source: trunk/LMDZ.MARS/libf/phymars/callradite.F @ 1242

Last change on this file since 1242 was 1226, checked in by aslmd, 11 years ago

LMDZ.MARS : Replaced comcstfi and planete includes by modules.

File size: 21.1 KB
Line 
1      SUBROUTINE callradite(icount,ngrid,nlayer,nq,zday,ls,pq,albedo,
2     $     emis,mu0,pplev,pplay,pt,tsurf,fract,dist_sol,igout,
3     $     dtlw,dtsw,fluxsurf_lw,fluxsurf_sw,fluxtop_lw,fluxtop_sw,
4     &     tauref,tau,aerosol,tauscaling,taucloudtes,rdust,rice,
5     &     nuice,co2ice)
6
7      use dimradmars_mod, only: ndomainsz, nflev, nsun, nir
8      use yomlw_h, only: gcp, nlaylte
9      USE comcstfi_h
10      IMPLICIT NONE
11c=======================================================================
12c   subject:
13c   --------
14c   Subroutine designed to call the main canonic
15c   radiative transfer subroutine "lwmain" et "swmain"
16c   to compute radiative heating and cooling rate and
17c   radiative fluxes to the surface.
18c
19c   These calculations are only valid on the part of the atmosphere
20c   where Local Thermal Equilibrium (NLTE) is verified. In practice
21c   The calculations are only performed for the first "nlaylte"
22c   parameters (nlaylte is calculated by subroutine "nlthermeq"
23c   and stored in module "yomlw_h").
24c
25c   The purpose of this subroutine is to:
26c      1) Make some initial calculation at first call
27c      2) Split the calculation in several sub-grid
28c        ("sub-domain") to save memory and
29c        be able run on a workstation at high resolution
30c        The sub-grid size is defined in dimradmars_mod
31c      3) Compute the 3D scattering parameters depending on the
32c        size distribution of the different tracers (added by JBM)
33c      4) call "lwmain" and "swmain"
34c
35c
36c   authors:   
37c   ------
38c   Francois Forget / Christophe Hourdin / J.-B. Madeleine (2009)
39c
40c
41c   3D scattering scheme user's guide (J.-B. Madeleine)
42c   ---------------------------------
43c
44c   This routine has been modified to take into account 3D, time
45c   dependent scattering properties of the aerosols.
46c---- The look-up tables that contain the scattering parameters
47c   of a given tracer, for different sizes, are read by SUAER.F90.
48c   The names of the corresponding ASCII files have to be set in
49c   this subroutine (file_id variable), and files must be in the
50c   directory specified in datafile.h. Please make sure that the
51c   ASCII files are correctly written, and that the range
52c   of particle sizes is consistent with what you would expect.
53c---- SUAER.F90 is in charge of reading the ASCII files and averaging
54c   the scattering parameters in each GCM channel, using the three last
55c   equations of Forget et al. 1998 (GRL 25, No.7, p.1105-1108).
56c---- These look-up tables, loaded during the firstcall, are then
57c   constantly used by the subroutine "aeroptproperties.F" to compute,
58c   online, the 3D scattering parameters, based on the size distribution
59c   (reffrad and nueffrad) of the different tracers, in each grid box.
60c   These 3D size distributions are loaded by the "updatereffrad.F"
61c   subroutine. A log-normal distribution is then assumed in
62c   "aeroptproperties.F", along with a Gauss-Legendre integration.
63c---- The optical depth at the visible reference wavelength (set in
64c   SUAER.F90, after the file_id variable) is then computed by
65c   the subroutine "aeropacity.F", by using the size and spatial
66c   distribution of the corresponding tracer. This connection has to
67c   be implemented in "aeropacity.F" when adding a new tracer. To do so,
68c   one can use equation 2 of Forget et al. 1998 (Icarus 131, p.302-316).
69c---- The resulting variables "aerosol", "QVISsQREF3d", "omegaVIS3d" and
70c   "gVIS3d" (same in the infrared) are finally used by lwmain.F and
71c   swmain.F to solve the radiative transfer equation.
72c
73c   changes:
74c   -------
75c
76c   > SRL 7/2000
77c   
78c   This version has been modified to only calculate radiative tendencies
79c   over layers 1..NFLEV (set in dimradmars_mod).  Returns zero for higher
80c   layers, if any.
81c   In other routines, nlayermx -> nflev.
82c   Routines affected: lwflux, lwi, lwmain, lwxb, lwxd, lwxn.
83c
84c   > J.-B. Madeleine 10W12
85c   This version uses the variable's splitting, which can be usefull
86c     when performing very high resolution simulation like LES.
87c
88c   ----------
89c   Here, solar band#1 is spectral interval between "long1vis" and "long2vis"
90c   set in dimradmars_mod
91c   Here, solar band#2 is spectral interval between "long2vis" and "long3vis"
92c   set in dimradmars_mod
93c
94c   input:
95c   -----
96c   icount                counter of call to subroutine physic by gcm
97c   ngrid                 number of gridpoint of horizontal grid
98c   nlayer                Number of layer
99c   nq                    Number of tracer
100c   ls                    Solar longitude (Ls) , radian
101c   zday                  Date (time since Ls=0, in martian days)
102c   pq(ngrid,nlayer,nq)   Advected fields
103c
104c   albedo (ngrid,2)      hemispheric surface albedo
105c                         albedo (i,1) : mean albedo for solar band#1
106c                                        (see below)
107c                         albedo (i,2) : mean albedo for solar band#2
108c                                        (see below)
109c   emis                  Thermal IR surface emissivity (no unit)
110c   mu0(ngrid)           cos of solar zenith angle
111c                           (=1 when sun at zenith)
112c   pplay(ngrid,nlayer)    pressure (Pa) in the middle of each layer
113c   pplev(ngrid,nlayer+1)  pressure (Pa) at boundaries of each layer
114c   pt(ngrid,nlayer)       atmospheric temperature in each layer (K)
115c   tsurf(ngrid)           surface temperature (K)
116c   fract(ngrid)         day fraction of the time interval
117c                          =1 during the full day ; =0 during the night
118c   declin                 latitude of subsolar point
119c   dist_sol               sun-Mars distance (AU)
120c   igout                  coordinate of analysed point for debugging
121c   reffrad(ngrid,nlayer,naerkind)  Aerosol effective radius
122c   nueffrad(ngrid,nlayer,naerkind) Aerosol effective variance
123
124c
125c  output:
126c  -------
127c dtlw (ngrid,nlayer)       longwave (IR) heating rate (K/s)
128c dtsw(ngrid,nlayer)        shortwave (Solar) heating rate (K/s)
129c fluxsurf_lw(ngrid)        surface downward flux tota LW (thermal IR) (W.m-2)
130c fluxsurf_sw(ngrid,1)      surface downward flux SW for solar band#1 (W.m-2)
131c fluxsurf_sw(ngrid,2)      surface downward flux SW for solar band#2 (W.m-2)
132c
133c fluxtop_lw(ngrid)         outgoing upward flux tota LW (thermal IR) (W.m-2)
134c fluxtop_sw(ngrid,1)       outgoing upward flux SW for solar band#1 (W.m-2)
135c fluxtop_sw(ngrid,2)       outgoing upward flux SW for solar band#2 (W.m-2)
136
137c   tauref       Prescribed mean column optical depth at 610 Pa
138c   tau          Column total visible dust optical depth at each point
139c   aerosol(ngrid,nlayer,naerkind)    aerosol extinction optical depth
140c                         at reference wavelength "longrefvis" set
141c                         in dimradmars_h , in each layer, for one of
142c                         the "naerkind" kind of aerosol optical
143c                         properties.
144
145c=======================================================================
146c
147c    Declarations :
148c    -------------
149c
150!#include "dimensions.h"
151!#include "dimphys.h"
152!#include "dimradmars.h"
153#include "callkeys.h"
154!#include "yomlw.h"
155! naerkind is set in scatterers.h (built when compiling with makegcm -s #)
156#include"scatterers.h"
157#include "aerkind.h"
158
159c-----------------------------------------------------------------------
160c    Input/Output
161c    ------------
162      INTEGER,INTENT(IN) :: icount       
163      INTEGER,INTENT(IN) :: ngrid,nlayer,nq
164      INTEGER,INTENT(IN) :: igout
165
166      REAL,INTENT(IN) :: pq(ngrid,nlayer,nq)
167      REAL,INTENT(IN) :: tauscaling(ngrid) ! Conversion factor for
168                               ! qdust and Ndust
169      REAL,INTENT(IN) :: albedo(ngrid,2),emis(ngrid)
170      REAL,INTENT(IN) :: ls,zday
171
172      REAL,INTENT(IN) :: pplev(ngrid,nlayer+1),pplay(ngrid,nlayer)
173      REAL,INTENT(IN) :: pt(ngrid,nlayer)
174      REAL,INTENT(IN) :: tsurf(ngrid)
175      REAL,INTENT(IN) :: dist_sol,mu0(ngrid),fract(ngrid)
176      REAL,INTENT(OUT) :: dtlw(ngrid,nlayer),dtsw(ngrid,nlayer)
177      REAL,INTENT(OUT) :: fluxsurf_lw(ngrid), fluxtop_lw(ngrid)
178      REAL,INTENT(OUT) :: fluxsurf_sw(ngrid,2), fluxtop_sw(ngrid,2)
179
180      REAL,INTENT(OUT) :: tauref(ngrid), tau(ngrid,naerkind)
181      REAL,INTENT(OUT) :: taucloudtes(ngrid)! Cloud opacity at infrared
182                               !   reference wavelength using
183                               !   Qabs instead of Qext
184                               !   (direct comparison with TES)
185      REAL,INTENT(OUT) :: aerosol(ngrid,nlayer,naerkind)
186      REAL,INTENT(OUT) :: rdust(ngrid,nlayer)  ! Dust geometric mean radius (m)
187      REAL,INTENT(OUT) :: rice(ngrid,nlayer)   ! Ice geometric mean radius (m)
188      REAL,INTENT(OUT) :: nuice(ngrid,nlayer)  ! Estimated effective variance
189      REAL,INTENT(IN) :: co2ice(ngrid)           ! co2 ice surface layer (kg.m-2)
190
191c
192c    Local variables :
193c    -----------------
194
195      INTEGER j,l,ig,n,ich
196      INTEGER aer_count,iaer
197      INTEGER jd,ig0,nd
198
199      real  cste_mars ! solar constant on Mars (Wm-2)
200      REAL ptlev(ngrid,nlayer+1)
201
202      INTEGER,SAVE :: ndomain
203
204c     Thermal IR net radiative budget (W m-2)
205
206      real znetrad(ndomainsz,nflev)
207
208      real zfluxd_sw(ndomainsz,nflev+1,2)
209      real zfluxu_sw(ndomainsz,nflev+1,2)
210
211      REAL zplev(ndomainsz,nflev+1)
212      REAL zztlev(ndomainsz,nflev+1)
213      REAL zplay(ndomainsz,nflev)
214      REAL zt(ndomainsz,nflev)
215      REAL zaerosol(ndomainsz,nflev,naerkind)
216      REAL zalbedo(ndomainsz,2)
217      REAL zdp(ndomainsz,nflev)
218      REAL zdt0(ndomainsz)
219
220      REAL zzdtlw(ndomainsz,nflev)
221      REAL zzdtsw(ndomainsz,nflev)
222      REAL zzflux(ndomainsz,6)
223      real zrmuz
224
225      REAL :: zQVISsQREF3d(ndomainsz,nflev,nsun,naerkind)
226      REAL :: zomegaVIS3d(ndomainsz,nflev,nsun,naerkind)
227      REAL :: zgVIS3d(ndomainsz,nflev,nsun,naerkind)
228
229      REAL :: zQIRsQREF3d(ndomainsz,nflev,nir,naerkind)
230      REAL :: zomegaIR3d(ndomainsz,nflev,nir,naerkind)
231      REAL :: zgIR3d(ndomainsz,nflev,nir,naerkind)
232
233c     Aerosol size distribution
234      REAL :: reffrad(ngrid,nlayer,naerkind)
235      REAL :: nueffrad(ngrid,nlayer,naerkind)
236c     Aerosol optical properties
237      REAL :: QVISsQREF3d(ngrid,nlayer,nsun,naerkind)
238      REAL :: omegaVIS3d(ngrid,nlayer,nsun,naerkind)
239      REAL :: gVIS3d(ngrid,nlayer,nsun,naerkind)
240
241      REAL :: QIRsQREF3d(ngrid,nlayer,nir,naerkind)
242      REAL :: omegaIR3d(ngrid,nlayer,nir,naerkind)
243      REAL :: gIR3d(ngrid,nlayer,nir,naerkind)
244
245      REAL :: QREFvis3d(ngrid,nlayer,naerkind)
246      REAL :: QREFir3d(ngrid,nlayer,naerkind)
247
248      REAL :: omegaREFvis3d(ngrid,nlayer,naerkind)
249      REAL :: omegaREFir3d(ngrid,nlayer,naerkind)
250
251c   local saved variables
252c   ---------------------
253
254      real,save,allocatable :: pview(:)
255     
256      real zco2   ! volume fraction of CO2 in Mars atmosphere
257      DATA zco2/0.95/
258      SAVE zco2
259
260      LOGICAL firstcall
261      DATA firstcall/.true./
262      SAVE firstcall
263
264c----------------------------------------------------------------------
265
266c     Initialisation
267c     --------------
268
269      IF (firstcall) THEN
270        ! compute ndomain and allocate local saved arrays
271        ndomain= (ngrid-1) / ndomainsz + 1
272        allocate(pview(ngrid))
273
274c        Please name the different scatterers here ----------------
275c        PLEASE MAKE SURE that you set up the right number of
276c          scatterers in scatterers.h (naerkind);
277          name_iaer(1) = "dust_conrath"   !! default choice is good old Conrath profile
278          IF (doubleq.AND.active) name_iaer(1) = "dust_doubleq" !! two-moment scheme
279          if (nq.gt.1) then
280           ! trick to avoid problems compiling with 1 tracer
281           ! and picky compilers who know name_iaer(2) is out of bounds
282           j=2
283          IF (water.AND.activice) name_iaer(j) = "h2o_ice"      !! radiatively-active clouds
284          IF (submicron.AND.active) name_iaer(j) = "dust_submicron" !! JBM experimental stuff
285          endif ! of if (nq.gt.1)
286c        ----------------------------------------------------------
287
288c        Assign a number to the different scatterers
289c        -------------------------------------------
290
291         iaer_dust_conrath=0
292         iaer_dust_doubleq=0
293         iaer_dust_submicron=0
294         iaer_h2o_ice=0
295
296         aer_count=0
297         if (.NOT.active) then
298           do iaer=1,naerkind
299             if (name_iaer(iaer).eq."dust_conrath") then
300               iaer_dust_conrath = iaer
301               aer_count = aer_count + 1
302             endif
303           enddo
304         endif
305         if (doubleq.AND.active) then
306           do iaer=1,naerkind
307             if (name_iaer(iaer).eq."dust_doubleq") then
308               iaer_dust_doubleq = iaer
309               aer_count = aer_count + 1
310             endif
311           enddo
312         endif
313         if (submicron.AND.active) then
314           do iaer=1,naerkind
315             if (name_iaer(iaer).eq."dust_submicron") then
316               iaer_dust_submicron = iaer
317               aer_count = aer_count + 1
318             endif
319           enddo
320         endif
321         if (water.AND.activice) then
322           do iaer=1,naerkind
323             if (name_iaer(iaer).eq."h2o_ice") then
324               iaer_h2o_ice = iaer
325               aer_count = aer_count + 1
326             endif
327           enddo
328         endif
329
330c        Check that we identified all tracers:
331         if (aer_count.ne.naerkind) then
332           write(*,*) "callradite: found only ",aer_count," scatterers"
333           write(*,*) "               expected ",naerkind
334           write(*,*) "please make sure that the number of"
335           write(*,*) "scatterers in scatterers.h, the names"
336           write(*,*) "in callradite.F, and the flags in"
337           write(*,*) "callphys.def are all consistent!"
338           do iaer=1,naerkind
339             write(*,*)'      ',iaer,' ',trim(name_iaer(iaer))
340           enddo
341           stop
342         else
343           write(*,*) "callradite: found all scatterers, namely:"
344           do iaer=1,naerkind
345             write(*,*)'      ',iaer,' ',trim(name_iaer(iaer))
346           enddo
347         endif
348c        -------------------------------------------
349
350         DO ig=1,ngrid
351            pview(ig)=1.66     ! cosecant of viewing angle
352         ENDDO
353         gcp = g/cpp
354
355c        Logical tests for radiatively active water-ice clouds:
356         IF ( (activice.AND.(.NOT.water)).OR.
357     &        (activice.AND.(naerkind.LT.2)) ) THEN
358           WRITE(*,*) 'If activice is TRUE, water has to be set'
359           WRITE(*,*) 'to TRUE, and "naerkind" must be at least'
360           WRITE(*,*) 'equal to 2 in scatterers.h.'
361           CALL ABORT
362         ELSE IF ( (.NOT.activice).AND.(naerkind.GT.1) ) THEN
363           WRITE(*,*) 'naerkind is greater than unity, but'
364           WRITE(*,*) 'activice has not been set to .true.'
365           WRITE(*,*) 'in callphys.def; this is not logical!'
366           CALL ABORT
367         ENDIF
368
369c        Loading the optical properties in external look-up tables:
370         CALL SUAER
371!         CALL SULW ! this step is now done in ini_yomlw_h
372
373         write(*,*) 'Splitting radiative calculations: ',
374     $              ' ngrid,ndomainsz,ndomain',
375     $                ngrid,ndomainsz,ndomain
376         if (ngrid .EQ. 1) then
377           if (ndomainsz .NE. 1) then
378             print*
379             print*,'ATTENTION !!!'
380             print*,'pour tourner en 1D, '
381             print*,'fixer ndomainsz=1 dans phymars/dimradmars_h'
382             print*
383             call exit(1)
384           endif
385         endif
386         firstcall=.false.
387      END IF
388
389c     Computing aerosol optical properties and opacity
390c     ------------------------------------------------
391
392c     Updating aerosol size distributions:
393      CALL updatereffrad(ngrid,nlayer,
394     &                rdust,rice,nuice,
395     &                reffrad,nueffrad,
396     &                pq,tauscaling,tau,pplay)
397
398c     Computing 3D scattering parameters:
399      CALL aeroptproperties(ngrid,nlayer,reffrad,nueffrad,
400     &                      QVISsQREF3d,omegaVIS3d,gVIS3d,
401     &                      QIRsQREF3d,omegaIR3d,gIR3d,
402     &                      QREFvis3d,QREFir3d,
403     &                      omegaREFvis3d,omegaREFir3d)
404
405c     Computing aerosol optical depth in each layer:
406      CALL aeropacity(ngrid,nlayer,nq,zday,pplay,pplev,ls,
407     &      pq,tauscaling,tauref,tau,taucloudtes,aerosol,reffrad,
408     &      nueffrad,QREFvis3d,QREFir3d,omegaREFvis3d,omegaREFir3d)
409
410c     Starting loop on sub-domain
411c     ----------------------------
412
413      DO jd=1,ndomain
414        ig0=(jd-1)*ndomainsz
415        if (jd.eq.ndomain) then
416         nd=ngrid-ig0
417        else
418         nd=ndomainsz
419        endif
420
421c       Spliting input variable in sub-domain input variables
422c       ---------------------------------------------------
423
424        do l=1,nlaylte
425         do ig = 1,nd
426           do iaer = 1, naerkind
427             do ich = 1, nsun
428               zQVISsQREF3d(ig,l,ich,iaer) =
429     &                           QVISsQREF3d(ig0+ig,l,ich,iaer)
430               zomegaVIS3d(ig,l,ich,iaer) =
431     &                           omegaVIS3d(ig0+ig,l,ich,iaer)
432               zgVIS3d(ig,l,ich,iaer) =
433     &                           gVIS3d(ig0+ig,l,ich,iaer)
434             enddo
435             do ich = 1, nir
436               zQIRsQREF3d(ig,l,ich,iaer) =
437     &                           QIRsQREF3d(ig0+ig,l,ich,iaer)
438               zomegaIR3d(ig,l,ich,iaer) =
439     &                           omegaIR3d(ig0+ig,l,ich,iaer)
440               zgIR3d(ig,l,ich,iaer) =
441     &                           gIR3d(ig0+ig,l,ich,iaer)
442             enddo
443           enddo
444         enddo
445        enddo
446
447        do l=1,nlaylte+1
448         do ig = 1,nd
449          zplev(ig,l) = pplev(ig0+ig,l)
450         enddo
451        enddo
452
453        do l=1,nlaylte
454         do ig = 1,nd
455          zplay(ig,l) = pplay(ig0+ig,l)
456          zt(ig,l) = pt(ig0+ig,l)
457c         Thickness of each layer (Pa) :
458          zdp(ig,l)= pplev(ig0+ig,l) - pplev(ig0+ig,l+1)
459         enddo
460        enddo
461
462        do n=1,naerkind
463          do l=1,nlaylte
464            do ig=1,nd
465              zaerosol(ig,l,n) = aerosol(ig0+ig,l,n)
466            enddo
467          enddo
468        enddo
469
470        do j=1,2
471          do ig = 1,nd
472           zalbedo(ig,j) = albedo(ig0+ig,j)
473          enddo
474        enddo
475
476c       Intermediate  levels: (computing tlev)
477c       ---------------------------------------
478c       Extrapolation for the air temperature above the surface
479        DO ig=1,nd
480              zztlev(ig,1)=zt(ig,1)+
481     s        (zplev(ig,1)-zplay(ig,1))*
482     s        (zt(ig,1)-zt(ig,2))/(zplay(ig,1)-zplay(ig,2))
483
484              zdt0(ig) = tsurf(ig0+ig) - zztlev(ig,1)
485        ENDDO
486
487        DO l=2,nlaylte
488         DO ig=1, nd
489               zztlev(ig,l)=0.5*(zt(ig,l-1)+zt(ig,l))
490         ENDDO
491        ENDDO
492
493        DO ig=1, nd
494           zztlev(ig,nlaylte+1)=zt(ig,nlaylte)
495        ENDDO
496
497
498c       Longwave ("lw") radiative transfer (= thermal infrared)
499c       -------------------------------------------------------
500        call lwmain (ig0,icount,nd,nflev
501     .        ,zdp,zdt0,emis(ig0+1),zplev,zztlev,zt
502     .        ,zaerosol,zzdtlw
503     .        ,fluxsurf_lw(ig0+1),fluxtop_lw(ig0+1)
504     .        ,znetrad
505     &        ,zQIRsQREF3d,zomegaIR3d,zgIR3d
506     &        ,co2ice(ig0+1))
507
508c       Shortwave ("sw") radiative transfer (= solar radiation)
509c       -------------------------------------------------------
510c          Mars solar constant (W m-2)
511c          1370 W.m-2 is the solar constant at 1 AU.
512           cste_mars=1370./(dist_sol*dist_sol)
513
514           call swmain ( nd, nflev,
515     S     cste_mars, zalbedo,
516     S     mu0(ig0+1), zdp, zplev, zaerosol, fract(ig0+1),
517     S     zzdtsw, zfluxd_sw, zfluxu_sw,
518     &     zQVISsQREF3d,zomegaVIS3d,zgVIS3d)
519
520c       ------------------------------------------------------------
521c       Un-spliting output variable from sub-domain input variables
522c       ------------------------------------------------------------
523
524        do l=1,nlaylte
525         do ig = 1,nd
526          dtlw(ig0+ig,l) = zzdtlw(ig,l)
527          dtsw(ig0+ig,l) = zzdtsw(ig,l)
528         enddo
529        enddo
530
531        do l=1,nlaylte+1
532         do ig = 1,nd
533          ptlev(ig0+ig,l) = zztlev(ig,l)
534         enddo
535        enddo
536
537        do ig = 1,nd
538          fluxsurf_sw(ig0+ig,1) = zfluxd_sw(ig,1,1)
539          fluxsurf_sw(ig0+ig,2) = zfluxd_sw(ig,1,2)
540          fluxtop_sw(ig0+ig,1) = zfluxu_sw(ig,nlaylte+1,1)
541          fluxtop_sw(ig0+ig,2) = zfluxu_sw(ig,nlaylte+1,2)
542        enddo
543
544      ENDDO         !   (boucle jd=1, ndomain)
545
546c     Zero tendencies for any remaining layers between nlaylte and nlayer
547      if (nlayer.gt.nlaylte) then
548         do l = nlaylte+1, nlayer
549            do ig = 1, ngrid
550               dtlw(ig, l) = 0.
551               dtsw(ig, l) = 0.
552            enddo
553         enddo
554      endif
555
556c     Output for debugging if lwrite=T
557c     --------------------------------
558c     Write all nlayer layers, even though only nlaylte layers may have
559c     non-zero tendencies.
560
561         IF(lwrite) THEN
562            PRINT*,'Diagnotique for the radiation'
563            PRINT*,'albedo, emissiv, mu0,fract,fluxsurf_lw,fluxsurf_sw'
564            PRINT*,albedo(igout,1),emis(igout),mu0(igout),
565     s           fract(igout), fluxsurf_lw(igout),
566     $     fluxsurf_sw(igout,1)+fluxsurf_sw(igout,2)
567            PRINT*,'Tlay Tlev Play Plev dT/dt SW dT/dt LW (K/s)'
568            PRINT*,'daysec',daysec
569            DO l=1,nlayer
570               PRINT*,pt(igout,l),ptlev(igout,l),
571     s         pplay(igout,l),pplev(igout,l),
572     s         dtsw(igout,l),dtlw(igout,l)
573            ENDDO
574         ENDIF
575
576
577      return
578      end
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