endif
1159
1160 #if ( defined OCEAN_3D || defined ML_2D)
1161 CALL GRFOROCEAN
1162 #else
1163 CALL GROCEAN(mndriver) 159.
1164 #endif
1165 c
1166 if(HPRNT)then
1167 print *,' main after groun',' TAU=',TAU
1168 #include "PRNT.COM"
1169 endif
1170 c print *,'H2SO4 before DRYCNV ',h2so4(1,33,1)
1171 CALL DRYCNV 160.
1172 c print *,'H2SO4 after DRYCNV ',h2so4(1,33,1)
1173 if(HPRNT)then
1174 print *,' main after drycn',' TAU=',TAU
1175 #include "PRNT.COM"
1176 endif
1177 CALL CLOCKS (MNOW) 161.
1178 MINC=MINC+MLAST-MNOW 162.
1179 MSURF=MSURF+MLAST-MNOW 163.
1180 MLAST=MNOW 164.
1181 CALL DIAG9A (5) 165.
1182 C**** STRATOSPHERIC MOMENTUM DRAG 166.
1183 CALL SDRAG(WLMMAX,JWLMMAX) 167.
1184 if(HPRNT)then
1185 print *,' main after sdrag',' TAU=',TAU
1186 #include "PRNT.COM"
1187 endif
1188 CALL CLOCKS (MNOW) 168.
1189 MINC=MINC+MLAST-MNOW 169.
1190 MSURF=MSURF+MLAST-MNOW 170.
1191 MLAST=MNOW 171.
1192 C 172.
1193 CALL DIAG9A (6) 173.
1194 MSRCE=MCNDS+MRAD+MSURF 174.
1195 PERCNT=100.*MSRCE/(MSTART-MNOW+1.E-5) 175.
1196 C**** SEA LEVEL PRESSURE FILTER 177.
1197 NFILTR= NDYN 177.5
1198 IF(MFILTR.LE.0.OR.MOD(NSTEP,NFILTR).NE.0) GO TO 500 178.
1199 IDACC(10)=IDACC(10)+1 179.
1200 if(HPRNT)then
1201 print *,' main before filtr',' TAU=',TAU
1202 #include "PRNT.COM"
1203 endif
1204 C
1205 C 180.
1206 C ****************
1207 if(LHORDIF)then
1208 DTDIF=3600.
1209 if(JM.eq.24)then
1210 CALL HORDIFF(DTDIF)
1211 else if(JM.eq.46)then
1212 CALL HORDIFFALL(DTDIF)
1213 else
1214 print *,' Wromg JM=',JM
1215 stop
1216 endif
1217 end if
1218 C ****************
1219 c CALL FILTER 181.
1220 C
1221 #if ( defined CPL_CHEM )
1222 !
1223 ! === Readjust total mass of tracers:
1224 !
1225 call chemairmass(p)
1226
1227 call chemmass2(1.00,cfc11,cfc11mass)
1228 call chemmass2(1.00,cfc12,cfc12mass)
1229 call chemmass2(1.00,xn2o ,xn2omass )
1230 call chemmass2(1.00,zco2,zco2mass)
1231 call chemmass2(1.00,ch4, ch4mass )
1232
1233 ! === if hfc, pfc, and sf6 are included:
1234 #ifdef INC_3GASES
1235 ! === 032698
1236 call chemmass2(1.0,hfc134a, hfc134amass)
1237 call chemmass2(1.0,pfc, pfcmass)
1238 call chemmass2(1.0,sf6, sf6mass)
1239 ! ===
1240 #endif
1241
1242 !
1243 ! === Accumulative calculation prepared for
1244 ! === carrying out monthly average:
1245 !
1246 call chemmonth1
1247 !
1248 #endif
1249
1250 CALL CLOCKS (MNOW) 182.
1251 MDYN=MDYN+MLAST-MNOW 183.
1252 MLAST=MNOW 184.
1253 C 185.
1254 CALL DIAG9A (7) 186.
1255 C**** 187.
1256 C**** UPDATE MODEL TIME AND CALL DAILY IF REQUIRED 188.
1257 C**** 189.
1258 500 NSTEP=NSTEP+NDYN 190.
1259 ITAU=(NSTEP+NSTEP0)*IDTHR 191.
1260 cJRS fix to DFLOAT 8/2/07
1261 TAU=DFLOAT(ITAU)/XINT 192.
1262 IDAY=1+ITAU/I24 193.
1263 TOFDAYPR=TOFDAY+1.00
1264 TOFDAY=(ITAU-(IDAY-1)*I24)/XINT 194.
1265 IF(.NOT.EVENT(24.)) GO TO 550 195.
1266 C 196.
1267 do J=1,JM0
1268 TSURFW(J)=TSURFD(J)
1269 TLANDW(J)=TLANDD(J)
1270 enddo
1271
1272 JDATECLM=JDATE
1273 JDATEPR=JDATE
1274 JMONTHPR=JMONTH
1275 JYEARPR=JYEAR
1276 CALL DAILY_NEW 197.
1277 c print *,' AFTER DAILY_NEW IDAY=',IDAY,' IYEAR=',IYEAR
1278 c print *,' JYEAR=',JYEAR,' JDAY=',JDAY
1279 #if( !defined OCEAN_3D && !defined ML_2D )
1280 CALL DAILY_OCEAN
1281 c print *,' AFTER DAILY_OCEAN IDAY=',IDAY,' IYEAR=',IYEAR
1282 c print *,' JYEAR=',JYEAR,' JDAY=',JDAY
1283 c print *,' JDATE=',JDATE,' JMONTH=',JMONTH
1284 #endif
1285 if(JDATE.eq.100)then
1286 print *,JDATE,JMONTH,JYEAR
1287 print *,' main after daily'
1288 print *,' T1 ocean'
1289 print 5001,(ODATA(1,j,1),j=1,JM0)
1290 print *,' T2 ocean'
1291 print 5001,(ODATA(1,j,4),j=1,JM0)
1292 print *,' T3 ocean'
1293 print 5001,(ODATA(1,j,5),j=1,JM0)
1294 print *,' sea ice'
1295 print 5002,(ODATA(1,j,2),j=1,JM0)
1296 endif
1297 CALL CLOCKS (MNOW) 198.
1298 MELSE=MELSE+(MLAST-MNOW) 199.
1299 MLAST=MNOW 200.
1300 NDAILY=SDAY/DT 201.
1301
1302 #if ( defined CPL_CHEM )
1303 !
1304 ! === Calculate air mass, second step:
1305 !
1306 i=1
1307 call chemairmass(p)
1308
1309 !
1310 ! === Calculate emission once per day:
1311 !
1312 c zxy=0.
1313 c do j=1,jm
1314 c zxy=zxy+zco2(1,j,1)
1315 c & *28.97296245/44.0*1.e-3
1316 c enddo
1317 c print *,' CO2 before emission ',zxy/jm
1318
1319 timeinday=1./(365.) !daily emission
1320 call chememission(timeinday)
1321
1322 c zxy=0.
1323 c do j=1,jm
1324 c zxy=zxy+zco2(1,j,1)
1325 c & *28.97296245/44.0*1.e-3
1326 c enddo
1327 c print *,' CO2 after emission ',zxy/jm
1328 !
1329 #endif
1330
1331 C 202.
1332 CALL DIAG9A (8) 203.
1333 #if ( !defined OCEAN_3D && !defined ML_2D )
1334 IF(KOCEAN.EQ.1) THEN
1335 DO 540 J=1,JM 203.11
1336 DO 540 I=1,IM 203.12
1337 AIJ(I,J,59)=AIJ(I,J,59)+ODATA(I,J,4) 203.13
1338 540 AIJ(I,J,60)=AIJ(I,J,60)+ODATA(I,J,5) 203.14
1339 if(TRANSR)then
1340 if(LMO.eq.11) then
1341 CALL ODIFS
1342 elseif(LMO.eq.12) then
1343 CALL ODIFS12
1344 else
1345 Print *,' Wromng LMO',LMO
1346 stop
1347 endif
1348 NODIFS=NODIFS+1
1349 do 5283 j=1,JM0
1350 do 5283 k=1,lmo
1351 RTGOAV(j,k)=RTGOAV(j,k)+RTGO(1,j,k)
1352 5283 continue
1353 endif
1354 C**** RESTRUCTURE THE OCEAN LAYERS AND ELIMINATE SMALL ICE BERGS 203.15
1355 CALL OSTRUC 203.16
1356 if(JDATE.eq.41)then
1357 print *,JDATE,JMONTH,JYEAR
1358 print *,' main after ostruc'
1359 print *,'Z1O'
1360 print 5001,(Z1O(1,j),j=1,JM0)
1361 print *,' T1 ocean'
1362 print 5001,(ODATA(1,j,1),j=1,JM0)
1363 print *,' T2 top ocean'
1364 print 5001,((2.*ODATA(1,j,4)-ODATA(1,j,5)),j=1,JM0)
1365 print *,' T2 ocean'
1366 print 5001,(ODATA(1,j,4),j=1,JM0)
1367 print *,' T3 ocean'
1368 print 5001,(ODATA(1,j,5),j=1,JM0)
1369 endif
1370 ENDIF ! KOCEAN
1371 #endif
1372 #if ( defined ML_2D )
1373 if(TRANSR)then
1374 NODIFS=NODIFS+1
1375 do 5283 j=1,JM0
1376 do 5283 k=1,lmo
1377 RTGOAV(j,k)=RTGOAV(j,k)+RTGO(1,j,k)
1378 5283 continue
1379 endif
1380 #endif
1381
1382 #if ( defined CPL_OCEANCO2 )
1383
1384 C For OCM or 3D ocean model with carbon cycle
1385 #ifdef PREDICTED_GASES
1386 c -------
1387 c 102596
1388 c air co2 mixing ratio goes to ocean carbon model:
1389 c
1390 do j=1,jm
1391 pC_atm(j)=zco2(1,j,1)
1392 & *28.97296245/44.0*1.e-9
1393 !ppb(m) to kg per volume base
1394
1395 atm_co2(j)=pC_atm(j)*1.e6
1396
1397 enddo ! j
1398 c
1399 c -------
1400 #else
1401
1402 do j=1,jm
1403 pC_atm(j)=atm_co2(j)*1.e-6
1404 enddo ! j
1405
1406 #endif
1407
1408 #if ( defined ML_2D )
1409 CB Gary CO2 uptake by the ocean
1410
1411 do j=1,jm
1412 if(NWMGEA(J).gt.0)then
1413 WSAV(J)=WSAV(J)/NWMGEA(J)
1414 NWMGEA(J)=0.
1415 else
1416 WSAV(J)=0.
1417 end if
1418 end do ! j
1419
1420 do j=1,jm
1421 tggary(j)=ODATA(1,j,1)+273.16
1422 wsgary(j)=WSAV(J)
1423 WSAV(j)=0.
1424 arsrf(j)=areaml(j)*(1.-ODATA(1,j,2))
1425 DEPTHML(j)=ZOAV(J)
1426 co24ocnan(j)=co24ocnan(j)+pC_atm(j)*1.e6
1427 enddo ! j
1428 c print *,'CO2 for 2D ocean'
1429 c print *,JYEAR,JMONTH
1430 c print *,'co2=',pC_atm(27)*1.e6,' ws=',wsgary(27)
1431 c print *,'tem=',tggary(27)
1432 c print '12f7.1,/,2(11f7.1,/,),12f7.1',(pC_atm(j)*1.e6,j=1,jm)
1433 c print '12f7.1,/,2(11f7.1,/,),12f7.1',(rco2(j,1),j=1,jm)
1434 c ncallgary=ncallgary+1
1435 ! 10/28/06
1436 ! call carb_mxdlyr_chem(focean)
1437 ! call carb_airsea_flx
1438 !
1439 ! 3D ocean chemistry
1440 call carb_chem_ocmip(focean)
1441 call carb_airsea_flx(dtco2)
1442 ! 3D ocean chemistry
1443 ! 10/28/06
1444 c print *,'FCO2 ncallgary=',ncallgary
1445 c print '12f7.1,/,2(11f7.1,/,),12f7.1',
1446 c & (fluxco2(j)*12.e-15*365.,j=1,jm)
1447 #endif
1448
1449 C For ocean carbon model
1450 c Annual oceanic CO2 uptake
1451 do j=1,jm
1452 OCUPT=OCUPT+fluxco2(j)
1453 enddo
1454 ! print *,' OCUPT=',OCUPT*12.e-15
1455
1456 #if ( defined CPL_CHEM )
1457 !
1458 ! === Calculate ocean uptake of CO2
1459 ! === once per day:
1460 !
1461 i=1
1462 call chemairmass(p) !update airmass
1463
1464 call chemoceanco2(fluxco2)
1465 !
1466 #endif
1467
1468 do j=1,jm
1469 fluxco2(j)=0.0
1470 enddo
1471 #endif
1472
1473 #if ( defined CPL_TEM )
1474 !#if ( defined CLM )
1475 c print *,'JDATE for TEM=',JDATECLM
1476 do j=1,jm
1477 if(npred4tem(j).gt.0)then
1478 c pred4tem(j)=pred4tem(j)/npred4tem(j)
1479 ewvd4tem(j)=ewvd4tem(j)/npred4tem(j)
1480 pre4tem(J)=pre4tem(J)+pred4tem(j)
1481 endif
1482 c
1483 if(nt2md4tem(j).gt.0)then
1484 t2md4tem(j)=t2md4tem(j)/nt2md4tem(j)
1485 endif
1486 temp4tem(j)=temp4tem(j)+t2md4tem(j)
1487 dtem4tem(JDATECLM,j)=t2md4tem(j)
1488 c
1489 if(nradd4tem(j).gt.0)then
1490 cldd4tem(j)=cldd4tem(j)/ncldd4tem(j)
1491 swtd4tem(j)=swtd4tem(j)/nradd4tem(j)
1492 swsd4tem(j)=swsd4tem(j)/nradd4tem(j)
1493 endif
1494 sws4tem(j)=sws4tem(j)+swsd4tem(j)
1495 c
1496 enddo
1497 c
1498 do j=1,jm
1499 pred4tem(j)=0.0
1500 ewvd4tem(j)=0.0
1501 t2md4tem(j)=0.0
1502 cldd4tem(j)=0.0
1503 swtd4tem(j)=0.0
1504 swsd4tem(j)=0.0
1505 npred4tem(j)=0
1506 ncldd4tem(j)=0
1507 nradd4tem(j)=0
1508 nt2md4tem(j)=0.
1509 enddo
1510 #endif
1511
1512 #if ( defined CPL_OCEANCO2 && defined ML_2D )
1513 C For OCM
1514
1515 ! dtco2=3600.*24.
1516 ! cfkvct=1.0
1517 ! if (JYEAR.ge.1991) then begin
1518 ! if (JYEAR.le.2100) then begin
1519 ! cfkvct=(1.0*(2100-JYEAR)+0.25*(JYEAR-1990))/110.
1520 ! esle
1521 ! cfkvct=0.25
1522 ! endif
1523 ! endif
1524 ! do j=1,jm
1525 ! edzcatr(j)=cfkvct*edzcar(j)
1526 ! enddo
1527 call diffusco2(lmo,jm,dtco2,0.5,edzcart,depthml,focean,
1528 & dzg,dzog,rco2)
1529 call hdocean(rco2,focean,dxv,dyv,DXYP,depthml,edohd,dtco2)
1530 call avegary
1531 CB Gary CO2 uptake by the ocean
1532 #endif
1533
1534 #if ( defined CPL_CHEM) && ( defined CPL_TEM )
1535 C take into accout land uptake form TEM for previous month
1536 do j=1,jm
1537 fluxnep(j)=aduptd+1.e-3*temco2(j)/NDAYMN(mndriver)
1538 c Annual TEM CO2 uptake
1539 TEMUPTANN=TEMUPTANN+fluxnep(j)
1540 enddo
1541 if(jdate.eq.1)then
1542 print *,'Monthly TEM uptake'
1543 c print *,mndriver,adupt,temuptann-temup0
1544 temup0=temuptann
1545 endif
1546 C
1547 c
1548 i=1
1549 call chemairmass(p) !update airmass
1550
1551 call chemtemco2(fluxnep)
1552 C
1553 c
1554 !
1555 #endif
1556
1557 c End of month
1558 if(JDATE.eq.1)then
1559
1560 #if ( defined CPL_CHEM )
1561 !
1562 ! === Calculating monthly averaged mixing ratios:
1563 !
1564 call chemmonth2
1565 c print *,'Atmosphere after chemmonth2'
1566
1567 ! === Calculate and print monthly n-s transport
1568 ! === of cfc11:
1569 !
1570 ! call chemtmp2
1571 !
1572 do nhr = 1,8
1573 sfc3hro3(1:nlat,nhr) = sfc3hro3(1:nlat,nhr)
1574 & /float(cnt3hr(nhr))
1575 #if ( defined CPL_TEM )
1576 o34tem(nhr,1:nlat)=sfc3hro3(1:nlat,nhr)
1577 #endif
1578 end do
1579 cwrite(124)sfc3hro3
1580 cnt3hr(1:8) = 0
1581 sfc3hro3(1:nlat,1:8) = 0.0
1582
1583 ! === Writing rawdata every month:
1584 !
1585 ! call chemprt !closed 032697
1586
1587 call chembudget (p)
1588 print *,' Atmosphre after chembudget mymonth=',mymonth
1589 ! === 09/26/94
1590 ! === Reset year and month index:
1591 !
1592 mymonth = mymonth + 1
1593 if(mymonth.gt.12)then
1594 myyear = myyear +1
1595 ! myyear = min(myyear,nchemyr)
1596 myyear = min(myyear,myyearlast)
1597 mymonth = 1
1598 ! endif ! 27/8/2005
1599
1600 ! === 092295
1601 ! === write rawdata for possible renew run
1602 ! === at end of each month:
1603 ! === at end of each year: 27/8/2005
1604 !
1605 rewind 178
1606 print *,'For chem restart ',myyear,mymonth
1607 write(178)myyear,mymonth,airmass,
1608 & cfc11,cfc110,
1609 & cfc11m,
1610 & cfc11sd,
1611 & cfc12,cfc12m,
1612 & cfc12sd,
1613 & xn2o ,xn2om ,
1614 & xn2osd,
1615 & hfc134a,hfc134am,
1616 & pfc ,pfcm,
1617 & sf6 ,sf6m,
1618 & bcarbon,bcm,
1619 & ocarbon,ocm,
1620 & atomo ,
1621 & o1d ,
1622 & o3 ,o3m ,
1623 & co ,com ,
1624 & zco2 ,zco2m,
1625 & atomh ,
1626 & ho ,
1627 & ho2 ,hoxm ,
1628 & h2o2 ,
1629 & xno ,
1630 & xno2 ,xnoxm,
1631 & xno3 ,
1632 & xn2o5 ,xnoym,
1633 & hno3 ,
1634 & ch4 ,ch4m ,
1635 & ch3 ,
1636 & cho ,
1637 & ch2o ,
1638 & ch3o ,
1639 & ch3o2 ,
1640 & ch3o2h,
1641 & so2 ,so2m ,
1642 & hoso2 ,
1643 & so3 ,
1644 & h2so4 ,h2so4m,
1645 & sviod ,sviodm
1646 rewind 178
1647
1648 endif
1649 #endif
1650
1651 #if ( defined CPL_TEM )
1652 !#if ( defined CLM )
1653 do J=1,JM
1654 c
1655 #ifdef PREDICTED_GASES
1656 co24tem(j)=zco2(1,j,1)
1657 & *28.97296245/44.0*1.e-3
1658 !ppm(m) to kg per volume base
1659 #else
1660 co24tem(j)=atm_co2(j)
1661
1662 #endif
1663 c
1664 enddo
1665 #endif
1666
1667 endif ! end of month
1668 550 continue
1669 C END of DAilY
1670
1671
1672 C CALL CHECKT (11) 203.17
1673 CALL CLOCKS (MNOW) 203.18
1674 MSURF=MSURF+(MLAST-MNOW) 203.19
1675 MLAST=MNOW 203.2
1676 C**** 204.
1677 C**** WRITE INFORMATION ONTO A TAPE EVERY USET HOURS 205.
1678 C**** 206.
1679 IF(USET.LE.0.) GO TO 600 207.
1680 IF(.NOT.EVENT(USET)) GO TO 600 208.
1681 C COMPUTATIONS FOR XXXXXX 209.
1682 WRITE (520) TAU,XXXXXX 210.
1683 CALL CLOCKS (MNOW) 211.
1684 MINC=MLAST-MNOW 212.
1685 MELSE=MELSE+MINC 213.
1686 PERCNT=100.*MELSE/(MSTART-MNOW+1.E-5) 214.
1687 c WRITE (6,910) MINC,MELSE,PERCNT,TAU 215.
1688 C**** 216.
1689 C**** CALL DIAGNOSTIC ROUTINES 217.
1690 C**** 218.
1691 600 IF(MOD(NSTEP-NDYN,NDA4).EQ.0) CALL DIAG4A 219.
1692 C 220.
1693 IF(NDPRNT(1).GE.0) GO TO 610 221.
1694 C**** PRINT CURRENT DIAGNOSTICS (INCLUDING THE INITIAL CONDITIONS) 222.
1695 IF(KDIAG(1).LT.9) CALL DIAG1(NOCLM) 223.
1696 IF(KDIAG(2).LT.9) CALL DIAG2 224.
1697 IF(KDIAG(7).LT.9) CALL DIAG7P 225.
1698 IF(KDIAG(3).LT.9) CALL DIAG3 226.
1699 C 227.
1700 C 228.
1701 IF(KDIAG(4).LT.9) CALL DIAG4 229.
1702 IF(TAU.LE.TAUI+DTHR*(NDYN+.5)) CALL DIAGKN 230.
1703 NDPRNT(1)=NDPRNT(1)+1 231.
1704 C 690 changed to 691 02/21/2003
1705 610 IF(.NOT.EVENT(24.)) GO TO 691 232.
1706 C**** PRINT DIAGNOSTIC TIME AVERAGED QUANTITIES ON NDPRNT-TH DAY OF RUN 233.
1707 DO 620 K=1,13 234.
1708 IF (JDAY.EQ.NDPRNT(K)) GO TO 630 235.
1709 620 CONTINUE 236.
1710 GO TO 640 237.
1711 c 630 WRITE (6,920) 238.
1712 630 continue
1713 IF(KDIAG(1).LT.9) CALL DIAG1(NOCLM) 239.
1714 IF(KDIAG(2).LT.9) CALL DIAG2 240.
1715 IF(KDIAG(7).LT.9) CALL DIAG7P 241.
1716 IF(KDIAG(3).LT.9) CALL DIAG3 242.
1717 C 243.
1718 C 244.
1719 C IF(KDIAG(6).LT.9) CALL DIAG6 245.
1720 IF(KDIAG(4).LT.9) CALL DIAG4 246.
1721 IF(KDIAG(8).LT.9) CALL DIAG8 (IPFLAG) 247.
1722 C**** THINGS TO DO BEFORE ZEROING OUT THE ACCUMULATING ARRAYS 248.
1723 C**** (NORMALLY DONE AT THE END OF A MONTH) 249.
1724 640 DO 650 K=1,13 250.
1725 IF(JDAY.EQ.NDZERO(K)) GO TO 660 251.
1726 650 CONTINUE 252.
1727 GO TO 690 253.
1728 C**** PRINT THE KEY DIAGNOSTICS 254.
1729 660 CONTINUE 255.
1730 CALL DIAGKN 255.
1731 C**** PRINT AND ZERO OUT THE TIMING NUMBERS 256.
1732 CALL CLOCKS (MNOW) 257.
1733 MDIAG=MDIAG+(MLAST-MNOW) 258.
1734 MLAST=MNOW 259.
1735 TOTALT=.01*(MSTART-MNOW) 260.
1736 PDYN=MDYN/TOTALT 261.
1737 PCDNS=MCNDS/TOTALT 262.
1738 PRAD=MRAD/TOTALT 263.
1739 PSURF=MSURF/TOTALT 264.
1740 PDIAG=MDIAG/TOTALT 265.
1741 PELSE=MELSE/TOTALT 266.
1742 DTIME=24.*TOTALT/(60.*(TAU-TAU0)) 267.
1743 c WRITE (6,909) DTIME,PDYN,PCDNS,PRAD,PSURF,PDIAG,PELSE 268.
1744 MDYN=0 269.
1745 MCNDS=0 270.
1746 MRAD=0 271.
1747 MSURF=0 272.
1748 MDIAG=0 273.
1749 MELSE=0 274.
1750 MSTART=MNOW 275.
1751 if(TRANSR)then
1752 do 5284 j=1,JM0
1753 do 5284 k=1,lmo
1754 RTGOAV(j,k)=RTGOAV(j,k)/NODIFS
1755 5284 continue
1756 c print *,'ATM RTGOAV monthly'
1757 c print *,(RTGOAV(J,1),j=1,jm)
1758 endif ! TRANSR
1759 SPGAV=srps(jm+3)/nsrps+PTOP
1760 do 5285 j=1,JM+3
1761 GBUDG(j,38,1)=(srps(j)/nsrps+PTOP)*1013./SPGAV
1762 5285 continue
1763 c do 5287 j=1,JM+3
1764 c GBUDG(j,38,1)=GBUDG(j,37,1)*1013./GBUDG(jm+3,37,1)
1765 c5287 continue
1766 ! print *,'FRMDICE'
1767 ! print '6(1PE12.4)',FRMDICE
1768 ENKE=0.0
1769 ENPT=0.0
1770 do ii=1,4
1771 ENKE=ENKE+SPECA(1,19,ii)
1772 ENPT=ENPT+SPECA(1,20,ii)
1773 enddo
1774 c print *,'ENKE=',ENKE,' ENTP=',ENPT,' ENTT=',ENKE+ENPT
1775 print *,'ENKE=',QTABLE(JMP3,19,10),' ENTP=',QTABLE(JMP3,20,10),
1776 & ' ENTT=',QTABLE(JMP3,19,10)+QTABLE(JMP3,20,10)
1777 print *,'WLMMAX=',WLMMAX,' JWLMMAX=',JWLMMAX
1778 c print *,'AJ(*,37)'
1779 c print *,(AJ(J,37),j=1,jm)
1780 c print *,'AJ(*,28)'
1781 c print *,(AJ(J,28),j=1,jm)
1782 c IF(USEP.LE.0.) GO TO 680 276.
1783 C**** WRITE SELECTED DIAGNOSTICS ONTO A DISK DATA SET FOR PLOTTING 277.
1784 c IF(TAU.LE.TAUI+1080.) GO TO 675 278.
1785 c 670 READ (16) TAUX 279.
1786 c IF(TAU.GT.TAUX+1080.) GO TO 670 280.
1787 675 WRITE (546) AEXP4,JDATE,JMONTH,JYEAR,JDATE0,JMNTH0,JYEAR0, 281.
1788 * GBUDG,QMAPS,QTABLE,INQTAB,J1QT,INQMAP,RTGOAV
1789 print *,'From atm write(546) ',JMNTH0,JYEAR0,' ',JMONTH,JYEAR
1790 c print *,0.1*GBUDG(1,26,2),0.1*GBUDG(1,35,2)
1791 nwr=nwr+1
1792 690 continue
1793 if(JDAY.eq.1)then
1794 rewind 547
1795 write(547)AEXP,nwr
1796 rewind 547
1797 print *,'From atm write(547) ',AEXP,nwr
1798 endif
1799 if(wr25.and.JDAY.eq.1)then
1800 c Write a restart file once a year
1801 print *,'Write a restart file once a year.'
1802
1803 #if ( defined CPL_OCEANCO2 && defined ML_2D )
1804 C Data for possible restart for OCM
1805 write(369)jyear-1,vdfocm
1806 write(369)Hg
1807 write(369)Rco2
1808 rewind 369
1809 #endif
1810
1811 print *,' KDISK0=',KDISK0
1812 CALL RFINAL (IRAND)
1813 REWIND KDISK0
1814 if(TRANSR)then
1815 WRITE(KDISK0) AEXP,TAU,JC,C,RC,KEYNR,U,V,T,P,Q,ODATA,GDATA,
1816 * BLDATA,
1817 * RQT,SRHR,TRHR,(AJ(K,1),K=1,KACC),TAU,TSSFC,CKS,CKN,WMGE,TPRIM2
1818 * ,MRCHT,TRSURF,SRSURF,TLANDW,TSURFW,DWAV0
1819 * ,TG3M,RTGO,STG3,DTG3
1820 else
1821 WRITE(KDISK0) AEXP,TAU,JC,C,RC,KEYNR,U,V,T,P,Q,ODATA,GDATA,
1822 * BLDATA,
1823 * RQT,SRHR,TRHR,(AJ(K,1),K=1,KACC),TAU,TSSFC,CKS,CKN,WMGE,TPRIM2
1824 * ,MRCHT,TRSURF,SRSURF,TLANDW,TSURFW,DWAV0
1825 c print *,' TSURFT'
1826 c print 5001,TSURFT
1827 c print *,' TSURFW'
1828 c print 5001,TSURFW
1829 endif
1830 REWIND KDISK0
1831 KDISK=3-KDISK
1832 KDISK0=500+KDISK
1833 end if
1834 C 690 changed to 691 02/21/2003
1835 680 IF(KCOPY.LE.0) GO TO 691 284.
1836 C**** WRITE A COPY OF THE FINAL RESTART DATA SET ONTO DISK 285.
1837 CALL RFINAL (IRAND) 285.5
1838 print *,' after 680'
1839 print *,' TAU=',TAU,' IRAND=',IRAND
1840 IF(KCOPY.GT.99) GO TO 687 286.
1841 683 READ (KCOPY) TAUX 286.5
1842 IF(TAU.GT.TAUX+3240.) GO TO 683 287.
1843 685 WRITE (KCOPY) TAU,JC,C,RC,KEYNR,U,V,T,P,Q,ODATA,GDATA,BLDATA, 287.5
1844 * RQT,SRHR,TRHR,(AJ(K,1),K=1,KACC),TAU,TSSFC,CKS,CKN 288.
1845 * ,WMGE,TPRIM2,MRCHT,TRSURF,SRSURF,TLANDW,TSURFW,DWAV0
1846 * ,TG3M,RTGO,STG3,DTG3
1847 REWIND KCOPY 288.5
1848 C 690 changed to 691 02/21/2003
1849 GO TO 691 289.
1850 687 KCOPY=KCOPY-100 289.5
1851 GO TO 685 289.6
1852 C**** TIME FOR CALLING DIAGNOSTICS 290.
1853 C 690 changed to 691 02/21/2003
1854 691 CALL CLOCKS (MNOW) 291.
1855 MDIAG=MDIAG+(MLAST-MNOW) 292.
1856 MLAST=MNOW 293.
1857 780 IF(TAU.LE.TAUI+DTHR*(NDYN+.5)) GO TO 120 294.
1858 GO TO 100 295.
1859 C**** 296.
1860 C**** END OF MAIN LOOP 297.
1861 C**** 298.
1862 C**** RUN TERMINATED BECAUSE SENSE SWITCH 6 WAS TURNED ON 299.
1863 800 WRITE (6,904) 300.
1864 IF(EVENT(TAUT)) GO TO 820 301.
1865 CALL RFINAL (IRAND) 302.
1866 print *,' after 800'
1867 print *,' TAU=',TAU,' IRAND=',IRAND
1868 if(wr25) then
1869 REWIND KDISK0 303.
1870 WRITE(KDISK0) AEXP,TAU,JC,C,RC,KEYNR,U,V,T,P,Q,ODATA,GDATA,BLDATA, 304.
1871 * RQT,SRHR,TRHR,(AJ(K,1),K=1,KACC),TAU,TSSFC,CKS,CKN,WMGE,TPRIM2 305.
1872 * ,MRCHT,TRSURF,SRSURF,TLANDW,TSURFW,DWAV0
1873 end if
1874 C WRITE (6,908) 306.
1875 C**** RUN TERMINATED BECAUSE IT REACHED TAUE (OR SS6 WAS TURNED ON) 307.
1876 c 820 WRITE (6,905) TAU,IDAY,TOFDAY 308.
1877 820 continue
1878
1879 #if ( defined OCEAN_3D || defined ML_2D )
1880 C DTATM time step of atm model in hours
1881 C precip and evap in mm/day or kg/m**2/day
1882 do j=1,jm0
1883 #if ( defined OCEAN_3D && defined CPL_OCEANCO2 )
1884 ncallatm=ncallatm+1
1885 ! 020107
1886 ! co24ocean(j)=pC_atm(j)*1.e6
1887 co24ocean(j)=atm_co2(j)
1888 ! 020107
1889 co24ocnan(j)=co24ocnan(j)+co24ocean(j)
1890 #endif
1891 #ifdef ML_2D
1892 cjrs block only MD_2D
1893 rseaice(j)=ODATA(1,J,2)
1894 #endif
1895 tauu(j)=tauu(j)/(NSURF*DTATM)
1896 tauv(j)=tauv(j)/(NSURF*DTATM)
1897 tempr(j)=tempr(j)/DTATM
1898 precip(j)=precip(j)/(DTATM/24.)
1899 fland=FDATA(1,J,2)
1900 if (fland.lt.1.0)then
1901 precip(j)=precip(j)*(1.-fland*prlnd2total(j,mndriver))
1902 & /(1.-fland)
1903 endif
1904 Cjrs surfpr(j)=surfpr(j)/(DTATM/24.)
1905 c
1906 if(naveo(j).gt.0)then
1907 hfluxo(j)=NSURF*hfluxo(j)/(NDYN*DT*naveo(j))
1908 dhfodtg(j)=dhfodtg(j)/naveo(j)
1909 dhfodtgeq(j)=dhfodtgeq(j)/naveo(j)
1910 evao(j)=NSURF*evao(j)/(NDYN*DT*naveo(j))
1911 devodtg(j)=devodtg(j)/naveo(j)
1912 devodtgeq(j)=devodtgeq(j)/naveo(j)
1913 C From mm/sec to mm/day
1914 evao(j)=24.*3600.*evao(j)
1915 devodtg(j)=24.*3600.*devodtg(j)
1916 devodtgeq(j)=24.*3600.*devodtgeq(j)
1917 endif
1918 C
1919 if(navei(j).gt.0)then
1920 hfluxi(j)=NSURF*hfluxi(j)/(NDYN*DT*navei(j))
1921 dhfidtg(j)=dhfidtg(j)/navei(j)
1922 dhfidtgeq(j)=dhfidtgeq(j)/navei(j)
1923 evai(j)=NSURF*evai(j)/(NDYN*DT*navei(j))
1924 devidtg(j)=devidtg(j)/navei(j)
1925 devidtgeq(j)=devidtgeq(j)/navei(j)
1926 C From mm/sec to mm/day
1927 evai(j)=24.*3600.*evai(j)
1928 devidtg(j)=24.*3600.*devidtg(j)
1929 devidtgeq(j)=24.*3600.*devidtgeq(j)
1930 endif
1931 C
1932 if(navrad(j).gt.0)then
1933 solarinc_ice(j)=solarinc_ice(j)/navrad(j)
1934 solarnet_ice(j)=solarnet_ice(j)/navrad(j)
1935 endif
1936 if(navrado(j).gt.0)then
1937 solarinc_ocean(j)=solarinc_ocean(j)/navrado(j)
1938 solarnet_ocean(j)=solarnet_ocean(j)/navrado(j)
1939 endif
1940 c Runoff is a flux of water from land in mm/day
1941 c not for m**2
1942 cjrs change runoff to new name arunoff
1943 arunoff(j)=arunoff(j)/(DTATM/24.)*FDATA(1,j,2)
1944 & *DXYP(J)
1945 if(NWMGEA(J).gt.0)then
1946 wsocean(J)=WSAV(J)/NWMGEA(J)
1947 NWMGEA(J)=0.
1948 else
1949 wsocean(J)=0.
1950 end if
1951 WSAV(J)=0.
1952 c dhdtav(j)=dhdtav(j)+dhfdtg(j)
1953 c devdtav(j)=devdtav(j)+devdtg(j)
1954 c
1955 c
1956 ps4ocean(j)=ps4ocean(j)/DTATM
1957 do l=1,lm
1958 qyz4ocean(j,l)=qyz4ocean(j,l)/DTATM
1959 tyz4ocean(j,l)=tyz4ocean(j,l)/DTATM
1960 enddo
1961 c
1962 c
1963 end do ! j
1964 rungl=0.0
1965 runn=0.0
1966 runt=0.0
1967 runs=0.0
1968 SLAND=0.0
1969 CLAT=20.*TWOPI/360.
1970 do j=1,jm
1971 SLAND=SLAND+FDATA(1,j,2)*DXYP(J)
1972 c jrs runoff->arunoff
1973 rungl=rungl+arunoff(j)
1974 if(LAT(J).lt.-CLAT)then
1975 runs=runs+arunoff(j)
1976 else if(LAT(J).lt.CLAT)then
1977 runt=runt+arunoff(j)
1978 else
1979 runn=runn+arunoff(j)
1980 endif
1981 enddo
1982 c print *,'RUNOFF TOFDAY=',TOFDAY
1983 c print *,rungl/SLAND,rungl,runs,runt,runn
1984 c nmonth=JMNTH0
1985 #ifdef ML_2D
1986 c jrs only ML_2D
1987 nmonth=AMONTH(mndriver)
1988 #endif
1989 jdatefl=jdate-1
1990 c if(JMONTH.ne.JMNTH0)jdatefl=NDAYMN(mndriver)
1991 c if(JMONTH.ne.JMNTH0)then
1992 c print *,'OCEAN FLUXS'
1993 c print *,JMONTH,JMNTH0,JDATE
1994 c print *,'Month=',AMONTH(mndriver),' day=',jdatefl
1995 c print *,' TAIR_OCEAN'
1996 c print *,(tairo(j),j=1,jm0)
1997 c print *,' TAIR_ICE'
1998 c print *,(tairi(j),j=1,jm0)
1999 c print *,' TAUU'
2000 c print *,(tauu(j),j=1,jm0)
2001 c print *,' TAUV'
2002 c print *,(tauv(j),j=1,jm0)
2003 c print *,' EVA-E OCEAN'
2004 c print *,(evao(j),j=1,jm0)
2005 c print *,' EVA-I OCEAN'
2006 c print *,(evai(j),j=1,jm0)
2007 c print *,' P-E ICE'
2008 c print *,(pmei(j),j=1,jm0)
2009 c print *,' HEAT FLUX OCEAN'
2010 c print *,(hfluxo(j),j=1,jm0)
2011 c print *,' DHEATFLUX_OCEAN/DTG'
2012 c print *,(dhfodtg(j),j=1,jm0)
2013 c print *,' EVA_OCEAN/DTG'
2014 c print *,(devodtg(j),j=1,jm0)
2015 c print *,' EVA_ICE/DTG'
2016 c print *,(devidtg(j),j=1,jm0)
2017 c print *,' HEAT FLUX ICE'
2018 c print *,(hfluxi(j),j=1,jm0)
2019 c print *,' DHEATFLUX_ICE/DTG'
2020 c print *,(dhfidtg(j),j=1,jm0)
2021 c print *,' DLH_OCEAN/DTG'
2022 c print *,(devidtg(j),j=1,jm0)
2023 c print *,'PS4OCEAN'
2024 c print *,(ps4ocean(j),j=1,jm0)
2025 c print *,'QYZ4OCEAN'
2026 c do l=1,lm
2027 c print *,(qyz4ocean(j,l),j=1,jm0)
2028 c enddo
2029 c endif
2030 c go to 587
2031 c write(893),nmonth,jdatefl,tempr,tauu,tauv,precip,evao,
2032 c & evai,hfluxo,dhfodtg,devodtg,hfluxi,dhfidtg,devidtg,
2033 c & solarinc_ice,solarnet_ice,rseaice
2034 #ifdef ML_2D
2035 c jrs only ML_2D
2036 do j=1,jm
2037 osst(j)=ODATA(1,j,1)
2038 aoice(j)=ODATA(1,j,3)
2039 foice(j)=ODATA(1,j,2)
2040 snowice(j)=GDATA(1,j,1)
2041 tice1(j)=GDATA(1,j,3)
2042 tice2(j)=GDATA(1,j,7)
2043 enddo
2044 #endif
2045 c write (894),nmonth,jdatefl,osst,aoice,foice,snowice,tice1,tice2
2046 587 continue
2047 #endif
2048
2049 C
2050 c TAU for coupler
2051 c
2052 TAUATM=TAU
2053 MONTHATM=JMONTH
2054 JDATEATM=JDATE
2055 JYEARATM=JYEAR
2056 C
2057 #ifdef ML_2D
2058 Cjrs change this block to only ML_2D
2059 IDAYM=IDAY
2060 JDAYM=JDAY
2061 JDATEM=JDATE
2062 JMONTHM=JMONTH
2063 JYEARM=JYEAR
2064 TAUML=TAU
2065 TOFDAYML=TOFDAY
2066 #endif
2067 C
2068 if(JDAY.ne.JDAYLAST)then
2069 c print *,'co24ocean=',co24ocean(jm/2)
2070 if(JDATEPR.ne.0)then
2071 c WRITE (6,905) TOFDAY,JDATE,JMONTH,JYEAR
2072 WRITE (6,905) TOFDAYPR,JDATEPR,JMONTHPR,JYEARPR
2073 endif
2074 cjrs print *,'ncallclm=',ncallclm
2075 JDAYLAST=JDAY
2076 c if(ncallclm.gt.6) stop
2077 c stop
2078 endif
2079 return
2080 C CALL ENQJOB 309.
2081 C CALL ENQJOB 310.
2082 IF(KSS6.EQ.1) STOP 12 310.1
2083 IF(IPFLAG.EQ.0) STOP 13 311.
2084 STOP 1 312.
2085 C**** 313.
2086 901 FORMAT ('0CLIMATE MODEL STARTED UP',14X,'DAY',I5,', HR',F6.2,I6, 314.
2087 * A5,I27,I7,F7.1,' TAU',F9.2) 315.
2088 902 FORMAT (' DYNAMIC TERMS INTEGRATED, MRCH=',I1,4X,'DAY',I5, 316.
2089 * ', HR',F6.2,I6,A5,2I7,F7.1,23X,'TAU',F9.2) 317.
2090 903 FORMAT (' SOURCE TERMS INTEGRATED',64X,2I7,F7.1) 318.
2091 904 FORMAT ('0SENSE SWITCH 6 HAS BEEN TURNED ON.') 319.
2092 905 FORMAT (/1(1X,33('****')/)/ 320.
2093 c * ' PROGRAM HAS TERMINATED NORMALLY. TAU,IDAY,TOFDAY=',F9.2, 321.
2094 * ' ATM HAS TERMINATED NORMALLY. AT ',F9.2,I3,A5,i5,
2095 * /1(1X,33('****')/)) 322.
2096 906 FORMAT (' OUTPUT RECORD WRITTEN ON UNIT',I3,55X,2I7,F7.1, 323.
2097 * ' TAU',F9.2,' ON ',A4) 324.
2098 908 FORMAT (' OUTPUT RECORD WRITTEN ON UNIT',I3,79X,'TAU',F9.2, 325.
2099 * ' ON ',A4) 326.
2100 909 FORMAT (/'0TIME',F7.2,'(MINUTES) DYNAMICS',F5.1, 327.
2101 * ' CONDENSATION',F5.1,' RADIATION',F5.1,' SURFACE', 328.
2102 * F5.1,' DIAGNOSTICS',F5.1,' OTHER',F5.1//) 329.
2103 910 FORMAT (' INFORMATION WRITTEN ON UNIT 20',57X,2I7,F7.1, 330.
2104 * ' TAU',F9.2,' ON TAPE') 331.
2105 920 FORMAT ('1'/64(1X/)) 332.
2106 END 333.
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