source: LMDZ6/branches/Ocean_skin/libf/phylmd/cloudth_mod.F90 @ 5185

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1MODULE cloudth_mod
2
3  IMPLICIT NONE
4
5CONTAINS
6
7       SUBROUTINE cloudth(ngrid,klev,ind2,  &
8     &           ztv,po,zqta,fraca, &
9     &           qcloud,ctot,zpspsk,paprs,pplay,ztla,zthl, &
10     &           ratqs,zqs,t)
11
12
13      IMPLICIT NONE
14
15
16!===========================================================================
17! Auteur : Arnaud Octavio Jam (LMD/CNRS)
18! Date : 25 Mai 2010
19! Objet : calcule les valeurs de qc et rneb dans les thermiques
20!===========================================================================
21
22
23#include "YOMCST.h"
24#include "YOETHF.h"
25#include "FCTTRE.h"
26#include "nuage.h"
27
28      INTEGER itap,ind1,ind2
29      INTEGER ngrid,klev,klon,l,ig
30     
31      REAL ztv(ngrid,klev)
32      REAL po(ngrid)
33      REAL zqenv(ngrid)   
34      REAL zqta(ngrid,klev)
35         
36      REAL fraca(ngrid,klev+1)
37      REAL zpspsk(ngrid,klev)
38      REAL paprs(ngrid,klev+1)
39      REAL pplay(ngrid,klev)
40      REAL ztla(ngrid,klev)
41      REAL zthl(ngrid,klev)
42
43      REAL zqsatth(ngrid,klev)
44      REAL zqsatenv(ngrid,klev)
45     
46     
47      REAL sigma1(ngrid,klev)
48      REAL sigma2(ngrid,klev)
49      REAL qlth(ngrid,klev)
50      REAL qlenv(ngrid,klev)
51      REAL qltot(ngrid,klev)
52      REAL cth(ngrid,klev) 
53      REAL cenv(ngrid,klev)   
54      REAL ctot(ngrid,klev)
55      REAL rneb(ngrid,klev)
56      REAL t(ngrid,klev)
57      REAL qsatmmussig1,qsatmmussig2,sqrt2pi,pi
58      REAL rdd,cppd,Lv
59      REAL alth,alenv,ath,aenv
60      REAL sth,senv,sigma1s,sigma2s,xth,xenv
61      REAL Tbef,zdelta,qsatbef,zcor
62      REAL qlbef 
63      REAL ratqs(ngrid,klev) ! determine la largeur de distribution de vapeur
64     
65      REAL zpdf_sig(ngrid),zpdf_k(ngrid),zpdf_delta(ngrid)
66      REAL zpdf_a(ngrid),zpdf_b(ngrid),zpdf_e1(ngrid),zpdf_e2(ngrid)
67      REAL zqs(ngrid), qcloud(ngrid)
68      REAL erf
69
70
71
72
73!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
74! Gestion de deux versions de cloudth
75!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
76
77      IF (iflag_cloudth_vert.GE.1) THEN
78      CALL cloudth_vert(ngrid,klev,ind2,  &
79     &           ztv,po,zqta,fraca, &
80     &           qcloud,ctot,zpspsk,paprs,pplay,ztla,zthl, &
81     &           ratqs,zqs,t)
82      RETURN
83      ENDIF
84!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
85
86
87!-------------------------------------------------------------------------------
88! Initialisation des variables r?elles
89!-------------------------------------------------------------------------------
90      sigma1(:,:)=0.
91      sigma2(:,:)=0.
92      qlth(:,:)=0.
93      qlenv(:,:)=0. 
94      qltot(:,:)=0.
95      rneb(:,:)=0.
96      qcloud(:)=0.
97      cth(:,:)=0.
98      cenv(:,:)=0.
99      ctot(:,:)=0.
100      qsatmmussig1=0.
101      qsatmmussig2=0.
102      rdd=287.04
103      cppd=1005.7
104      pi=3.14159
105      Lv=2.5e6
106      sqrt2pi=sqrt(2.*pi)
107
108
109
110!-------------------------------------------------------------------------------
111! Calcul de la fraction du thermique et des ?cart-types des distributions
112!-------------------------------------------------------------------------------                 
113      do ind1=1,ngrid
114
115      if ((ztv(ind1,1).gt.ztv(ind1,2)).and.(fraca(ind1,ind2).gt.1.e-10)) then
116
117      zqenv(ind1)=(po(ind1)-fraca(ind1,ind2)*zqta(ind1,ind2))/(1.-fraca(ind1,ind2))
118
119
120!      zqenv(ind1)=po(ind1)
121      Tbef=zthl(ind1,ind2)*zpspsk(ind1,ind2)
122      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
123      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
124      qsatbef=MIN(0.5,qsatbef)
125      zcor=1./(1.-retv*qsatbef)
126      qsatbef=qsatbef*zcor
127      zqsatenv(ind1,ind2)=qsatbef
128
129
130
131
132      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2) 
133      aenv=1./(1.+(alenv*Lv/cppd))
134      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))
135
136
137
138
139      Tbef=ztla(ind1,ind2)*zpspsk(ind1,ind2)
140      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
141      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
142      qsatbef=MIN(0.5,qsatbef)
143      zcor=1./(1.-retv*qsatbef)
144      qsatbef=qsatbef*zcor
145      zqsatth(ind1,ind2)=qsatbef
146           
147      alth=(0.622*Lv*zqsatth(ind1,ind2))/(rdd*ztla(ind1,ind2)**2)   
148      ath=1./(1.+(alth*Lv/cppd))
149      sth=ath*(zqta(ind1,ind2)-zqsatth(ind1,ind2))
150     
151     
152
153!------------------------------------------------------------------------------
154! Calcul des ?cart-types pour s
155!------------------------------------------------------------------------------
156
157!      sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+ratqs(ind1,ind2)*po(ind1)
158!      sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.4+0.002*zqta(ind1,ind2)
159!       if (paprs(ind1,ind2).gt.90000) then
160!       ratqs(ind1,ind2)=0.002
161!       else
162!       ratqs(ind1,ind2)=0.002+0.0*(90000-paprs(ind1,ind2))/20000
163!       endif
164       sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+0.002*po(ind1)
165       sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.01)**0.4+0.002*zqta(ind1,ind2)
166!       sigma1s=ratqs(ind1,ind2)*po(ind1)
167!      sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.4+0.00003 
168 
169!------------------------------------------------------------------------------
170! Calcul de l'eau condens?e et de la couverture nuageuse
171!------------------------------------------------------------------------------
172      sqrt2pi=sqrt(2.*pi)
173      xth=sth/(sqrt(2.)*sigma2s)
174      xenv=senv/(sqrt(2.)*sigma1s)
175      cth(ind1,ind2)=0.5*(1.+1.*erf(xth))
176      cenv(ind1,ind2)=0.5*(1.+1.*erf(xenv))
177      ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)   
178
179      qlth(ind1,ind2)=sigma2s*((exp(-1.*xth**2)/sqrt2pi)+xth*sqrt(2.)*cth(ind1,ind2))
180      qlenv(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2))   
181      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
182
183!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
184      if (ctot(ind1,ind2).lt.1.e-10) then
185      ctot(ind1,ind2)=0.
186      qcloud(ind1)=zqsatenv(ind1,ind2)
187
188      else   
189               
190      ctot(ind1,ind2)=ctot(ind1,ind2)
191      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqs(ind1)
192
193      endif                           
194     
195         
196!     print*,sth,sigma2s,qlth(ind1,ind2),ctot(ind1,ind2),qltot(ind1,ind2),'verif'
197
198
199      else  ! gaussienne environnement seule
200     
201      zqenv(ind1)=po(ind1)
202      Tbef=t(ind1,ind2)
203      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
204      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
205      qsatbef=MIN(0.5,qsatbef)
206      zcor=1./(1.-retv*qsatbef)
207      qsatbef=qsatbef*zcor
208      zqsatenv(ind1,ind2)=qsatbef
209     
210
211!      qlbef=Max(po(ind1)-zqsatenv(ind1,ind2),0.)
212      zthl(ind1,ind2)=t(ind1,ind2)*(101325/paprs(ind1,ind2))**(rdd/cppd)
213      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2) 
214      aenv=1./(1.+(alenv*Lv/cppd))
215      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))
216     
217
218      sigma1s=ratqs(ind1,ind2)*zqenv(ind1)
219
220      sqrt2pi=sqrt(2.*pi)
221      xenv=senv/(sqrt(2.)*sigma1s)
222      ctot(ind1,ind2)=0.5*(1.+1.*erf(xenv))
223      qltot(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2))
224     
225      if (ctot(ind1,ind2).lt.1.e-3) then
226      ctot(ind1,ind2)=0.
227      qcloud(ind1)=zqsatenv(ind1,ind2)
228
229      else   
230               
231      ctot(ind1,ind2)=ctot(ind1,ind2)
232      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqsatenv(ind1,ind2)
233
234      endif   
235 
236 
237 
238 
239 
240 
241      endif   
242      enddo
243     
244      return
245!     end
246END SUBROUTINE cloudth
247
248
249
250!===========================================================================
251     SUBROUTINE cloudth_vert(ngrid,klev,ind2,  &
252     &           ztv,po,zqta,fraca, &
253     &           qcloud,ctot,zpspsk,paprs,pplay,ztla,zthl, &
254     &           ratqs,zqs,t)
255
256!===========================================================================
257! Auteur : Arnaud Octavio Jam (LMD/CNRS)
258! Date : 25 Mai 2010
259! Objet : calcule les valeurs de qc et rneb dans les thermiques
260!===========================================================================
261
262
263      USE ioipsl_getin_p_mod, ONLY : getin_p
264
265      IMPLICIT NONE
266
267#include "YOMCST.h"
268#include "YOETHF.h"
269#include "FCTTRE.h"
270#include "nuage.h"
271     
272      INTEGER itap,ind1,ind2
273      INTEGER ngrid,klev,klon,l,ig
274     
275      REAL ztv(ngrid,klev)
276      REAL po(ngrid)
277      REAL zqenv(ngrid)   
278      REAL zqta(ngrid,klev)
279         
280      REAL fraca(ngrid,klev+1)
281      REAL zpspsk(ngrid,klev)
282      REAL paprs(ngrid,klev+1)
283      REAL pplay(ngrid,klev)
284      REAL ztla(ngrid,klev)
285      REAL zthl(ngrid,klev)
286
287      REAL zqsatth(ngrid,klev)
288      REAL zqsatenv(ngrid,klev)
289     
290     
291      REAL sigma1(ngrid,klev)                                                         
292      REAL sigma2(ngrid,klev)
293      REAL qlth(ngrid,klev)
294      REAL qlenv(ngrid,klev)
295      REAL qltot(ngrid,klev)
296      REAL cth(ngrid,klev) 
297      REAL cenv(ngrid,klev)   
298      REAL ctot(ngrid,klev)
299      REAL rneb(ngrid,klev)
300      REAL t(ngrid,klev)                                                                 
301      REAL qsatmmussig1,qsatmmussig2,sqrt2pi,pi
302      REAL rdd,cppd,Lv,sqrt2,sqrtpi
303      REAL alth,alenv,ath,aenv
304      REAL sth,senv,sigma1s,sigma2s,xth,xenv
305      REAL xth1,xth2,xenv1,xenv2,deltasth, deltasenv
306      REAL IntJ,IntI1,IntI2,IntI3,coeffqlenv,coeffqlth
307      REAL Tbef,zdelta,qsatbef,zcor
308      REAL qlbef 
309      REAL ratqs(ngrid,klev) ! determine la largeur de distribution de vapeur
310      ! Change the width of the PDF used for vertical subgrid scale heterogeneity
311      ! (J Jouhaud, JL Dufresne, JB Madeleine)
312      REAL,SAVE :: vert_alpha
313      !$OMP THREADPRIVATE(vert_alpha)
314      LOGICAL, SAVE :: firstcall = .TRUE.
315      !$OMP THREADPRIVATE(firstcall)
316     
317      REAL zpdf_sig(ngrid),zpdf_k(ngrid),zpdf_delta(ngrid)
318      REAL zpdf_a(ngrid),zpdf_b(ngrid),zpdf_e1(ngrid),zpdf_e2(ngrid)
319      REAL zqs(ngrid), qcloud(ngrid)
320      REAL erf
321
322!------------------------------------------------------------------------------
323! Initialisation des variables r?elles
324!------------------------------------------------------------------------------
325      sigma1(:,:)=0.
326      sigma2(:,:)=0.
327      qlth(:,:)=0.
328      qlenv(:,:)=0. 
329      qltot(:,:)=0.
330      rneb(:,:)=0.
331      qcloud(:)=0.
332      cth(:,:)=0.
333      cenv(:,:)=0.
334      ctot(:,:)=0.
335      qsatmmussig1=0.
336      qsatmmussig2=0.
337      rdd=287.04
338      cppd=1005.7
339      pi=3.14159
340      Lv=2.5e6
341      sqrt2pi=sqrt(2.*pi)
342      sqrt2=sqrt(2.)
343      sqrtpi=sqrt(pi)
344
345      IF (firstcall) THEN
346        vert_alpha=0.5
347        CALL getin_p('cloudth_vert_alpha',vert_alpha)
348        WRITE(*,*) 'cloudth_vert_alpha = ', vert_alpha
349        firstcall=.FALSE.
350      ENDIF
351
352!-------------------------------------------------------------------------------
353! Calcul de la fraction du thermique et des ?cart-types des distributions
354!-------------------------------------------------------------------------------                 
355      do ind1=1,ngrid
356
357      if ((ztv(ind1,1).gt.ztv(ind1,2)).and.(fraca(ind1,ind2).gt.1.e-10)) then
358
359      zqenv(ind1)=(po(ind1)-fraca(ind1,ind2)*zqta(ind1,ind2))/(1.-fraca(ind1,ind2))
360
361
362!      zqenv(ind1)=po(ind1)
363      Tbef=zthl(ind1,ind2)*zpspsk(ind1,ind2)
364      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
365      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
366      qsatbef=MIN(0.5,qsatbef)
367      zcor=1./(1.-retv*qsatbef)
368      qsatbef=qsatbef*zcor
369      zqsatenv(ind1,ind2)=qsatbef
370
371
372
373
374      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2) 
375      aenv=1./(1.+(alenv*Lv/cppd))
376      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))
377
378
379
380
381      Tbef=ztla(ind1,ind2)*zpspsk(ind1,ind2)
382      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
383      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
384      qsatbef=MIN(0.5,qsatbef)
385      zcor=1./(1.-retv*qsatbef)
386      qsatbef=qsatbef*zcor
387      zqsatth(ind1,ind2)=qsatbef
388           
389      alth=(0.622*Lv*zqsatth(ind1,ind2))/(rdd*ztla(ind1,ind2)**2)   
390      ath=1./(1.+(alth*Lv/cppd))
391      sth=ath*(zqta(ind1,ind2)-zqsatth(ind1,ind2))
392     
393     
394
395!------------------------------------------------------------------------------
396! Calcul des ?cart-types pour s
397!------------------------------------------------------------------------------
398
399      sigma1s=(0.92**0.5)*(fraca(ind1,ind2)**0.5)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+ratqs(ind1,ind2)*po(ind1)
400      sigma2s=0.09*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.5+0.002*zqta(ind1,ind2)
401!       if (paprs(ind1,ind2).gt.90000) then
402!       ratqs(ind1,ind2)=0.002
403!       else
404!       ratqs(ind1,ind2)=0.002+0.0*(90000-paprs(ind1,ind2))/20000
405!       endif
406!       sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+0.002*po(ind1)
407!       sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.01)**0.4+0.002*zqta(ind1,ind2)
408!       sigma1s=ratqs(ind1,ind2)*po(ind1)
409!      sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.4+0.00003 
410 
411!------------------------------------------------------------------------------
412! Calcul de l'eau condens?e et de la couverture nuageuse
413!------------------------------------------------------------------------------
414      sqrt2pi=sqrt(2.*pi)
415      xth=sth/(sqrt(2.)*sigma2s)
416      xenv=senv/(sqrt(2.)*sigma1s)
417      cth(ind1,ind2)=0.5*(1.+1.*erf(xth))
418      cenv(ind1,ind2)=0.5*(1.+1.*erf(xenv))
419      ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)   
420
421      qlth(ind1,ind2)=sigma2s*((exp(-1.*xth**2)/sqrt2pi)+xth*sqrt(2.)*cth(ind1,ind2))
422      qlenv(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2))   
423      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
424     
425       IF (iflag_cloudth_vert == 1) THEN
426!-------------------------------------------------------------------------------
427!  Version 2: Modification selon J.-Louis. On condense ?? partir de qsat-ratqs
428!-------------------------------------------------------------------------------
429!      deltasenv=aenv*ratqs(ind1,ind2)*po(ind1)
430!      deltasth=ath*ratqs(ind1,ind2)*zqta(ind1,ind2)
431      deltasenv=aenv*ratqs(ind1,ind2)*zqsatenv(ind1,ind2)
432      deltasth=ath*ratqs(ind1,ind2)*zqsatth(ind1,ind2)
433!      deltasenv=aenv*0.01*po(ind1)
434!     deltasth=ath*0.01*zqta(ind1,ind2)   
435      xenv1=(senv-deltasenv)/(sqrt(2.)*sigma1s)
436      xenv2=(senv+deltasenv)/(sqrt(2.)*sigma1s)
437      xth1=(sth-deltasth)/(sqrt(2.)*sigma2s)
438      xth2=(sth+deltasth)/(sqrt(2.)*sigma2s)
439      coeffqlenv=(sigma1s)**2/(2*sqrtpi*deltasenv)
440      coeffqlth=(sigma2s)**2/(2*sqrtpi*deltasth)
441     
442      cth(ind1,ind2)=0.5*(1.+1.*erf(xth2))
443      cenv(ind1,ind2)=0.5*(1.+1.*erf(xenv2))
444      ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)   
445
446      IntJ=sigma1s*(exp(-1.*xenv1**2)/sqrt2pi)+0.5*senv*(1+erf(xenv1))
447      IntI1=coeffqlenv*0.5*(0.5*sqrtpi*(erf(xenv2)-erf(xenv1))+xenv1*exp(-1.*xenv1**2)-xenv2*exp(-1.*xenv2**2))
448      IntI2=coeffqlenv*xenv2*(exp(-1.*xenv2**2)-exp(-1.*xenv1**2))
449      IntI3=coeffqlenv*0.5*sqrtpi*xenv2**2*(erf(xenv2)-erf(xenv1))
450
451      qlenv(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
452!      qlenv(ind1,ind2)=IntJ
453!      print*, qlenv(ind1,ind2),'VERIF EAU'
454
455
456      IntJ=sigma2s*(exp(-1.*xth1**2)/sqrt2pi)+0.5*sth*(1+erf(xth1))
457!      IntI1=coeffqlth*((0.5*xth1-xth2)*exp(-1.*xth1**2)+0.5*xth2*exp(-1.*xth2**2))
458!      IntI2=coeffqlth*0.5*sqrtpi*(0.5+xth2**2)*(erf(xth2)-erf(xth1))
459      IntI1=coeffqlth*0.5*(0.5*sqrtpi*(erf(xth2)-erf(xth1))+xth1*exp(-1.*xth1**2)-xth2*exp(-1.*xth2**2))
460      IntI2=coeffqlth*xth2*(exp(-1.*xth2**2)-exp(-1.*xth1**2))
461      IntI3=coeffqlth*0.5*sqrtpi*xth2**2*(erf(xth2)-erf(xth1))
462      qlth(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
463!      qlth(ind1,ind2)=IntJ
464!      print*, IntJ,IntI1,IntI2,IntI3,qlth(ind1,ind2),'VERIF EAU2'
465      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
466
467      ELSE IF (iflag_cloudth_vert == 2) THEN
468
469!-------------------------------------------------------------------------------
470!  Version 3: Modification Jean Jouhaud. On condense a partir de -delta s
471!-------------------------------------------------------------------------------
472!      deltasenv=aenv*ratqs(ind1,ind2)*po(ind1)
473!      deltasth=ath*ratqs(ind1,ind2)*zqta(ind1,ind2)
474!      deltasenv=aenv*ratqs(ind1,ind2)*zqsatenv(ind1,ind2)
475!      deltasth=ath*ratqs(ind1,ind2)*zqsatth(ind1,ind2)
476      deltasenv=aenv*vert_alpha*sigma1s
477      deltasth=ath*vert_alpha*sigma2s
478     
479      xenv1=-(senv+deltasenv)/(sqrt(2.)*sigma1s)
480      xenv2=-(senv-deltasenv)/(sqrt(2.)*sigma1s)
481      xth1=-(sth+deltasth)/(sqrt(2.)*sigma2s)
482      xth2=-(sth-deltasth)/(sqrt(2.)*sigma2s)
483!     coeffqlenv=(sigma1s)**2/(2*sqrtpi*deltasenv)
484!     coeffqlth=(sigma2s)**2/(2*sqrtpi*deltasth)
485     
486      cth(ind1,ind2)=0.5*(1.-1.*erf(xth1))
487      cenv(ind1,ind2)=0.5*(1.-1.*erf(xenv1))
488      ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)
489
490      IntJ=0.5*senv*(1-erf(xenv2))+(sigma1s/sqrt2pi)*exp(-1.*xenv2**2)
491      IntI1=(((senv+deltasenv)**2+(sigma1s)**2)/(8*deltasenv))*(erf(xenv2)-erf(xenv1))
492      IntI2=(sigma1s**2/(4*deltasenv*sqrtpi))*(xenv1*exp(-1.*xenv1**2)-xenv2*exp(-1.*xenv2**2))
493      IntI3=((sqrt2*sigma1s*(senv+deltasenv))/(4*sqrtpi*deltasenv))*(exp(-1.*xenv1**2)-exp(-1.*xenv2**2))
494
495!      IntI1=0.5*(0.5*sqrtpi*(erf(xenv2)-erf(xenv1))+xenv1*exp(-1.*xenv1**2)-xenv2*exp(-1.*xenv2**2))
496!      IntI2=xenv2*(exp(-1.*xenv2**2)-exp(-1.*xenv1**2))
497!      IntI3=0.5*sqrtpi*xenv2**2*(erf(xenv2)-erf(xenv1))
498
499      qlenv(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
500!      qlenv(ind1,ind2)=IntJ
501!      print*, qlenv(ind1,ind2),'VERIF EAU'
502
503      IntJ=0.5*sth*(1-erf(xth2))+(sigma2s/sqrt2pi)*exp(-1.*xth2**2)
504      IntI1=(((sth+deltasth)**2+(sigma2s)**2)/(8*deltasth))*(erf(xth2)-erf(xth1))
505      IntI2=(sigma2s**2/(4*deltasth*sqrtpi))*(xth1*exp(-1.*xth1**2)-xth2*exp(-1.*xth2**2))
506      IntI3=((sqrt2*sigma2s*(sth+deltasth))/(4*sqrtpi*deltasth))*(exp(-1.*xth1**2)-exp(-1.*xth2**2))
507     
508      qlth(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
509!      qlth(ind1,ind2)=IntJ
510!      print*, IntJ,IntI1,IntI2,IntI3,qlth(ind1,ind2),'VERIF EAU2'
511      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
512     
513
514
515
516      ENDIF ! of if (iflag_cloudth_vert==1 or 2)
517
518!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
519
520      if (cenv(ind1,ind2).lt.1.e-10.or.cth(ind1,ind2).lt.1.e-10) then
521      ctot(ind1,ind2)=0.
522      qcloud(ind1)=zqsatenv(ind1,ind2)
523
524      else
525               
526      ctot(ind1,ind2)=ctot(ind1,ind2)
527      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqs(ind1)
528!      qcloud(ind1)=fraca(ind1,ind2)*qlth(ind1,ind2)/cth(ind1,ind2) &
529!    &             +(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)/cenv(ind1,ind2)+zqs(ind1)
530
531      endif 
532                       
533     
534         
535!     print*,sth,sigma2s,qlth(ind1,ind2),ctot(ind1,ind2),qltot(ind1,ind2),'verif'
536
537
538      else  ! gaussienne environnement seule
539     
540      zqenv(ind1)=po(ind1)
541      Tbef=t(ind1,ind2)
542      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
543      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
544      qsatbef=MIN(0.5,qsatbef)
545      zcor=1./(1.-retv*qsatbef)
546      qsatbef=qsatbef*zcor
547      zqsatenv(ind1,ind2)=qsatbef
548     
549
550!      qlbef=Max(po(ind1)-zqsatenv(ind1,ind2),0.)
551      zthl(ind1,ind2)=t(ind1,ind2)*(101325/paprs(ind1,ind2))**(rdd/cppd)
552      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2) 
553      aenv=1./(1.+(alenv*Lv/cppd))
554      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))
555     
556
557      sigma1s=ratqs(ind1,ind2)*zqenv(ind1)
558
559      sqrt2pi=sqrt(2.*pi)
560      xenv=senv/(sqrt(2.)*sigma1s)
561      ctot(ind1,ind2)=0.5*(1.+1.*erf(xenv))
562      qltot(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2))
563     
564      if (ctot(ind1,ind2).lt.1.e-3) then
565      ctot(ind1,ind2)=0.
566      qcloud(ind1)=zqsatenv(ind1,ind2)
567
568      else   
569               
570      ctot(ind1,ind2)=ctot(ind1,ind2)
571      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqsatenv(ind1,ind2)
572
573      endif   
574 
575 
576 
577 
578 
579 
580      endif   
581      enddo
582     
583      return
584!     end
585END SUBROUTINE cloudth_vert
586
587
588
589
590       SUBROUTINE cloudth_v3(ngrid,klev,ind2,  &
591     &           ztv,po,zqta,fraca, &
592     &           qcloud,ctot,ctot_vol,zpspsk,paprs,pplay,ztla,zthl, &
593     &           ratqs,zqs,t)
594
595
596      IMPLICIT NONE
597
598
599!===========================================================================
600! Author : Arnaud Octavio Jam (LMD/CNRS)
601! Date : 25 Mai 2010
602! Objet : calcule les valeurs de qc et rneb dans les thermiques
603!===========================================================================
604
605
606#include "YOMCST.h"
607#include "YOETHF.h"
608#include "FCTTRE.h"
609#include "nuage.h"
610
611      INTEGER itap,ind1,ind2
612      INTEGER ngrid,klev,klon,l,ig
613     
614      REAL ztv(ngrid,klev)
615      REAL po(ngrid)
616      REAL zqenv(ngrid)   
617      REAL zqta(ngrid,klev)
618         
619      REAL fraca(ngrid,klev+1)
620      REAL zpspsk(ngrid,klev)
621      REAL paprs(ngrid,klev+1)
622      REAL pplay(ngrid,klev)
623      REAL ztla(ngrid,klev)
624      REAL zthl(ngrid,klev)
625
626      REAL zqsatth(ngrid,klev)
627      REAL zqsatenv(ngrid,klev)
628     
629      REAL sigma1(ngrid,klev)                                                         
630      REAL sigma2(ngrid,klev)
631      REAL qlth(ngrid,klev)
632      REAL qlenv(ngrid,klev)
633      REAL qltot(ngrid,klev)
634      REAL cth(ngrid,klev)
635      REAL cenv(ngrid,klev)   
636      REAL ctot(ngrid,klev)
637      REAL cth_vol(ngrid,klev)
638      REAL cenv_vol(ngrid,klev)
639      REAL ctot_vol(ngrid,klev)
640      REAL rneb(ngrid,klev)     
641      REAL t(ngrid,klev)
642      REAL qsatmmussig1,qsatmmussig2,sqrt2pi,sqrt2,sqrtpi,pi
643      REAL rdd,cppd,Lv
644      REAL alth,alenv,ath,aenv
645      REAL sth,senv,sigma1s,sigma2s,xth,xenv, exp_xenv1, exp_xenv2,exp_xth1,exp_xth2
646      REAL inverse_rho,beta,a_Brooks,b_Brooks,A_Maj_Brooks,Dx_Brooks,f_Brooks
647      REAL Tbef,zdelta,qsatbef,zcor
648      REAL qlbef 
649      REAL ratqs(ngrid,klev) ! Determine the width of the vapour distribution
650      REAL zpdf_sig(ngrid),zpdf_k(ngrid),zpdf_delta(ngrid)
651      REAL zpdf_a(ngrid),zpdf_b(ngrid),zpdf_e1(ngrid),zpdf_e2(ngrid)
652      REAL zqs(ngrid), qcloud(ngrid)
653      REAL erf
654
655
656      IF (iflag_cloudth_vert.GE.1) THEN
657      CALL cloudth_vert_v3(ngrid,klev,ind2,  &
658     &           ztv,po,zqta,fraca, &
659     &           qcloud,ctot,ctot_vol,zpspsk,paprs,pplay,ztla,zthl, &
660     &           ratqs,zqs,t)
661      RETURN
662      ENDIF
663!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
664
665
666!-------------------------------------------------------------------------------
667! Initialisation des variables r?elles
668!-------------------------------------------------------------------------------
669      sigma1(:,:)=0.
670      sigma2(:,:)=0.
671      qlth(:,:)=0.
672      qlenv(:,:)=0. 
673      qltot(:,:)=0.
674      rneb(:,:)=0.
675      qcloud(:)=0.
676      cth(:,:)=0.
677      cenv(:,:)=0.
678      ctot(:,:)=0.
679      cth_vol(:,:)=0.
680      cenv_vol(:,:)=0.
681      ctot_vol(:,:)=0.
682      qsatmmussig1=0.
683      qsatmmussig2=0.
684      rdd=287.04
685      cppd=1005.7
686      pi=3.14159
687      Lv=2.5e6
688      sqrt2pi=sqrt(2.*pi)
689      sqrt2=sqrt(2.)
690      sqrtpi=sqrt(pi)
691
692
693!-------------------------------------------------------------------------------
694! Cloud fraction in the thermals and standard deviation of the PDFs
695!-------------------------------------------------------------------------------                 
696      do ind1=1,ngrid
697
698      if ((ztv(ind1,1).gt.ztv(ind1,2)).and.(fraca(ind1,ind2).gt.1.e-10)) then
699
700      zqenv(ind1)=(po(ind1)-fraca(ind1,ind2)*zqta(ind1,ind2))/(1.-fraca(ind1,ind2))
701
702      Tbef=zthl(ind1,ind2)*zpspsk(ind1,ind2)
703      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
704      qsatbef= R2ES*FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
705      qsatbef=MIN(0.5,qsatbef)
706      zcor=1./(1.-retv*qsatbef)
707      qsatbef=qsatbef*zcor
708      zqsatenv(ind1,ind2)=qsatbef
709
710
711      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2)     !qsl, p84
712      aenv=1./(1.+(alenv*Lv/cppd))                                      !al, p84
713      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))                          !s, p84
714
715!po = qt de l'environnement ET des thermique
716!zqenv = qt environnement
717!zqsatenv = qsat environnement
718!zthl = Tl environnement
719
720
721      Tbef=ztla(ind1,ind2)*zpspsk(ind1,ind2)
722      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
723      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
724      qsatbef=MIN(0.5,qsatbef)
725      zcor=1./(1.-retv*qsatbef)
726      qsatbef=qsatbef*zcor
727      zqsatth(ind1,ind2)=qsatbef
728           
729      alth=(0.622*Lv*zqsatth(ind1,ind2))/(rdd*ztla(ind1,ind2)**2)       !qsl, p84
730      ath=1./(1.+(alth*Lv/cppd))                                        !al, p84
731      sth=ath*(zqta(ind1,ind2)-zqsatth(ind1,ind2))                      !s, p84
732     
733!zqta = qt thermals
734!zqsatth = qsat thermals
735!ztla = Tl thermals
736
737!------------------------------------------------------------------------------
738! s standard deviations
739!------------------------------------------------------------------------------
740
741!     tests
742!     sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+0.002*po(ind1)
743!     sigma1s=(0.92*(fraca(ind1,ind2)**0.5)/(1-fraca(ind1,ind2))*(((sth-senv)**2)**0.5))+ratqs(ind1,ind2)*po(ind1)
744!     sigma2s=(0.09*(((sth-senv)**2)**0.5)/((fraca(ind1,ind2)+0.02)**0.5))+0.002*zqta(ind1,ind2)
745!     final option
746      sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+ratqs(ind1,ind2)*po(ind1)
747      sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.01)**0.4+0.002*zqta(ind1,ind2)
748 
749!------------------------------------------------------------------------------
750! Condensed water and cloud cover
751!------------------------------------------------------------------------------
752      xth=sth/(sqrt2*sigma2s)
753      xenv=senv/(sqrt2*sigma1s)
754      cth(ind1,ind2)=0.5*(1.+1.*erf(xth))       !4.18 p 111, l.7 p115 & 4.20 p 119 thesis Arnaud Jam
755      cenv(ind1,ind2)=0.5*(1.+1.*erf(xenv))     !4.18 p 111, l.7 p115 & 4.20 p 119 thesis Arnaud Jam
756      ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)
757      ctot_vol(ind1,ind2)=ctot(ind1,ind2)
758
759      qlth(ind1,ind2)=sigma2s*((exp(-1.*xth**2)/sqrt2pi)+xth*sqrt2*cth(ind1,ind2))
760      qlenv(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt2*cenv(ind1,ind2))
761      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
762
763      if (ctot(ind1,ind2).lt.1.e-10) then
764      ctot(ind1,ind2)=0.
765      qcloud(ind1)=zqsatenv(ind1,ind2)
766      else
767      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqs(ind1)
768      endif
769
770      else  ! Environnement only, follow the if l.110
771     
772      zqenv(ind1)=po(ind1)
773      Tbef=t(ind1,ind2)
774      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
775      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
776      qsatbef=MIN(0.5,qsatbef)
777      zcor=1./(1.-retv*qsatbef)
778      qsatbef=qsatbef*zcor
779      zqsatenv(ind1,ind2)=qsatbef
780
781!     qlbef=Max(po(ind1)-zqsatenv(ind1,ind2),0.)
782      zthl(ind1,ind2)=t(ind1,ind2)*(101325/paprs(ind1,ind2))**(rdd/cppd)
783      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2) 
784      aenv=1./(1.+(alenv*Lv/cppd))
785      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))
786     
787      sigma1s=ratqs(ind1,ind2)*zqenv(ind1)
788
789      xenv=senv/(sqrt2*sigma1s)
790      ctot(ind1,ind2)=0.5*(1.+1.*erf(xenv))
791      ctot_vol(ind1,ind2)=ctot(ind1,ind2)
792      qltot(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt2*cenv(ind1,ind2))
793
794      if (ctot(ind1,ind2).lt.1.e-3) then
795      ctot(ind1,ind2)=0.
796      qcloud(ind1)=zqsatenv(ind1,ind2)
797      else   
798      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqsatenv(ind1,ind2)
799      endif
800
801
802      endif       ! From the separation (thermal/envrionnement) et (environnement) only, l.110 et l.183
803      enddo       ! from the loop on ngrid l.108
804      return
805!     end
806END SUBROUTINE cloudth_v3
807
808
809
810!===========================================================================
811     SUBROUTINE cloudth_vert_v3(ngrid,klev,ind2,  &
812     &           ztv,po,zqta,fraca, &
813     &           qcloud,ctot,ctot_vol,zpspsk,paprs,pplay,ztla,zthl, &
814     &           ratqs,zqs,t)
815
816!===========================================================================
817! Auteur : Arnaud Octavio Jam (LMD/CNRS)
818! Date : 25 Mai 2010
819! Objet : calcule les valeurs de qc et rneb dans les thermiques
820!===========================================================================
821
822
823      USE ioipsl_getin_p_mod, ONLY : getin_p
824      USE phys_output_var_mod, ONLY : cloudth_sth,cloudth_senv, &
825     &                                cloudth_sigmath,cloudth_sigmaenv
826
827      IMPLICIT NONE
828
829#include "YOMCST.h"
830#include "YOETHF.h"
831#include "FCTTRE.h"
832#include "nuage.h"
833     
834      INTEGER itap,ind1,ind2
835      INTEGER ngrid,klev,klon,l,ig
836     
837      REAL ztv(ngrid,klev)
838      REAL po(ngrid)
839      REAL zqenv(ngrid)   
840      REAL zqta(ngrid,klev)
841         
842      REAL fraca(ngrid,klev+1)
843      REAL zpspsk(ngrid,klev)
844      REAL paprs(ngrid,klev+1)
845      REAL pplay(ngrid,klev)
846      REAL ztla(ngrid,klev)
847      REAL zthl(ngrid,klev)
848
849      REAL zqsatth(ngrid,klev)
850      REAL zqsatenv(ngrid,klev)
851     
852      REAL sigma1(ngrid,klev)                                                         
853      REAL sigma2(ngrid,klev)
854      REAL qlth(ngrid,klev)
855      REAL qlenv(ngrid,klev)
856      REAL qltot(ngrid,klev)
857      REAL cth(ngrid,klev)
858      REAL cenv(ngrid,klev)   
859      REAL ctot(ngrid,klev)
860      REAL cth_vol(ngrid,klev)
861      REAL cenv_vol(ngrid,klev)
862      REAL ctot_vol(ngrid,klev)
863      REAL rneb(ngrid,klev)
864      REAL t(ngrid,klev)                                                                 
865      REAL qsatmmussig1,qsatmmussig2,sqrtpi,sqrt2,sqrt2pi,pi
866      REAL rdd,cppd,Lv
867      REAL alth,alenv,ath,aenv
868      REAL sth,senv,sigma1s,sigma2s,sigma1s_fraca,sigma1s_ratqs
869      REAL inverse_rho,beta,a_Brooks,b_Brooks,A_Maj_Brooks,Dx_Brooks,f_Brooks
870      REAL xth,xenv,exp_xenv1,exp_xenv2,exp_xth1,exp_xth2
871      REAL xth1,xth2,xenv1,xenv2,deltasth, deltasenv
872      REAL IntJ,IntI1,IntI2,IntI3,IntJ_CF,IntI1_CF,IntI3_CF,coeffqlenv,coeffqlth
873      REAL Tbef,zdelta,qsatbef,zcor
874      REAL qlbef 
875      REAL ratqs(ngrid,klev) ! determine la largeur de distribution de vapeur
876      ! Change the width of the PDF used for vertical subgrid scale heterogeneity
877      ! (J Jouhaud, JL Dufresne, JB Madeleine)
878      REAL,SAVE :: vert_alpha, vert_alpha_th
879      !$OMP THREADPRIVATE(vert_alpha, vert_alpha_th)
880      REAL,SAVE :: sigma1s_factor=1.1
881      REAL,SAVE :: sigma1s_power=0.6
882      REAL,SAVE :: sigma2s_factor=0.09
883      REAL,SAVE :: sigma2s_power=0.5
884      REAL,SAVE :: cloudth_ratqsmin=-1.
885      !$OMP THREADPRIVATE(sigma1s_factor,sigma1s_power,sigma2s_factor,sigma2s_power,cloudth_ratqsmin)
886      INTEGER, SAVE :: iflag_cloudth_vert_noratqs=0
887      !$OMP THREADPRIVATE(iflag_cloudth_vert_noratqs)
888
889      LOGICAL, SAVE :: firstcall = .TRUE.
890      !$OMP THREADPRIVATE(firstcall)
891
892      REAL zpdf_sig(ngrid),zpdf_k(ngrid),zpdf_delta(ngrid)
893      REAL zpdf_a(ngrid),zpdf_b(ngrid),zpdf_e1(ngrid),zpdf_e2(ngrid)
894      REAL zqs(ngrid), qcloud(ngrid)
895      REAL erf
896
897      REAL rhodz(ngrid,klev)
898      REAL zrho(ngrid,klev)
899      REAL dz(ngrid,klev)
900
901      DO ind1 = 1, ngrid
902        !Layer calculation
903        rhodz(ind1,ind2) = (paprs(ind1,ind2)-paprs(ind1,ind2+1))/rg !kg/m2
904        zrho(ind1,ind2) = pplay(ind1,ind2)/t(ind1,ind2)/rd !kg/m3
905        dz(ind1,ind2) = rhodz(ind1,ind2)/zrho(ind1,ind2) !m : epaisseur de la couche en metre
906      END DO
907
908!------------------------------------------------------------------------------
909! Initialize
910!------------------------------------------------------------------------------
911
912      sigma1(:,:)=0.
913      sigma2(:,:)=0.
914      qlth(:,:)=0.
915      qlenv(:,:)=0. 
916      qltot(:,:)=0.
917      rneb(:,:)=0.
918      qcloud(:)=0.
919      cth(:,:)=0.
920      cenv(:,:)=0.
921      ctot(:,:)=0.
922      cth_vol(:,:)=0.
923      cenv_vol(:,:)=0.
924      ctot_vol(:,:)=0.
925      qsatmmussig1=0.
926      qsatmmussig2=0.
927      rdd=287.04
928      cppd=1005.7
929      pi=3.14159
930      Lv=2.5e6
931      sqrt2pi=sqrt(2.*pi)
932      sqrt2=sqrt(2.)
933      sqrtpi=sqrt(pi)
934
935      IF (firstcall) THEN
936        vert_alpha=0.5
937        CALL getin_p('cloudth_vert_alpha',vert_alpha)
938        WRITE(*,*) 'cloudth_vert_alpha = ', vert_alpha
939        ! The factor used for the thermal is equal to that of the environment
940        !   if nothing is explicitly specified in the def file
941        vert_alpha_th=vert_alpha
942        CALL getin_p('cloudth_vert_alpha_th',vert_alpha_th)
943        WRITE(*,*) 'cloudth_vert_alpha_th = ', vert_alpha_th
944        ! Factor used in the calculation of sigma1s
945        CALL getin_p('cloudth_sigma1s_factor',sigma1s_factor)
946        WRITE(*,*) 'cloudth_sigma1s_factor = ', sigma1s_factor
947        ! Power used in the calculation of sigma1s
948        CALL getin_p('cloudth_sigma1s_power',sigma1s_power)
949        WRITE(*,*) 'cloudth_sigma1s_power = ', sigma1s_power
950        ! Factor used in the calculation of sigma2s
951        CALL getin_p('cloudth_sigma2s_factor',sigma2s_factor)
952        WRITE(*,*) 'cloudth_sigma2s_factor = ', sigma2s_factor
953        ! Power used in the calculation of sigma2s
954        CALL getin_p('cloudth_sigma2s_power',sigma2s_power)
955        WRITE(*,*) 'cloudth_sigma2s_power = ', sigma2s_power
956        ! Minimum value for the environmental air subgrid water distrib
957        CALL getin_p('cloudth_ratqsmin',cloudth_ratqsmin)
958        WRITE(*,*) 'cloudth_ratqsmin = ', cloudth_ratqsmin
959        ! Remove the dependency to ratqs from the variance of the vertical PDF
960        CALL getin_p('iflag_cloudth_vert_noratqs',iflag_cloudth_vert_noratqs)
961        WRITE(*,*) 'iflag_cloudth_vert_noratqs = ', iflag_cloudth_vert_noratqs
962
963        firstcall=.FALSE.
964      ENDIF
965
966!-------------------------------------------------------------------------------
967! Calcul de la fraction du thermique et des ecart-types des distributions
968!-------------------------------------------------------------------------------                 
969      do ind1=1,ngrid
970
971      if ((ztv(ind1,1).gt.ztv(ind1,2)).and.(fraca(ind1,ind2).gt.1.e-10)) then !Thermal and environnement
972
973      zqenv(ind1)=(po(ind1)-fraca(ind1,ind2)*zqta(ind1,ind2))/(1.-fraca(ind1,ind2)) !qt = a*qtth + (1-a)*qtenv
974
975
976      Tbef=zthl(ind1,ind2)*zpspsk(ind1,ind2)
977      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
978      qsatbef= R2ES*FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
979      qsatbef=MIN(0.5,qsatbef)
980      zcor=1./(1.-retv*qsatbef)
981      qsatbef=qsatbef*zcor
982      zqsatenv(ind1,ind2)=qsatbef
983
984
985      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2)     !qsl, p84
986      aenv=1./(1.+(alenv*Lv/cppd))                                      !al, p84
987      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))                          !s, p84
988
989!zqenv = qt environnement
990!zqsatenv = qsat environnement
991!zthl = Tl environnement
992
993
994      Tbef=ztla(ind1,ind2)*zpspsk(ind1,ind2)
995      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
996      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
997      qsatbef=MIN(0.5,qsatbef)
998      zcor=1./(1.-retv*qsatbef)
999      qsatbef=qsatbef*zcor
1000      zqsatth(ind1,ind2)=qsatbef
1001           
1002      alth=(0.622*Lv*zqsatth(ind1,ind2))/(rdd*ztla(ind1,ind2)**2)       !qsl, p84
1003      ath=1./(1.+(alth*Lv/cppd))                                        !al, p84
1004      sth=ath*(zqta(ind1,ind2)-zqsatth(ind1,ind2))                      !s, p84
1005     
1006     
1007!zqta = qt thermals
1008!zqsatth = qsat thermals
1009!ztla = Tl thermals
1010!------------------------------------------------------------------------------
1011! s standard deviation
1012!------------------------------------------------------------------------------
1013
1014      sigma1s_fraca = (sigma1s_factor**0.5)*(fraca(ind1,ind2)**sigma1s_power) / &
1015     &                (1-fraca(ind1,ind2))*((sth-senv)**2)**0.5
1016!     sigma1s_fraca = (1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5
1017      IF (cloudth_ratqsmin>0.) THEN
1018         sigma1s_ratqs = cloudth_ratqsmin*po(ind1)
1019      ELSE
1020         sigma1s_ratqs = ratqs(ind1,ind2)*po(ind1)
1021      ENDIF
1022      sigma1s = sigma1s_fraca + sigma1s_ratqs
1023      sigma2s=(sigma2s_factor*(((sth-senv)**2)**0.5)/((fraca(ind1,ind2)+0.02)**sigma2s_power))+0.002*zqta(ind1,ind2)
1024!      tests
1025!      sigma1s=(0.92**0.5)*(fraca(ind1,ind2)**0.5)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+ratqs(ind1,ind2)*po(ind1)
1026!      sigma1s=(0.92*(fraca(ind1,ind2)**0.5)/(1-fraca(ind1,ind2))*(((sth-senv)**2)**0.5))+0.002*zqenv(ind1)
1027!      sigma2s=0.09*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.5+0.002*zqta(ind1,ind2)
1028!      sigma2s=(0.09*(((sth-senv)**2)**0.5)/((fraca(ind1,ind2)+0.02)**0.5))+ratqs(ind1,ind2)*zqta(ind1,ind2)
1029!       if (paprs(ind1,ind2).gt.90000) then
1030!       ratqs(ind1,ind2)=0.002
1031!       else
1032!       ratqs(ind1,ind2)=0.002+0.0*(90000-paprs(ind1,ind2))/20000
1033!       endif
1034!       sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+0.002*po(ind1)
1035!       sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.01)**0.4+0.002*zqta(ind1,ind2)
1036!       sigma1s=ratqs(ind1,ind2)*po(ind1)
1037!      sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.02)**0.4+0.00003 
1038 
1039       IF (iflag_cloudth_vert == 1) THEN
1040!-------------------------------------------------------------------------------
1041!  Version 2: Modification from Arnaud Jam according to JL Dufrense. Condensate from qsat-ratqs
1042!-------------------------------------------------------------------------------
1043
1044      deltasenv=aenv*ratqs(ind1,ind2)*zqsatenv(ind1,ind2)
1045      deltasth=ath*ratqs(ind1,ind2)*zqsatth(ind1,ind2)
1046
1047      xenv1=(senv-deltasenv)/(sqrt(2.)*sigma1s)
1048      xenv2=(senv+deltasenv)/(sqrt(2.)*sigma1s)
1049      xth1=(sth-deltasth)/(sqrt(2.)*sigma2s)
1050      xth2=(sth+deltasth)/(sqrt(2.)*sigma2s)
1051      coeffqlenv=(sigma1s)**2/(2*sqrtpi*deltasenv)
1052      coeffqlth=(sigma2s)**2/(2*sqrtpi*deltasth)
1053     
1054      cth(ind1,ind2)=0.5*(1.+1.*erf(xth2))
1055      cenv(ind1,ind2)=0.5*(1.+1.*erf(xenv2))
1056      ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)   
1057
1058      ! Environment
1059      IntJ=sigma1s*(exp(-1.*xenv1**2)/sqrt2pi)+0.5*senv*(1+erf(xenv1))
1060      IntI1=coeffqlenv*0.5*(0.5*sqrtpi*(erf(xenv2)-erf(xenv1))+xenv1*exp(-1.*xenv1**2)-xenv2*exp(-1.*xenv2**2))
1061      IntI2=coeffqlenv*xenv2*(exp(-1.*xenv2**2)-exp(-1.*xenv1**2))
1062      IntI3=coeffqlenv*0.5*sqrtpi*xenv2**2*(erf(xenv2)-erf(xenv1))
1063
1064      qlenv(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
1065
1066      ! Thermal
1067      IntJ=sigma2s*(exp(-1.*xth1**2)/sqrt2pi)+0.5*sth*(1+erf(xth1))
1068      IntI1=coeffqlth*0.5*(0.5*sqrtpi*(erf(xth2)-erf(xth1))+xth1*exp(-1.*xth1**2)-xth2*exp(-1.*xth2**2))
1069      IntI2=coeffqlth*xth2*(exp(-1.*xth2**2)-exp(-1.*xth1**2))
1070      IntI3=coeffqlth*0.5*sqrtpi*xth2**2*(erf(xth2)-erf(xth1))
1071      qlth(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
1072      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
1073
1074      ELSE IF (iflag_cloudth_vert >= 3) THEN
1075      IF (iflag_cloudth_vert < 5) THEN
1076!-------------------------------------------------------------------------------
1077!  Version 3: Changes by J. Jouhaud; condensation for q > -delta s
1078!-------------------------------------------------------------------------------
1079!      deltasenv=aenv*ratqs(ind1,ind2)*po(ind1)
1080!      deltasth=ath*ratqs(ind1,ind2)*zqta(ind1,ind2)
1081!      deltasenv=aenv*ratqs(ind1,ind2)*zqsatenv(ind1,ind2)
1082!      deltasth=ath*ratqs(ind1,ind2)*zqsatth(ind1,ind2)
1083      IF (iflag_cloudth_vert == 3) THEN
1084        deltasenv=aenv*vert_alpha*sigma1s
1085        deltasth=ath*vert_alpha_th*sigma2s
1086      ELSE IF (iflag_cloudth_vert == 4) THEN
1087        IF (iflag_cloudth_vert_noratqs == 1) THEN
1088          deltasenv=vert_alpha*max(sigma1s_fraca,1e-10)
1089          deltasth=vert_alpha_th*sigma2s
1090        ELSE
1091          deltasenv=vert_alpha*sigma1s
1092          deltasth=vert_alpha_th*sigma2s
1093        ENDIF
1094      ENDIF
1095     
1096      xenv1=-(senv+deltasenv)/(sqrt(2.)*sigma1s)
1097      xenv2=-(senv-deltasenv)/(sqrt(2.)*sigma1s)
1098      exp_xenv1 = exp(-1.*xenv1**2)
1099      exp_xenv2 = exp(-1.*xenv2**2)
1100      xth1=-(sth+deltasth)/(sqrt(2.)*sigma2s)
1101      xth2=-(sth-deltasth)/(sqrt(2.)*sigma2s)
1102      exp_xth1 = exp(-1.*xth1**2)
1103      exp_xth2 = exp(-1.*xth2**2)
1104     
1105      !CF_surfacique
1106      cth(ind1,ind2)=0.5*(1.-1.*erf(xth1))
1107      cenv(ind1,ind2)=0.5*(1.-1.*erf(xenv1))
1108      ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)
1109
1110
1111      !CF_volumique & eau condense
1112      !environnement
1113      IntJ=0.5*senv*(1-erf(xenv2))+(sigma1s/sqrt2pi)*exp_xenv2
1114      IntJ_CF=0.5*(1.-1.*erf(xenv2))
1115      if (deltasenv .lt. 1.e-10) then
1116      qlenv(ind1,ind2)=IntJ
1117      cenv_vol(ind1,ind2)=IntJ_CF
1118      else
1119      IntI1=(((senv+deltasenv)**2+(sigma1s)**2)/(8*deltasenv))*(erf(xenv2)-erf(xenv1))
1120      IntI2=(sigma1s**2/(4*deltasenv*sqrtpi))*(xenv1*exp_xenv1-xenv2*exp_xenv2)
1121      IntI3=((sqrt2*sigma1s*(senv+deltasenv))/(4*sqrtpi*deltasenv))*(exp_xenv1-exp_xenv2)
1122      IntI1_CF=((senv+deltasenv)*(erf(xenv2)-erf(xenv1)))/(4*deltasenv)
1123      IntI3_CF=(sqrt2*sigma1s*(exp_xenv1-exp_xenv2))/(4*sqrtpi*deltasenv)
1124      qlenv(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
1125      cenv_vol(ind1,ind2)=IntJ_CF+IntI1_CF+IntI3_CF
1126      endif
1127
1128      !thermique
1129      IntJ=0.5*sth*(1-erf(xth2))+(sigma2s/sqrt2pi)*exp_xth2
1130      IntJ_CF=0.5*(1.-1.*erf(xth2))
1131      if (deltasth .lt. 1.e-10) then
1132      qlth(ind1,ind2)=IntJ
1133      cth_vol(ind1,ind2)=IntJ_CF
1134      else
1135      IntI1=(((sth+deltasth)**2+(sigma2s)**2)/(8*deltasth))*(erf(xth2)-erf(xth1))
1136      IntI2=(sigma2s**2/(4*deltasth*sqrtpi))*(xth1*exp_xth1-xth2*exp_xth2)
1137      IntI3=((sqrt2*sigma2s*(sth+deltasth))/(4*sqrtpi*deltasth))*(exp_xth1-exp_xth2)
1138      IntI1_CF=((sth+deltasth)*(erf(xth2)-erf(xth1)))/(4*deltasth)
1139      IntI3_CF=(sqrt2*sigma2s*(exp_xth1-exp_xth2))/(4*sqrtpi*deltasth)
1140      qlth(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
1141      cth_vol(ind1,ind2)=IntJ_CF+IntI1_CF+IntI3_CF
1142      endif
1143
1144      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
1145      ctot_vol(ind1,ind2)=fraca(ind1,ind2)*cth_vol(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv_vol(ind1,ind2)
1146
1147      ELSE IF (iflag_cloudth_vert == 5) THEN
1148         sigma1s=(0.71794+0.000498239*dz(ind1,ind2))*(fraca(ind1,ind2)**0.5) &
1149              /(1-fraca(ind1,ind2))*(((sth-senv)**2)**0.5) &
1150              +ratqs(ind1,ind2)*po(ind1) !Environment
1151      sigma2s=(0.03218+0.000092655*dz(ind1,ind2))/((fraca(ind1,ind2)+0.02)**0.5)*(((sth-senv)**2)**0.5)+0.002*zqta(ind1,ind2)                   !Thermals
1152      !sigma1s=(1.1**0.5)*(fraca(ind1,ind2)**0.6)/(1-fraca(ind1,ind2))*((sth-senv)**2)**0.5+0.002*po(ind1)
1153      !sigma2s=0.11*((sth-senv)**2)**0.5/(fraca(ind1,ind2)+0.01)**0.4+0.002*zqta(ind1,ind2)
1154      xth=sth/(sqrt(2.)*sigma2s)
1155      xenv=senv/(sqrt(2.)*sigma1s)
1156
1157      !Volumique
1158      cth_vol(ind1,ind2)=0.5*(1.+1.*erf(xth))
1159      cenv_vol(ind1,ind2)=0.5*(1.+1.*erf(xenv))
1160      ctot_vol(ind1,ind2)=fraca(ind1,ind2)*cth_vol(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv_vol(ind1,ind2)
1161      !print *,'jeanjean_CV=',ctot_vol(ind1,ind2)
1162
1163      qlth(ind1,ind2)=sigma2s*((exp(-1.*xth**2)/sqrt2pi)+xth*sqrt(2.)*cth_vol(ind1,ind2))
1164      qlenv(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv_vol(ind1,ind2)) 
1165      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
1166
1167      !Surfacique
1168      !Neggers
1169      !beta=0.0044
1170      !inverse_rho=1.+beta*dz(ind1,ind2)
1171      !print *,'jeanjean : beta=',beta
1172      !cth(ind1,ind2)=cth_vol(ind1,ind2)*inverse_rho
1173      !cenv(ind1,ind2)=cenv_vol(ind1,ind2)*inverse_rho
1174      !ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)
1175
1176      !Brooks
1177      a_Brooks=0.6694
1178      b_Brooks=0.1882
1179      A_Maj_Brooks=0.1635 !-- sans shear
1180      !A_Maj_Brooks=0.17   !-- ARM LES
1181      !A_Maj_Brooks=0.18   !-- RICO LES
1182      !A_Maj_Brooks=0.19   !-- BOMEX LES
1183      Dx_Brooks=200000.
1184      f_Brooks=A_Maj_Brooks*(dz(ind1,ind2)**(a_Brooks))*(Dx_Brooks**(-b_Brooks))
1185      !print *,'jeanjean_f=',f_Brooks
1186
1187      cth(ind1,ind2)=1./(1.+exp(-1.*f_Brooks)*((1./max(1.e-15,min(cth_vol(ind1,ind2),1.)))- 1.))
1188      cenv(ind1,ind2)=1./(1.+exp(-1.*f_Brooks)*((1./max(1.e-15,min(cenv_vol(ind1,ind2),1.)))- 1.))
1189      ctot(ind1,ind2)=1./(1.+exp(-1.*f_Brooks)*((1./max(1.e-15,min(ctot_vol(ind1,ind2),1.)))- 1.))
1190      !print *,'JJ_ctot_1',ctot(ind1,ind2)
1191
1192
1193
1194
1195
1196      ENDIF ! of if (iflag_cloudth_vert<5)
1197      ENDIF ! of if (iflag_cloudth_vert==1 or 3 or 4)
1198
1199!      if (ctot(ind1,ind2).lt.1.e-10) then
1200      if (cenv(ind1,ind2).lt.1.e-10.or.cth(ind1,ind2).lt.1.e-10) then
1201      ctot(ind1,ind2)=0.
1202      ctot_vol(ind1,ind2)=0.
1203      qcloud(ind1)=zqsatenv(ind1,ind2)
1204
1205      else
1206               
1207      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqs(ind1)
1208!      qcloud(ind1)=fraca(ind1,ind2)*qlth(ind1,ind2)/cth(ind1,ind2) &
1209!    &             +(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)/cenv(ind1,ind2)+zqs(ind1)
1210
1211      endif 
1212
1213      else  ! gaussienne environnement seule
1214     
1215
1216      zqenv(ind1)=po(ind1)
1217      Tbef=t(ind1,ind2)
1218      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
1219      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
1220      qsatbef=MIN(0.5,qsatbef)
1221      zcor=1./(1.-retv*qsatbef)
1222      qsatbef=qsatbef*zcor
1223      zqsatenv(ind1,ind2)=qsatbef
1224     
1225
1226!      qlbef=Max(po(ind1)-zqsatenv(ind1,ind2),0.)
1227      zthl(ind1,ind2)=t(ind1,ind2)*(101325/paprs(ind1,ind2))**(rdd/cppd)
1228      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2)
1229      aenv=1./(1.+(alenv*Lv/cppd))
1230      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))
1231      sth=0.
1232     
1233
1234      sigma1s=ratqs(ind1,ind2)*zqenv(ind1)
1235      sigma2s=0.
1236
1237      sqrt2pi=sqrt(2.*pi)
1238      xenv=senv/(sqrt(2.)*sigma1s)
1239      ctot(ind1,ind2)=0.5*(1.+1.*erf(xenv))
1240      ctot_vol(ind1,ind2)=ctot(ind1,ind2)
1241      qltot(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2))
1242     
1243      if (ctot(ind1,ind2).lt.1.e-3) then
1244      ctot(ind1,ind2)=0.
1245      qcloud(ind1)=zqsatenv(ind1,ind2)
1246
1247      else   
1248               
1249!      ctot(ind1,ind2)=ctot(ind1,ind2)
1250      qcloud(ind1)=qltot(ind1,ind2)/ctot(ind1,ind2)+zqsatenv(ind1,ind2)
1251
1252      endif 
1253 
1254
1255
1256
1257      endif       ! From the separation (thermal/envrionnement) et (environnement) only, l.335 et l.492
1258      ! Outputs used to check the PDFs
1259      cloudth_senv(ind1,ind2) = senv
1260      cloudth_sth(ind1,ind2) = sth
1261      cloudth_sigmaenv(ind1,ind2) = sigma1s
1262      cloudth_sigmath(ind1,ind2) = sigma2s
1263
1264      enddo       ! from the loop on ngrid l.333
1265      return
1266!     end
1267END SUBROUTINE cloudth_vert_v3
1268!
1269
1270
1271
1272
1273
1274
1275
1276
1277
1278
1279
1280       SUBROUTINE cloudth_v6(ngrid,klev,ind2,  &
1281     &           ztv,po,zqta,fraca, &
1282     &           qcloud,ctot_surf,ctot_vol,zpspsk,paprs,pplay,ztla,zthl, &
1283     &           ratqs,zqs,T)
1284
1285
1286      USE ioipsl_getin_p_mod, ONLY : getin_p
1287      USE phys_output_var_mod, ONLY : cloudth_sth,cloudth_senv, &
1288     &                                cloudth_sigmath,cloudth_sigmaenv
1289
1290      IMPLICIT NONE
1291
1292#include "YOMCST.h"
1293#include "YOETHF.h"
1294#include "FCTTRE.h"
1295#include "nuage.h"
1296
1297
1298        !Domain variables
1299      INTEGER ngrid !indice Max lat-lon
1300      INTEGER klev  !indice Max alt
1301      INTEGER ind1  !indice in [1:ngrid]
1302      INTEGER ind2  !indice in [1:klev]
1303        !thermal plume fraction
1304      REAL fraca(ngrid,klev+1)   !thermal plumes fraction in the gridbox
1305        !temperatures
1306      REAL T(ngrid,klev)       !temperature
1307      REAL zpspsk(ngrid,klev)  !factor (p/p0)**kappa (used for potential variables)
1308      REAL ztv(ngrid,klev)     !potential temperature (voir thermcell_env.F90)
1309      REAL ztla(ngrid,klev)    !liquid temperature in the thermals (Tl_th)
1310      REAL zthl(ngrid,klev)    !liquid temperature in the environment (Tl_env)
1311        !pressure
1312      REAL paprs(ngrid,klev+1)   !pressure at the interface of levels
1313      REAL pplay(ngrid,klev)     !pressure at the middle of the level
1314        !humidity
1315      REAL ratqs(ngrid,klev)   !width of the total water subgrid-scale distribution
1316      REAL po(ngrid)           !total water (qt)
1317      REAL zqenv(ngrid)        !total water in the environment (qt_env)
1318      REAL zqta(ngrid,klev)    !total water in the thermals (qt_th)
1319      REAL zqsatth(ngrid,klev)   !water saturation level in the thermals (q_sat_th)
1320      REAL zqsatenv(ngrid,klev)  !water saturation level in the environment (q_sat_env)
1321      REAL qlth(ngrid,klev)    !condensed water in the thermals
1322      REAL qlenv(ngrid,klev)   !condensed water in the environment
1323      REAL qltot(ngrid,klev)   !condensed water in the gridbox
1324        !cloud fractions
1325      REAL cth_vol(ngrid,klev)   !cloud fraction by volume in the thermals
1326      REAL cenv_vol(ngrid,klev)  !cloud fraction by volume in the environment
1327      REAL ctot_vol(ngrid,klev)  !cloud fraction by volume in the gridbox
1328      REAL cth_surf(ngrid,klev)  !cloud fraction by surface in the thermals
1329      REAL cenv_surf(ngrid,klev) !cloud fraction by surface in the environment 
1330      REAL ctot_surf(ngrid,klev) !cloud fraction by surface in the gridbox
1331        !PDF of saturation deficit variables
1332      REAL rdd,cppd,Lv
1333      REAL Tbef,zdelta,qsatbef,zcor
1334      REAL alth,alenv,ath,aenv
1335      REAL sth,senv              !saturation deficits in the thermals and environment
1336      REAL sigma_env,sigma_th    !standard deviations of the biGaussian PDF
1337        !cloud fraction variables
1338      REAL xth,xenv
1339      REAL inverse_rho,beta                                  !Neggers et al. (2011) method
1340      REAL a_Brooks,b_Brooks,A_Maj_Brooks,Dx_Brooks,f_Brooks !Brooks et al. (2005) method
1341        !Incloud total water variables
1342      REAL zqs(ngrid)    !q_sat
1343      REAL qcloud(ngrid) !eau totale dans le nuage
1344        !Some arithmetic variables
1345      REAL erf,pi,sqrt2,sqrt2pi
1346        !Depth of the layer
1347      REAL dz(ngrid,klev)    !epaisseur de la couche en metre
1348      REAL rhodz(ngrid,klev)
1349      REAL zrho(ngrid,klev)
1350      DO ind1 = 1, ngrid
1351        rhodz(ind1,ind2) = (paprs(ind1,ind2)-paprs(ind1,ind2+1))/rg ![kg/m2]
1352        zrho(ind1,ind2) = pplay(ind1,ind2)/T(ind1,ind2)/rd          ![kg/m3]
1353        dz(ind1,ind2) = rhodz(ind1,ind2)/zrho(ind1,ind2)            ![m]
1354      END DO
1355
1356!------------------------------------------------------------------------------
1357! Initialization
1358!------------------------------------------------------------------------------
1359      qlth(:,:)=0.
1360      qlenv(:,:)=0. 
1361      qltot(:,:)=0.
1362      cth_vol(:,:)=0.
1363      cenv_vol(:,:)=0.
1364      ctot_vol(:,:)=0.
1365      cth_surf(:,:)=0.
1366      cenv_surf(:,:)=0.
1367      ctot_surf(:,:)=0.
1368      qcloud(:)=0.
1369      rdd=287.04
1370      cppd=1005.7
1371      pi=3.14159
1372      Lv=2.5e6
1373      sqrt2=sqrt(2.)
1374      sqrt2pi=sqrt(2.*pi)
1375
1376
1377      DO ind1=1,ngrid
1378!-------------------------------------------------------------------------------
1379!Both thermal and environment in the gridbox
1380!-------------------------------------------------------------------------------
1381      IF ((ztv(ind1,1).gt.ztv(ind1,2)).and.(fraca(ind1,ind2).gt.1.e-10)) THEN
1382        !--------------------------------------------
1383        !calcul de qsat_env
1384        !--------------------------------------------
1385      Tbef=zthl(ind1,ind2)*zpspsk(ind1,ind2)
1386      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
1387      qsatbef= R2ES*FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
1388      qsatbef=MIN(0.5,qsatbef)
1389      zcor=1./(1.-retv*qsatbef)
1390      qsatbef=qsatbef*zcor
1391      zqsatenv(ind1,ind2)=qsatbef
1392        !--------------------------------------------
1393        !calcul de s_env
1394        !--------------------------------------------
1395      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2)     !qsl, p84 these Arnaud Jam
1396      aenv=1./(1.+(alenv*Lv/cppd))                                      !al, p84 these Arnaud Jam
1397      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))                          !s, p84 these Arnaud Jam
1398        !--------------------------------------------
1399        !calcul de qsat_th
1400        !--------------------------------------------
1401      Tbef=ztla(ind1,ind2)*zpspsk(ind1,ind2)
1402      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
1403      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
1404      qsatbef=MIN(0.5,qsatbef)
1405      zcor=1./(1.-retv*qsatbef)
1406      qsatbef=qsatbef*zcor
1407      zqsatth(ind1,ind2)=qsatbef
1408        !--------------------------------------------
1409        !calcul de s_th 
1410        !--------------------------------------------
1411      alth=(0.622*Lv*zqsatth(ind1,ind2))/(rdd*ztla(ind1,ind2)**2)       !qsl, p84 these Arnaud Jam
1412      ath=1./(1.+(alth*Lv/cppd))                                        !al, p84 these Arnaud Jam
1413      sth=ath*(zqta(ind1,ind2)-zqsatth(ind1,ind2))                      !s, p84 these Arnaud Jam
1414        !--------------------------------------------
1415        !calcul standard deviations bi-Gaussian PDF
1416        !--------------------------------------------
1417      sigma_th=(0.03218+0.000092655*dz(ind1,ind2))/((fraca(ind1,ind2)+0.01)**0.5)*(((sth-senv)**2)**0.5)+0.002*zqta(ind1,ind2)
1418      sigma_env=(0.71794+0.000498239*dz(ind1,ind2))*(fraca(ind1,ind2)**0.5) &
1419           /(1-fraca(ind1,ind2))*(((sth-senv)**2)**0.5) &
1420           +ratqs(ind1,ind2)*po(ind1)
1421      xth=sth/(sqrt2*sigma_th)
1422      xenv=senv/(sqrt2*sigma_env)
1423        !--------------------------------------------
1424        !Cloud fraction by volume CF_vol
1425        !--------------------------------------------
1426      cth_vol(ind1,ind2)=0.5*(1.+1.*erf(xth))
1427      cenv_vol(ind1,ind2)=0.5*(1.+1.*erf(xenv))
1428      ctot_vol(ind1,ind2)=fraca(ind1,ind2)*cth_vol(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv_vol(ind1,ind2)
1429        !--------------------------------------------
1430        !Condensed water qc
1431        !--------------------------------------------
1432      qlth(ind1,ind2)=sigma_th*((exp(-1.*xth**2)/sqrt2pi)+xth*sqrt2*cth_vol(ind1,ind2))
1433      qlenv(ind1,ind2)=sigma_env*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt2*cenv_vol(ind1,ind2)) 
1434      qltot(ind1,ind2)=fraca(ind1,ind2)*qlth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qlenv(ind1,ind2)
1435        !--------------------------------------------
1436        !Cloud fraction by surface CF_surf
1437        !--------------------------------------------
1438        !Method Neggers et al. (2011) : ok for cumulus clouds only
1439      !beta=0.0044 (Jouhaud et al.2018)
1440      !inverse_rho=1.+beta*dz(ind1,ind2)
1441      !ctot_surf(ind1,ind2)=ctot_vol(ind1,ind2)*inverse_rho
1442        !Method Brooks et al. (2005) : ok for all types of clouds
1443      a_Brooks=0.6694
1444      b_Brooks=0.1882
1445      A_Maj_Brooks=0.1635 !-- sans dependence au cisaillement de vent
1446      Dx_Brooks=200000.   !-- si l'on considere des mailles de 200km de cote
1447      f_Brooks=A_Maj_Brooks*(dz(ind1,ind2)**(a_Brooks))*(Dx_Brooks**(-b_Brooks))
1448      ctot_surf(ind1,ind2)=1./(1.+exp(-1.*f_Brooks)*((1./max(1.e-15,min(ctot_vol(ind1,ind2),1.)))- 1.))
1449        !--------------------------------------------
1450        !Incloud Condensed water qcloud
1451        !--------------------------------------------
1452      if (ctot_surf(ind1,ind2) .lt. 1.e-10) then
1453      ctot_vol(ind1,ind2)=0.
1454      ctot_surf(ind1,ind2)=0.
1455      qcloud(ind1)=zqsatenv(ind1,ind2)
1456      else
1457      qcloud(ind1)=qltot(ind1,ind2)/ctot_vol(ind1,ind2)+zqs(ind1)
1458      endif
1459
1460
1461
1462!-------------------------------------------------------------------------------
1463!Environment only in the gridbox
1464!-------------------------------------------------------------------------------
1465      ELSE
1466        !--------------------------------------------
1467        !calcul de qsat_env
1468        !--------------------------------------------
1469      Tbef=zthl(ind1,ind2)*zpspsk(ind1,ind2)
1470      zdelta=MAX(0.,SIGN(1.,RTT-Tbef))
1471      qsatbef= R2ES * FOEEW(Tbef,zdelta)/paprs(ind1,ind2)
1472      qsatbef=MIN(0.5,qsatbef)
1473      zcor=1./(1.-retv*qsatbef)
1474      qsatbef=qsatbef*zcor
1475      zqsatenv(ind1,ind2)=qsatbef
1476        !--------------------------------------------
1477        !calcul de s_env
1478        !--------------------------------------------
1479      alenv=(0.622*Lv*zqsatenv(ind1,ind2))/(rdd*zthl(ind1,ind2)**2)     !qsl, p84 these Arnaud Jam
1480      aenv=1./(1.+(alenv*Lv/cppd))                                      !al, p84 these Arnaud Jam
1481      senv=aenv*(po(ind1)-zqsatenv(ind1,ind2))                          !s, p84 these Arnaud Jam
1482        !--------------------------------------------
1483        !calcul standard deviations Gaussian PDF
1484        !--------------------------------------------
1485      zqenv(ind1)=po(ind1)
1486      sigma_env=ratqs(ind1,ind2)*zqenv(ind1)
1487      xenv=senv/(sqrt2*sigma_env)
1488        !--------------------------------------------
1489        !Cloud fraction by volume CF_vol
1490        !--------------------------------------------
1491      ctot_vol(ind1,ind2)=0.5*(1.+1.*erf(xenv))
1492        !--------------------------------------------
1493        !Condensed water qc
1494        !--------------------------------------------
1495      qltot(ind1,ind2)=sigma_env*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt2*ctot_vol(ind1,ind2))
1496        !--------------------------------------------
1497        !Cloud fraction by surface CF_surf
1498        !--------------------------------------------
1499        !Method Neggers et al. (2011) : ok for cumulus clouds only
1500      !beta=0.0044 (Jouhaud et al.2018)
1501      !inverse_rho=1.+beta*dz(ind1,ind2)
1502      !ctot_surf(ind1,ind2)=ctot_vol(ind1,ind2)*inverse_rho
1503        !Method Brooks et al. (2005) : ok for all types of clouds
1504      a_Brooks=0.6694
1505      b_Brooks=0.1882
1506      A_Maj_Brooks=0.1635 !-- sans dependence au shear
1507      Dx_Brooks=200000.
1508      f_Brooks=A_Maj_Brooks*(dz(ind1,ind2)**(a_Brooks))*(Dx_Brooks**(-b_Brooks))
1509      ctot_surf(ind1,ind2)=1./(1.+exp(-1.*f_Brooks)*((1./max(1.e-15,min(ctot_vol(ind1,ind2),1.)))- 1.))
1510        !--------------------------------------------
1511        !Incloud Condensed water qcloud
1512        !--------------------------------------------
1513      if (ctot_surf(ind1,ind2) .lt. 1.e-8) then
1514      ctot_vol(ind1,ind2)=0.
1515      ctot_surf(ind1,ind2)=0.
1516      qcloud(ind1)=zqsatenv(ind1,ind2)
1517      else
1518      qcloud(ind1)=qltot(ind1,ind2)/ctot_vol(ind1,ind2)+zqsatenv(ind1,ind2)
1519      endif
1520
1521
1522      END IF  ! From the separation (thermal/envrionnement) et (environnement only)
1523
1524      ! Outputs used to check the PDFs
1525      cloudth_senv(ind1,ind2) = senv
1526      cloudth_sth(ind1,ind2) = sth
1527      cloudth_sigmaenv(ind1,ind2) = sigma_env
1528      cloudth_sigmath(ind1,ind2) = sigma_th
1529
1530      END DO  ! From the loop on ngrid
1531      return
1532
1533END SUBROUTINE cloudth_v6
1534
1535
1536
1537
1538
1539!+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
1540SUBROUTINE cloudth_mpc(klon,klev,ind2,mpc_bl_points,                        &
1541&           temp,ztv,po,zqta,fraca,zpspsk,paprs,pplay,ztla,zthl,            &
1542&           ratqs,zqs,snowflux,qcloud,qincloud,icefrac,ctot,ctot_vol)
1543!+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
1544! Author : Arnaud Octavio Jam (LMD/CNRS), Etienne Vignon (LMDZ/CNRS)
1545! Date: Adapted from cloudth_vert_v3 in 2021
1546! Aim : computes qc and rneb in thermals with cold microphysical considerations
1547!       + for mixed phase boundary layer clouds, calculate ql and qi from
1548!       a stationary MPC model
1549! IMPORTANT NOTE: we assume iflag_clouth_vert=3
1550!+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
1551
1552
1553      USE ioipsl_getin_p_mod, ONLY : getin_p
1554      USE phys_output_var_mod, ONLY : cloudth_sth,cloudth_senv,cloudth_sigmath,cloudth_sigmaenv
1555      USE lscp_tools_mod, ONLY: CALC_QSAT_ECMWF, FALLICE_VELOCITY
1556      USE phys_local_var_mod, ONLY : qlth, qith, qsith, wiceth
1557
1558      IMPLICIT NONE
1559
1560#include "YOMCST.h"
1561#include "YOETHF.h"
1562#include "FCTTRE.h"
1563#include "nuage.h"
1564     
1565
1566!------------------------------------------------------------------------------
1567! Declaration
1568!------------------------------------------------------------------------------
1569
1570! INPUT/OUTPUT
1571
1572      INTEGER, INTENT(IN)                         :: klon,klev,ind2
1573     
1574
1575      REAL, DIMENSION(klon,klev), INTENT(IN)      ::  temp          ! Temperature [K]
1576      REAL, DIMENSION(klon,klev), INTENT(IN)      ::  ztv           ! Virtual potential temp [K]
1577      REAL, DIMENSION(klon),      INTENT(IN)      ::  po            ! specific humidity [kg/kg]
1578      REAL, DIMENSION(klon,klev), INTENT(IN)      ::  zqta          ! specific humidity within thermals [kg/kg]
1579      REAL, DIMENSION(klon,klev+1), INTENT(IN)    ::  fraca         ! Fraction of the mesh covered by thermals [0-1]
1580      REAL, DIMENSION(klon,klev), INTENT(IN)      ::  zpspsk
1581      REAL, DIMENSION(klon,klev+1), INTENT(IN)    ::  paprs         ! Pressure at layer interfaces [Pa]
1582      REAL, DIMENSION(klon,klev), INTENT(IN)      ::  pplay         ! Pressure at the center of layers [Pa]
1583      REAL, DIMENSION(klon,klev), INTENT(IN)      ::  ztla          ! Liquid temp [K]
1584      REAL, DIMENSION(klon,klev), INTENT(INOUT)      ::  zthl       ! Liquid potential temp [K]
1585      REAL, DIMENSION(klon,klev), INTENT(IN)      ::  ratqs         ! Parameter that determines the width of the total water distrib.
1586      REAL, DIMENSION(klon),      INTENT(IN)      ::  zqs           ! Saturation specific humidity in the mesh [kg/kg]
1587      REAL, DIMENSION(klon,klev+1), INTENT(IN)    ::  snowflux      ! snow flux at the interface of the layer [kg/m2/s]
1588
1589      INTEGER, DIMENSION(klon,klev), INTENT(INOUT) :: mpc_bl_points  ! grid points with convective (thermals) mixed phase clouds
1590     
1591      REAL, DIMENSION(klon,klev), INTENT(OUT)      ::  ctot         ! Cloud fraction [0-1]
1592      REAL, DIMENSION(klon,klev), INTENT(OUT)      ::  ctot_vol     ! Volume cloud fraction [0-1]
1593      REAL, DIMENSION(klon),      INTENT(OUT)      ::  qcloud       ! In cloud total water content [kg/kg]
1594      REAL, DIMENSION(klon),      INTENT(OUT)      ::  qincloud       ! In cloud condensed water content [kg/kg]
1595      REAL, DIMENSION(klon,klev), INTENT(OUT)      ::  icefrac      ! Fraction of ice in clouds [0-1]
1596
1597
1598! LOCAL VARIABLES
1599
1600      INTEGER itap,ind1,l,ig,iter,k
1601      INTEGER iflag_topthermals, niter
1602      LOGICAL falseklon(klon)
1603
1604      REAL zqsatth(klon), zqsatenv(klon), zqsatenvonly(klon)
1605      REAL sigma1(klon,klev)                                                         
1606      REAL sigma2(klon,klev)
1607      REAL qcth(klon,klev)
1608      REAL qcenv(klon,klev)
1609      REAL qctot(klon,klev)
1610      REAL cth(klon,klev)
1611      REAL cenv(klon,klev)   
1612      REAL cth_vol(klon,klev)
1613      REAL cenv_vol(klon,klev)
1614      REAL rneb(klon,klev)
1615      REAL zqenv(klon), zqth(klon), zqenvonly(klon)
1616      REAL qsatmmussig1,qsatmmussig2,sqrtpi,sqrt2,sqrt2pi,pi
1617      REAL rdd,cppd,Lv
1618      REAL alth,alenv,ath,aenv
1619      REAL sth,senv,sigma1s,sigma2s,sigma1s_fraca,sigma1s_ratqs
1620      REAL inverse_rho,beta,a_Brooks,b_Brooks,A_Maj_Brooks,Dx_Brooks,f_Brooks
1621      REAL xth,xenv,exp_xenv1,exp_xenv2,exp_xth1,exp_xth2
1622      REAL xth1,xth2,xenv1,xenv2,deltasth, deltasenv
1623      REAL IntJ,IntI1,IntI2,IntI3,IntJ_CF,IntI1_CF,IntI3_CF,coeffqlenv,coeffqlth
1624      REAL zdelta,qsatbef,zcor
1625      REAL Tbefth(klon), Tbefenv(klon), Tbefenvonly(klon), rhoth(klon)
1626      REAL qlbef
1627      REAL dqsatenv(klon), dqsatth(klon), dqsatenvonly(klon)
1628      REAL erf
1629      REAL zpdf_sig(klon),zpdf_k(klon),zpdf_delta(klon)
1630      REAL zpdf_a(klon),zpdf_b(klon),zpdf_e1(klon),zpdf_e2(klon)
1631      REAL rhodz(klon,klev)
1632      REAL zrho(klon,klev)
1633      REAL dz(klon,klev)
1634      REAL qslenv(klon), qslth(klon)
1635      REAL alenvl, aenvl
1636      REAL sthi, sthl, sthil, althl, athl, althi, athi, sthlc, deltasthc, sigma2sc
1637      REAL senvi, senvl, qbase, sbase, qliqth, qiceth
1638      REAL qmax, ttarget, stmp, cout, coutref, fraci
1639      REAL maxi, mini, pas, temp_lim
1640      REAL deltazlev_mpc(klev), temp_mpc(klev), pres_mpc(klev), fraca_mpc(klev+1), snowf_mpc(klev+1)
1641
1642      ! Modifty the saturation deficit PDF in thermals
1643      ! in the presence of ice crystals
1644      REAL,SAVE :: C_mpc
1645      !$OMP THREADPRIVATE(C_mpc)
1646      REAL, SAVE    :: Ni,C_cap,Ei,d_top
1647      !$OMP THREADPRIVATE(Ni,C_cap,Ei,d_top)
1648      ! Change the width of the PDF used for vertical subgrid scale heterogeneity
1649      ! (J Jouhaud, JL Dufresne, JB Madeleine)
1650      REAL,SAVE :: vert_alpha, vert_alpha_th
1651      !$OMP THREADPRIVATE(vert_alpha, vert_alpha_th)
1652      REAL,SAVE :: sigma1s_factor=1.1
1653      REAL,SAVE :: sigma1s_power=0.6
1654      REAL,SAVE :: sigma2s_factor=0.09
1655      REAL,SAVE :: sigma2s_power=0.5
1656      REAL,SAVE :: cloudth_ratqsmin=-1.
1657      !$OMP THREADPRIVATE(sigma1s_factor,sigma1s_power,sigma2s_factor,sigma2s_power,cloudth_ratqsmin)
1658      INTEGER, SAVE :: iflag_cloudth_vert_noratqs=0
1659      !$OMP THREADPRIVATE(iflag_cloudth_vert_noratqs)
1660      LOGICAL, SAVE :: firstcall = .TRUE.
1661      !$OMP THREADPRIVATE(firstcall)
1662
1663      CHARACTER (len = 80) :: abort_message
1664      CHARACTER (len = 20) :: routname = 'cloudth_mpc'
1665
1666
1667!------------------------------------------------------------------------------
1668! Initialisation
1669!------------------------------------------------------------------------------
1670
1671
1672! Few initial checksS
1673
1674      IF (iflag_cloudth_vert.NE.3) THEN
1675         abort_message = 'clouth_mpc cannot be used if iflag_cloudth_vert .NE. 3'
1676         CALL abort_physic(routname,abort_message,1)
1677      ENDIF
1678
1679      DO k = 1,klev
1680      DO ind1 = 1, klon
1681        rhodz(ind1,k) = (paprs(ind1,k)-paprs(ind1,k+1))/rg !kg/m2
1682        zrho(ind1,k) = pplay(ind1,k)/temp(ind1,k)/rd !kg/m3
1683        dz(ind1,k) = rhodz(ind1,k)/zrho(ind1,k) !m : epaisseur de la couche en metre
1684      END DO
1685      END DO
1686
1687
1688      sigma1(:,:)=0.
1689      sigma2(:,:)=0.
1690      qcth(:,:)=0.
1691      qcenv(:,:)=0. 
1692      qctot(:,:)=0.
1693      qlth(:,ind2)=0.
1694      qith(:,ind2)=0.
1695      wiceth(:,ind2)=0.
1696      rneb(:,:)=0.
1697      qcloud(:)=0.
1698      cth(:,:)=0.
1699      cenv(:,:)=0.
1700      ctot(:,:)=0.
1701      cth_vol(:,:)=0.
1702      cenv_vol(:,:)=0.
1703      ctot_vol(:,:)=0.
1704      falseklon(:)=.false.
1705      qsatmmussig1=0.
1706      qsatmmussig2=0.
1707      rdd=287.04
1708      cppd=1005.7
1709      pi=3.14159
1710      sqrt2pi=sqrt(2.*pi)
1711      sqrt2=sqrt(2.)
1712      sqrtpi=sqrt(pi)
1713      icefrac(:,ind2)=0.
1714      althl=0.
1715      althi=0.
1716      athl=0.
1717      athi=0.
1718      senvl=0.
1719      senvi=0.
1720      sthi=0.
1721      sthl=0.
1722      sthil=0.
1723
1724
1725
1726      IF (firstcall) THEN
1727
1728        vert_alpha=0.5
1729        CALL getin_p('cloudth_vert_alpha',vert_alpha)
1730        WRITE(*,*) 'cloudth_vert_alpha = ', vert_alpha
1731        ! The factor used for the thermal is equal to that of the environment
1732        !   if nothing is explicitly specified in the def file
1733        vert_alpha_th=vert_alpha
1734        CALL getin_p('cloudth_vert_alpha_th',vert_alpha_th)
1735        WRITE(*,*) 'cloudth_vert_alpha_th = ', vert_alpha_th
1736        ! Factor used in the calculation of sigma1s
1737        CALL getin_p('cloudth_sigma1s_factor',sigma1s_factor)
1738        WRITE(*,*) 'cloudth_sigma1s_factor = ', sigma1s_factor
1739        ! Power used in the calculation of sigma1s
1740        CALL getin_p('cloudth_sigma1s_power',sigma1s_power)
1741        WRITE(*,*) 'cloudth_sigma1s_power = ', sigma1s_power
1742        ! Factor used in the calculation of sigma2s
1743        CALL getin_p('cloudth_sigma2s_factor',sigma2s_factor)
1744        WRITE(*,*) 'cloudth_sigma2s_factor = ', sigma2s_factor
1745        ! Power used in the calculation of sigma2s
1746        CALL getin_p('cloudth_sigma2s_power',sigma2s_power)
1747        WRITE(*,*) 'cloudth_sigma2s_power = ', sigma2s_power
1748        ! Minimum value for the environmental air subgrid water distrib
1749        CALL getin_p('cloudth_ratqsmin',cloudth_ratqsmin)
1750        WRITE(*,*) 'cloudth_ratqsmin = ', cloudth_ratqsmin
1751        ! Remove the dependency to ratqs from the variance of the vertical PDF
1752        CALL getin_p('iflag_cloudth_vert_noratqs',iflag_cloudth_vert_noratqs)
1753        WRITE(*,*) 'iflag_cloudth_vert_noratqs = ', iflag_cloudth_vert_noratqs
1754        ! Modifies the PDF in thermals when ice crystals are present
1755        C_mpc=1.e4
1756        CALL getin_p('C_mpc',C_mpc)
1757        WRITE(*,*) 'C_mpc = ', C_mpc
1758        Ni=2.0e3
1759        CALL getin_p('Ni', Ni)
1760        WRITE(*,*) 'Ni = ', Ni
1761        Ei=0.5
1762        CALL getin_p('Ei', Ei)
1763        WRITE(*,*) 'Ei = ', Ei
1764        C_cap=0.5
1765        CALL getin_p('C_cap', C_cap)
1766        WRITE(*,*) 'C_cap = ', C_cap
1767        d_top=1.2
1768        CALL getin_p('d_top', d_top)
1769        WRITE(*,*) 'd_top = ', d_top
1770
1771        firstcall=.FALSE.
1772
1773      ENDIF
1774
1775
1776
1777!-------------------------------------------------------------------------------
1778! Identify grid points with potential mixed-phase conditions
1779!-------------------------------------------------------------------------------
1780
1781      temp_lim=RTT-40.0
1782
1783      DO ind1=1,klon
1784            IF ((temp(ind1,ind2) .LT. RTT) .AND. (temp(ind1,ind2) .GT. temp_lim) &
1785            .AND. (iflag_mpc_bl .GE. 1) .AND. (ind2<=klev-2)  &
1786            .AND. (ztv(ind1,1).GT.ztv(ind1,2)) .AND.(fraca(ind1,ind2).GT.1.e-10)) THEN
1787                mpc_bl_points(ind1,ind2)=1
1788            ELSE
1789                mpc_bl_points(ind1,ind2)=0
1790            ENDIF
1791      ENDDO
1792
1793
1794!-------------------------------------------------------------------------------
1795! Thermal fraction calculation and standard deviation of the distribution
1796!------------------------------------------------------------------------------- 
1797
1798! calculation of temperature, humidity and saturation specific humidity
1799
1800Tbefenv(:)=zthl(:,ind2)*zpspsk(:,ind2)
1801Tbefth(:)=ztla(:,ind2)*zpspsk(:,ind2)
1802Tbefenvonly(:)=temp(:,ind2)
1803rhoth(:)=paprs(:,ind2)/Tbefth(:)/RD
1804
1805zqenv(:)=(po(:)-fraca(:,ind2)*zqta(:,ind2))/(1.-fraca(:,ind2)) !qt = a*qtth + (1-a)*qtenv
1806zqth(:)=zqta(:,ind2)
1807zqenvonly(:)=po(:)
1808
1809
1810CALL CALC_QSAT_ECMWF(klon,Tbefenvonly,zqenvonly,paprs(:,ind2),RTT,0,.false.,zqsatenvonly,dqsatenv)
1811
1812CALL CALC_QSAT_ECMWF(klon,Tbefenv,zqenv,paprs(:,ind2),RTT,0,.false.,zqsatenv,dqsatenv)
1813CALL CALC_QSAT_ECMWF(klon,Tbefenv,zqenv,paprs(:,ind2),RTT,1,.false.,qslenv,dqsatenv)
1814
1815CALL CALC_QSAT_ECMWF(klon,Tbefth,zqth,paprs(:,ind2),RTT,1,.false.,qslth,dqsatth)
1816CALL CALC_QSAT_ECMWF(klon,Tbefth,zqth,paprs(:,ind2),RTT,2,.false.,qsith(:,ind2),dqsatth)
1817CALL CALC_QSAT_ECMWF(klon,Tbefth,zqth,paprs(:,ind2),RTT,0,.false.,zqsatth,dqsatth)
1818
1819
1820  DO ind1=1,klon
1821
1822
1823    IF ((ztv(ind1,1).GT.ztv(ind1,2)).AND.(fraca(ind1,ind2).GT.1.e-10)) THEN !Thermal and environnement
1824
1825
1826! Environment:
1827
1828
1829        IF (Tbefenv(ind1) .GE. RTT) THEN
1830               Lv=RLVTT
1831        ELSE
1832               Lv=RLSTT
1833        ENDIF
1834       
1835
1836        alenv=(0.622*Lv*zqsatenv(ind1))/(rdd*zthl(ind1,ind2)**2)     !qsl, p84
1837        aenv=1./(1.+(alenv*Lv/cppd))                                      !al, p84
1838        senv=aenv*(po(ind1)-zqsatenv(ind1))                          !s, p84
1839     
1840        ! For MPCs:
1841        IF (mpc_bl_points(ind1,ind2) .EQ. 1) THEN
1842        alenvl=(0.622*RLVTT*qslenv(ind1))/(rdd*zthl(ind1,ind2)**2)     
1843        aenvl=1./(1.+(alenv*Lv/cppd))         
1844        senvl=aenvl*(po(ind1)-qslenv(ind1))   
1845        senvi=senv
1846        ENDIF
1847
1848
1849! Thermals:
1850
1851
1852        IF (Tbefth(ind1) .GE. RTT) THEN
1853            Lv=RLVTT
1854        ELSE
1855            Lv=RLSTT
1856        ENDIF
1857
1858       
1859        alth=(0.622*Lv*zqsatth(ind1))/(rdd*ztla(ind1,ind2)**2)       
1860        ath=1./(1.+(alth*Lv/cppd))                                                         
1861        sth=ath*(zqta(ind1,ind2)-zqsatth(ind1))                     
1862
1863       ! For MPCs:
1864        IF (mpc_bl_points(ind1,ind2) .GT. 0) THEN
1865         althi=alth
1866         althl=(0.622*RLVTT*qslth(ind1))/(rdd*ztla(ind1,ind2)**2)                   
1867         athl=1./(1.+(alth*RLVTT/cppd))
1868         athi=alth     
1869         sthl=athl*(zqta(ind1,ind2)-qslth(ind1))   
1870         sthi=athi*(zqta(ind1,ind2)-qsith(ind1,ind2)) 
1871         sthil=athi*(zqta(ind1,ind2)-qslth(ind1))
1872        ENDIF     
1873
1874
1875
1876!-------------------------------------------------------------------------------
1877!  Version 3: Changes by J. Jouhaud; condensation for q > -delta s
1878!  Rq: in this subroutine, we assume iflag_clouth_vert .EQ. 3
1879!-------------------------------------------------------------------------------
1880
1881        IF (mpc_bl_points(ind1,ind2) .EQ. 0) THEN ! No BL MPC
1882
1883       ! Standard deviation of the distributions
1884
1885           sigma1s_fraca = (sigma1s_factor**0.5)*(fraca(ind1,ind2)**sigma1s_power) / &
1886           &                (1-fraca(ind1,ind2))*((sth-senv)**2)**0.5
1887
1888           IF (cloudth_ratqsmin>0.) THEN
1889             sigma1s_ratqs = cloudth_ratqsmin*po(ind1)
1890           ELSE
1891             sigma1s_ratqs = ratqs(ind1,ind2)*po(ind1)
1892           ENDIF
1893 
1894           sigma1s = sigma1s_fraca + sigma1s_ratqs
1895           sigma2s=(sigma2s_factor*(((sth-senv)**2)**0.5)/((fraca(ind1,ind2)+0.02)**sigma2s_power))+0.002*zqta(ind1,ind2)
1896
1897
1898           deltasenv=aenv*vert_alpha*sigma1s
1899           deltasth=ath*vert_alpha_th*sigma2s
1900
1901           xenv1=-(senv+deltasenv)/(sqrt(2.)*sigma1s)
1902           xenv2=-(senv-deltasenv)/(sqrt(2.)*sigma1s)
1903           exp_xenv1 = exp(-1.*xenv1**2)
1904           exp_xenv2 = exp(-1.*xenv2**2)
1905           xth1=-(sth+deltasth)/(sqrt(2.)*sigma2s)
1906           xth2=-(sth-deltasth)/(sqrt(2.)*sigma2s)
1907           exp_xth1 = exp(-1.*xth1**2)
1908           exp_xth2 = exp(-1.*xth2**2)
1909     
1910      !surface CF
1911
1912           cth(ind1,ind2)=0.5*(1.-1.*erf(xth1))
1913           cenv(ind1,ind2)=0.5*(1.-1.*erf(xenv1))
1914           ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)
1915
1916
1917      !volume CF and condensed water
1918
1919            !environnement
1920
1921            IntJ=0.5*senv*(1-erf(xenv2))+(sigma1s/sqrt2pi)*exp_xenv2
1922            IntJ_CF=0.5*(1.-1.*erf(xenv2))
1923
1924            IF (deltasenv .LT. 1.e-10) THEN
1925              qcenv(ind1,ind2)=IntJ
1926              cenv_vol(ind1,ind2)=IntJ_CF
1927            ELSE
1928              IntI1=(((senv+deltasenv)**2+(sigma1s)**2)/(8*deltasenv))*(erf(xenv2)-erf(xenv1))
1929              IntI2=(sigma1s**2/(4*deltasenv*sqrtpi))*(xenv1*exp_xenv1-xenv2*exp_xenv2)
1930              IntI3=((sqrt2*sigma1s*(senv+deltasenv))/(4*sqrtpi*deltasenv))*(exp_xenv1-exp_xenv2)
1931              IntI1_CF=((senv+deltasenv)*(erf(xenv2)-erf(xenv1)))/(4*deltasenv)
1932              IntI3_CF=(sqrt2*sigma1s*(exp_xenv1-exp_xenv2))/(4*sqrtpi*deltasenv)
1933              qcenv(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
1934              cenv_vol(ind1,ind2)=IntJ_CF+IntI1_CF+IntI3_CF
1935            ENDIF
1936             
1937
1938
1939            !thermals
1940
1941            IntJ=0.5*sth*(1-erf(xth2))+(sigma2s/sqrt2pi)*exp_xth2
1942            IntJ_CF=0.5*(1.-1.*erf(xth2))
1943     
1944            IF (deltasth .LT. 1.e-10) THEN
1945              qcth(ind1,ind2)=IntJ
1946              cth_vol(ind1,ind2)=IntJ_CF
1947            ELSE
1948              IntI1=(((sth+deltasth)**2+(sigma2s)**2)/(8*deltasth))*(erf(xth2)-erf(xth1))
1949              IntI2=(sigma2s**2/(4*deltasth*sqrtpi))*(xth1*exp_xth1-xth2*exp_xth2)
1950              IntI3=((sqrt2*sigma2s*(sth+deltasth))/(4*sqrtpi*deltasth))*(exp_xth1-exp_xth2)
1951              IntI1_CF=((sth+deltasth)*(erf(xth2)-erf(xth1)))/(4*deltasth)
1952              IntI3_CF=(sqrt2*sigma2s*(exp_xth1-exp_xth2))/(4*sqrtpi*deltasth)
1953              qlth(ind1,ind2)=IntJ+IntI1+IntI2+IntI3
1954              cth_vol(ind1,ind2)=IntJ_CF+IntI1_CF+IntI3_CF
1955            ENDIF
1956
1957              qctot(ind1,ind2)=fraca(ind1,ind2)*qcth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qcenv(ind1,ind2)
1958              ctot_vol(ind1,ind2)=fraca(ind1,ind2)*cth_vol(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv_vol(ind1,ind2)
1959             
1960
1961            IF (cenv(ind1,ind2).LT.1.e-10.or.cth(ind1,ind2).LT.1.e-10) THEN
1962                ctot(ind1,ind2)=0.
1963                ctot_vol(ind1,ind2)=0.
1964                qcloud(ind1)=zqsatenv(ind1)
1965                qincloud(ind1)=0.
1966            ELSE               
1967                qcloud(ind1)=qctot(ind1,ind2)/ctot(ind1,ind2)+zqs(ind1)
1968                qincloud(ind1)=qctot(ind1,ind2)/ctot(ind1,ind2)
1969            ENDIF
1970
1971
1972        ELSE ! mpc_bl_points>0
1973
1974            ! Treat boundary layer mixed phase clouds
1975           
1976            ! thermals
1977            !=========
1978
1979            ! ice phase
1980            !...........
1981
1982            qiceth=0.
1983            deltazlev_mpc=dz(ind1,:)
1984            temp_mpc=ztla(ind1,:)*zpspsk(ind1,:)
1985            pres_mpc=pplay(ind1,:)
1986            fraca_mpc=fraca(ind1,:)
1987            snowf_mpc=snowflux(ind1,:)
1988            iflag_topthermals=0
1989            IF ((mpc_bl_points(ind1,ind2) .EQ. 1) .AND. (mpc_bl_points(ind1,ind2+1) .EQ. 0))  THEN
1990                iflag_topthermals = 1
1991            ELSE IF ((mpc_bl_points(ind1,ind2) .EQ. 1) .AND. (mpc_bl_points(ind1,ind2+1) .EQ. 1) &
1992                    .AND. (mpc_bl_points(ind1,ind2+2) .EQ. 0) ) THEN
1993                iflag_topthermals = 2
1994            ELSE
1995                iflag_topthermals = 0
1996            ENDIF
1997
1998            CALL ICE_MPC_BL_CLOUDS(ind1,ind2,klev,Ni,Ei,C_cap,d_top,iflag_topthermals,temp_mpc,pres_mpc,zqta(ind1,:), &
1999                                   qsith(ind1,:),qlth(ind1,:),deltazlev_mpc,wiceth(ind1,:),fraca_mpc,qith(ind1,:))
2000
2001            ! qmax calculation
2002            sigma2s=(sigma2s_factor*((MAX((sthl-senvl),0.)**2)**0.5)/((fraca(ind1,ind2)+0.02)**sigma2s_power))+0.002*zqta(ind1,ind2)
2003            deltasth=athl*vert_alpha_th*sigma2s
2004            xth1=-(sthl+deltasth)/(sqrt(2.)*sigma2s)
2005            xth2=-(sthl-deltasth)/(sqrt(2.)*sigma2s)
2006            exp_xth1 = exp(-1.*xth1**2)
2007            exp_xth2 = exp(-1.*xth2**2)
2008            IntJ=0.5*sthl*(1-erf(xth2))+(sigma2s/sqrt2pi)*exp_xth2
2009            IntJ_CF=0.5*(1.-1.*erf(xth2))
2010            IntI1=(((sthl+deltasth)**2+(sigma2s)**2)/(8*deltasth))*(erf(xth2)-erf(xth1))
2011            IntI2=(sigma2s**2/(4*deltasth*sqrtpi))*(xth1*exp_xth1-xth2*exp_xth2)
2012            IntI3=((sqrt2*sigma2s*(sthl+deltasth))/(4*sqrtpi*deltasth))*(exp_xth1-exp_xth2)
2013            IntI1_CF=((sthl+deltasth)*(erf(xth2)-erf(xth1)))/(4*deltasth)
2014            IntI3_CF=(sqrt2*sigma2s*(exp_xth1-exp_xth2))/(4*sqrtpi*deltasth)
2015            qmax=MAX(IntJ+IntI1+IntI2+IntI3,0.)
2016
2017
2018            ! Liquid phase
2019            !................
2020            ! We account for the effect of ice crystals in thermals on sthl
2021            ! and on the width of the distribution
2022
2023            sthlc=sthl*1./(1.+C_mpc*qith(ind1,ind2))  &
2024                + (1.-1./(1.+C_mpc*qith(ind1,ind2))) * athl*(qsith(ind1,ind2)-qslth(ind1)) 
2025
2026            sigma2sc=(sigma2s_factor*((MAX((sthlc-senvl),0.)**2)**0.5) &
2027                 /((fraca(ind1,ind2)+0.02)**sigma2s_power)) &
2028                 +0.002*zqta(ind1,ind2)
2029            deltasthc=athl*vert_alpha_th*sigma2sc
2030     
2031           
2032            xth1=-(sthlc+deltasthc)/(sqrt(2.)*sigma2sc)
2033            xth2=-(sthlc-deltasthc)/(sqrt(2.)*sigma2sc)           
2034            exp_xth1 = exp(-1.*xth1**2)
2035            exp_xth2 = exp(-1.*xth2**2)
2036            IntJ=0.5*sthlc*(1-erf(xth2))+(sigma2sc/sqrt2pi)*exp_xth2
2037            IntJ_CF=0.5*(1.-1.*erf(xth2))
2038            IntI1=(((sthlc+deltasthc)**2+(sigma2sc)**2)/(8*deltasthc))*(erf(xth2)-erf(xth1))
2039            IntI2=(sigma2sc**2/(4*deltasthc*sqrtpi))*(xth1*exp_xth1-xth2*exp_xth2)
2040            IntI3=((sqrt2*sigma2sc*(sthlc+deltasthc))/(4*sqrtpi*deltasthc))*(exp_xth1-exp_xth2)
2041            IntI1_CF=((sthlc+deltasthc)*(erf(xth2)-erf(xth1)))/(4*deltasthc)
2042            IntI3_CF=(sqrt2*sigma2sc*(exp_xth1-exp_xth2))/(4*sqrtpi*deltasthc)
2043            qliqth=IntJ+IntI1+IntI2+IntI3
2044           
2045            qlth(ind1,ind2)=MAX(0.,qliqth)
2046
2047            ! Condensed water
2048           
2049            qcth(ind1,ind2)=qlth(ind1,ind2)+qith(ind1,ind2)
2050
2051
2052            ! consistency with subgrid distribution
2053           
2054             IF ((qcth(ind1,ind2) .GT. qmax) .AND. (qcth(ind1,ind2) .GT. 0)) THEN
2055                 fraci=qith(ind1,ind2)/qcth(ind1,ind2)
2056                 qcth(ind1,ind2)=qmax
2057                 qith(ind1,ind2)=fraci*qmax
2058                 qlth(ind1,ind2)=(1.-fraci)*qmax
2059             ENDIF
2060
2061            ! Cloud Fraction
2062            !...............
2063            ! calculation of qbase which is the value of the water vapor within mixed phase clouds
2064            ! such that the total water in cloud = qbase+qliqth+qiceth
2065            ! sbase is the value of s such that int_sbase^\intfy s ds = cloud fraction
2066            ! sbase and qbase calculation (note that sbase is wrt liq so negative)
2067            ! look for an approximate solution with iteration
2068           
2069            ttarget=qcth(ind1,ind2)
2070            mini= athl*(qsith(ind1,ind2)-qslth(ind1))
2071            maxi= 0. !athl*(3.*sqrt(sigma2s))
2072            niter=20
2073            pas=(maxi-mini)/niter
2074            stmp=mini
2075            sbase=stmp
2076            coutref=1.E6
2077            DO iter=1,niter
2078                cout=ABS(sigma2s/SQRT(2.*RPI)*EXP(-((sthl-stmp)/sigma2s)**2)+(sthl-stmp)/SQRT(2.)*(1.-erf(-(sthl-stmp)/sigma2s)) &
2079                     + stmp/2.*(1.-erf(-(sthl-stmp)/sigma2s)) -ttarget)
2080               IF (cout .LT. coutref) THEN
2081                     sbase=stmp
2082                     coutref=cout
2083                ELSE
2084                     stmp=stmp+pas
2085                ENDIF
2086            ENDDO
2087            qbase=MAX(0., sbase/athl+qslth(ind1))
2088
2089            ! surface cloud fraction in thermals
2090            cth(ind1,ind2)=0.5*(1.-erf((sbase-sthl)/sqrt(2.)/sigma2s))
2091            cth(ind1,ind2)=MIN(MAX(cth(ind1,ind2),0.),1.)
2092
2093
2094            !volume cloud fraction in thermals
2095            !to be checked
2096            xth1=-(sthl+deltasth-sbase)/(sqrt(2.)*sigma2s)
2097            xth2=-(sthl-deltasth-sbase)/(sqrt(2.)*sigma2s)           
2098            exp_xth1 = exp(-1.*xth1**2)
2099            exp_xth2 = exp(-1.*xth2**2)
2100
2101            IntJ=0.5*sthl*(1-erf(xth2))+(sigma2s/sqrt2pi)*exp_xth2
2102            IntJ_CF=0.5*(1.-1.*erf(xth2))
2103     
2104            IF (deltasth .LT. 1.e-10) THEN
2105              cth_vol(ind1,ind2)=IntJ_CF
2106            ELSE
2107              IntI1=(((sthl+deltasth-sbase)**2+(sigma2s)**2)/(8*deltasth))*(erf(xth2)-erf(xth1))
2108              IntI2=(sigma2s**2/(4*deltasth*sqrtpi))*(xth1*exp_xth1-xth2*exp_xth2)
2109              IntI3=((sqrt2*sigma2s*(sthl+deltasth))/(4*sqrtpi*deltasth))*(exp_xth1-exp_xth2)
2110              IntI1_CF=((sthl-sbase+deltasth)*(erf(xth2)-erf(xth1)))/(4*deltasth)
2111              IntI3_CF=(sqrt2*sigma2s*(exp_xth1-exp_xth2))/(4*sqrtpi*deltasth)
2112              cth_vol(ind1,ind2)=IntJ_CF+IntI1_CF+IntI3_CF
2113            ENDIF
2114              cth_vol(ind1,ind2)=MIN(MAX(0.,cth_vol(ind1,ind2)),1.)
2115
2116
2117
2118            ! Environment
2119            !=============
2120            ! In the environment/downdrafts, only liquid clouds
2121            ! See Shupe et al. 2008, JAS
2122
2123            ! standard deviation of the distribution in the environment
2124            sth=sthl
2125            senv=senvl
2126            sigma1s_fraca = (sigma1s_factor**0.5)*(fraca(ind1,ind2)**sigma1s_power) / &
2127                          &                (1-fraca(ind1,ind2))*(MAX((sth-senv),0.)**2)**0.5
2128            ! for mixed phase clouds, there is no contribution from large scale ratqs to the distribution
2129            ! in the environement
2130
2131            sigma1s_ratqs=1E-10
2132            IF (cloudth_ratqsmin>0.) THEN
2133                sigma1s_ratqs = cloudth_ratqsmin*po(ind1)
2134            ENDIF
2135
2136            sigma1s = sigma1s_fraca + sigma1s_ratqs
2137            deltasenv=aenvl*vert_alpha*sigma1s
2138            xenv1=-(senvl+deltasenv)/(sqrt(2.)*sigma1s)
2139            xenv2=-(senvl-deltasenv)/(sqrt(2.)*sigma1s)
2140            exp_xenv1 = exp(-1.*xenv1**2)
2141            exp_xenv2 = exp(-1.*xenv2**2)
2142
2143            !surface CF
2144            cenv(ind1,ind2)=0.5*(1.-1.*erf(xenv1))
2145
2146            !volume CF and condensed water
2147            IntJ=0.5*senvl*(1-erf(xenv2))+(sigma1s/sqrt2pi)*exp_xenv2
2148            IntJ_CF=0.5*(1.-1.*erf(xenv2))
2149
2150            IF (deltasenv .LT. 1.e-10) THEN
2151              qcenv(ind1,ind2)=IntJ
2152              cenv_vol(ind1,ind2)=IntJ_CF
2153            ELSE
2154              IntI1=(((senvl+deltasenv)**2+(sigma1s)**2)/(8*deltasenv))*(erf(xenv2)-erf(xenv1))
2155              IntI2=(sigma1s**2/(4*deltasenv*sqrtpi))*(xenv1*exp_xenv1-xenv2*exp_xenv2)
2156              IntI3=((sqrt2*sigma1s*(senv+deltasenv))/(4*sqrtpi*deltasenv))*(exp_xenv1-exp_xenv2)
2157              IntI1_CF=((senvl+deltasenv)*(erf(xenv2)-erf(xenv1)))/(4*deltasenv)
2158              IntI3_CF=(sqrt2*sigma1s*(exp_xenv1-exp_xenv2))/(4*sqrtpi*deltasenv)
2159              qcenv(ind1,ind2)=IntJ+IntI1+IntI2+IntI3 ! only liquid water in environment
2160              cenv_vol(ind1,ind2)=IntJ_CF+IntI1_CF+IntI3_CF
2161            ENDIF
2162
2163            qcenv(ind1,ind2)=MAX(qcenv(ind1,ind2),0.)
2164            cenv_vol(ind1,ind2)=MIN(MAX(cenv_vol(ind1,ind2),0.),1.)
2165
2166
2167           
2168            ! Thermals + environment
2169            ! =======================
2170            ctot(ind1,ind2)=fraca(ind1,ind2)*cth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv(ind1,ind2)
2171            qctot(ind1,ind2)=fraca(ind1,ind2)*qcth(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*qcenv(ind1,ind2)
2172            ctot_vol(ind1,ind2)=fraca(ind1,ind2)*cth_vol(ind1,ind2)+(1.-1.*fraca(ind1,ind2))*cenv_vol(ind1,ind2)
2173            IF (qcth(ind1,ind2) .GT. 0) THEN
2174               icefrac(ind1,ind2)=fraca(ind1,ind2)*qith(ind1,ind2) &
2175                    /(fraca(ind1,ind2)*qcth(ind1,ind2) &
2176                    +(1.-1.*fraca(ind1,ind2))*qcenv(ind1,ind2))
2177                icefrac(ind1,ind2)=MAX(MIN(1.,icefrac(ind1,ind2)),0.)
2178            ELSE
2179                icefrac(ind1,ind2)=0.
2180            ENDIF
2181
2182            IF (cenv(ind1,ind2).LT.1.e-10.or.cth(ind1,ind2).LT.1.e-10) THEN
2183                ctot(ind1,ind2)=0.
2184                ctot_vol(ind1,ind2)=0.
2185                qincloud(ind1)=0.
2186                qcloud(ind1)=zqsatenv(ind1)
2187            ELSE               
2188                qcloud(ind1)=fraca(ind1,ind2)*(qcth(ind1,ind2)/cth(ind1,ind2)+qbase) &
2189                            +(1.-1.*fraca(ind1,ind2))*(qcenv(ind1,ind2)/cenv(ind1,ind2)+qslenv(ind1))
2190                qincloud(ind1)=MAX(fraca(ind1,ind2)*(qcth(ind1,ind2)/cth(ind1,ind2)) &
2191                            +(1.-1.*fraca(ind1,ind2))*(qcenv(ind1,ind2)/cenv(ind1,ind2)),0.)
2192            ENDIF
2193
2194        ENDIF ! mpc_bl_points
2195
2196
2197    ELSE  ! gaussian for environment only
2198
2199     
2200
2201
2202        IF (Tbefenvonly(ind1) .GE. RTT) THEN
2203                Lv=RLVTT
2204        ELSE
2205                Lv=RLSTT
2206        ENDIF
2207       
2208
2209        zthl(ind1,ind2)=temp(ind1,ind2)*(101325./paprs(ind1,ind2))**(rdd/cppd)
2210        alenv=(0.622*Lv*zqsatenvonly(ind1))/(rdd*zthl(ind1,ind2)**2)
2211        aenv=1./(1.+(alenv*Lv/cppd))
2212        senv=aenv*(po(ind1)-zqsatenvonly(ind1))
2213        sth=0.
2214     
2215        sigma1s=ratqs(ind1,ind2)*zqenvonly(ind1)
2216        sigma2s=0.
2217
2218        sqrt2pi=sqrt(2.*pi)
2219        xenv=senv/(sqrt(2.)*sigma1s)
2220        ctot(ind1,ind2)=0.5*(1.+1.*erf(xenv))
2221        ctot_vol(ind1,ind2)=ctot(ind1,ind2)
2222        qctot(ind1,ind2)=sigma1s*((exp(-1.*xenv**2)/sqrt2pi)+xenv*sqrt(2.)*cenv(ind1,ind2))
2223     
2224        IF (ctot(ind1,ind2).LT.1.e-3) THEN
2225          ctot(ind1,ind2)=0.
2226          qcloud(ind1)=zqsatenvonly(ind1)
2227          qincloud(ind1)=0.
2228        ELSE
2229          qcloud(ind1)=qctot(ind1,ind2)/ctot(ind1,ind2)+zqsatenvonly(ind1)
2230          qincloud(ind1)=MAX(qctot(ind1,ind2)/ctot(ind1,ind2),0.)
2231        ENDIF
2232 
2233
2234    ENDIF       ! From the separation (thermal/envrionnement) and (environnement only,) l.335 et l.492
2235
2236    ! Outputs used to check the PDFs
2237    cloudth_senv(ind1,ind2) = senv
2238    cloudth_sth(ind1,ind2) = sth
2239    cloudth_sigmaenv(ind1,ind2) = sigma1s
2240    cloudth_sigmath(ind1,ind2) = sigma2s
2241
2242
2243    ENDDO       !loop on klon
2244
2245    ! Calcule ice fall velocity in thermals
2246
2247    CALL FALLICE_VELOCITY(klon,qith(:,ind2),Tbefth(:),rhoth(:),paprs(:,ind2),falseklon(:),wiceth(:,ind2))
2248
2249RETURN
2250
2251
2252END SUBROUTINE cloudth_mpc
2253
2254!++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
2255SUBROUTINE ICE_MPC_BL_CLOUDS(ind1,ind2,klev,Ni,Ei,C_cap,d_top,iflag_topthermals,temp,pres,qth,qsith,qlth,deltazlev,vith,fraca,qith)
2256
2257! parameterization of ice for boundary
2258! layer mixed-phase clouds assuming a stationary system
2259!
2260! Note that vapor deposition on ice crystals and riming of liquid droplets
2261! depend on the ice number concentration Ni
2262! One could assume that Ni depends on qi, e.g.,  Ni=beta*(qi*rho)**xi
2263! and use values from Hong et al. 2004, MWR for instance
2264! One may also estimate Ni as a function of T, as in Meyers 1922 or Fletcher 1962
2265! One could also think of a more complex expression of Ni;
2266! function of qi, T, the concentration in aerosols or INP ..
2267! Here we prefer fixing Ni to a tuning parameter
2268! By default we take 2.0L-1=2.0e3m-3, median value from measured vertical profiles near Svalbard
2269! in Mioche et al. 2017
2270!
2271!
2272! References:
2273!------------
2274! This parameterization is thoroughly described in Vignon et al.
2275!
2276! More specifically
2277! for the Water vapor deposition process:
2278!
2279! Rotstayn, L. D., 1997: A physically based scheme for the treat-
2280! ment of stratiform cloudfs and precipitation in large-scale
2281! models. I: Description and evaluation of the microphysical
2282! processes. Quart. J. Roy. Meteor. Soc., 123, 1227–1282.
2283!
2284!  Morrison, H., and A. Gettelman, 2008: A new two-moment bulk
2285!  stratiform cloud microphysics scheme in the NCAR Com-
2286!  munity Atmosphere Model (CAM3). Part I: Description and
2287!  numerical tests. J. Climate, 21, 3642–3659
2288!
2289! for the Riming process:
2290!
2291! Rutledge, S. A., and P. V. Hobbs, 1983: The mesoscale and micro-
2292! scale structure and organization of clouds and precipitation in
2293! midlatitude cyclones. VII: A model for the ‘‘seeder-feeder’’
2294! process in warm-frontal rainbands. J. Atmos. Sci., 40, 1185–1206
2295!
2296! Thompson, G., R. M. Rasmussen, and K. Manning, 004: Explicit
2297! forecasts of winter precipitation using an improved bulk
2298! microphysics scheme. Part I: Description and sensitivityThompson, G., R. M. Rasmussen, and K. Manning, 2004: Explicit
2299! forecasts of winter precipitation using an improved bulk
2300! microphysics scheme. Part I: Description and sensitivity analysis. Mon. Wea. Rev., 132, 519–542
2301!
2302! For the formation of clouds by thermals:
2303!
2304! Rio, C., & Hourdin, F. (2008). A thermal plume model for the convective boundary layer : Representation of cumulus clouds. Journal of
2305! the Atmospheric Sciences, 65, 407–425.
2306!
2307! Jam, A., Hourdin, F., Rio, C., & Couvreux, F. (2013). Resolved versus parametrized boundary-layer plumes. Part III: Derivation of a
2308! statistical scheme for cumulus clouds. Boundary-layer Meteorology, 147, 421–441. https://doi.org/10.1007/s10546-012-9789-3
2309!
2310!
2311!
2312! Contact: Etienne Vignon, etienne.vignon@lmd.ipsl.fr
2313!=============================================================================
2314
2315    USE ioipsl_getin_p_mod, ONLY : getin_p
2316    USE phys_state_var_mod, ONLY : fm_therm, detr_therm, entr_therm
2317
2318    IMPLICIT none
2319
2320    INCLUDE "YOMCST.h"
2321    INCLUDE "nuage.h"
2322
2323    INTEGER, INTENT(IN) :: ind1,ind2, klev           ! horizontal and vertical indices and dimensions
2324    INTEGER, INTENT(IN) :: iflag_topthermals         ! uppermost layer of thermals ?
2325    REAL, INTENT(IN)    :: Ni                        ! ice number concentration [m-3]
2326    REAL, INTENT(IN)    :: Ei                        ! ice-droplet collision efficiency
2327    REAL, INTENT(IN)    :: C_cap                     ! ice crystal capacitance
2328    REAL, INTENT(IN)    :: d_top                     ! cloud-top ice crystal mixing parameter
2329    REAL,  DIMENSION(klev), INTENT(IN) :: temp       ! temperature [K] within thermals
2330    REAL,  DIMENSION(klev), INTENT(IN) :: pres       ! pressure [Pa]
2331    REAL,  DIMENSION(klev), INTENT(IN) :: qth        ! mean specific water content in thermals [kg/kg]
2332    REAL,  DIMENSION(klev), INTENT(IN) :: qsith        ! saturation specific humidity wrt ice in thermals [kg/kg]
2333    REAL,  DIMENSION(klev), INTENT(IN) :: qlth       ! condensed liquid water in thermals, approximated value [kg/kg]
2334    REAL,  DIMENSION(klev), INTENT(IN) :: deltazlev  ! layer thickness [m]
2335    REAL,  DIMENSION(klev), INTENT(IN) :: vith       ! ice crystal fall velocity [m/s]
2336    REAL,  DIMENSION(klev+1), INTENT(IN) :: fraca      ! fraction of the mesh covered by thermals
2337    REAL,  DIMENSION(klev), INTENT(INOUT) :: qith       ! condensed ice water , thermals [kg/kg]
2338
2339
2340    INTEGER ind2p1,ind2p2
2341    REAL rho(klev)
2342    REAL unsurtaudet, unsurtaustardep, unsurtaurim
2343    REAL qi, AA, BB, Ka, Dv, rhoi
2344    REAL p0, t0, fp1, fp2
2345    REAL alpha, flux_term
2346    REAL det_term, precip_term, rim_term, dep_term
2347
2348
2349    ind2p1=ind2+1
2350    ind2p2=ind2+2
2351
2352    rho=pres/temp/RD  ! air density kg/m3
2353
2354    Ka=2.4e-2      ! thermal conductivity of the air, SI
2355    p0=101325.0    ! ref pressure
2356    T0=273.15      ! ref temp
2357    rhoi=500.0     ! cloud ice density following Reisner et al. 1998
2358    alpha=700.     ! fallvelocity param
2359
2360
2361    IF (iflag_topthermals .GT. 0) THEN ! uppermost thermals levels
2362
2363    Dv=0.0001*0.211*(p0/pres(ind2))*((temp(ind2)/T0)**1.94) ! water vapor diffusivity in air, SI
2364
2365    ! Detrainment term:
2366
2367    unsurtaudet=detr_therm(ind1,ind2)/rho(ind2)/deltazlev(ind2)
2368 
2369
2370    ! Deposition term
2371    AA=RLSTT/Ka/temp(ind2)*(RLSTT/RV/temp(ind2)-1.)
2372    BB=1./(rho(ind2)*Dv*qsith(ind2))
2373    unsurtaustardep=C_cap*(Ni**0.66)*(qth(ind2)-qsith(ind2))/qsith(ind2) &
2374                    *4.*RPI/(AA+BB)*(6.*rho(ind2)/rhoi/RPI/Gamma(4.))**(0.33)
2375
2376    ! Riming term  neglected at this level
2377    !unsurtaurim=rho(ind2)*alpha*3./rhoi/2.*Ei*qlth(ind2)*((p0/pres(ind2))**0.4)
2378
2379    qi=fraca(ind2)*unsurtaustardep/MAX((d_top*unsurtaudet),1E-12)
2380    qi=MAX(qi,0.)**(3./2.)
2381
2382    ELSE ! other levels, estimate qi(k) from variables at k+1 and k+2
2383
2384    Dv=0.0001*0.211*(p0/pres(ind2p1))*((temp(ind2p1)/T0)**1.94) ! water vapor diffusivity in air, SI
2385
2386    ! Detrainment term:
2387
2388    unsurtaudet=detr_therm(ind1,ind2p1)/rho(ind2p1)/deltazlev(ind2p1)
2389    det_term=-unsurtaudet*qith(ind2p1)*rho(ind2p1)
2390   
2391   
2392    ! Deposition term
2393
2394    AA=RLSTT/Ka/temp(ind2p1)*(RLSTT/RV/temp(ind2p1)-1.)
2395    BB=1./(rho(ind2p1)*Dv*qsith(ind2p1))
2396    unsurtaustardep=C_cap*(Ni**0.66)*(qth(ind2p1)-qsith(ind2p1)) &
2397         /qsith(ind2p1)*4.*RPI/(AA+BB) &
2398         *(6.*rho(ind2p1)/rhoi/RPI/Gamma(4.))**(0.33)
2399    dep_term=rho(ind2p1)*fraca(ind2p1)*(qith(ind2p1)**0.33)*unsurtaustardep
2400 
2401    ! Riming term
2402
2403    unsurtaurim=rho(ind2p1)*alpha*3./rhoi/2.*Ei*qlth(ind2p1)*((p0/pres(ind2p1))**0.4)
2404    rim_term=rho(ind2p1)*fraca(ind2p1)*qith(ind2p1)*unsurtaurim
2405
2406    ! Precip term
2407
2408    ! We assume that there is no solid precipitation outside thermals
2409    ! so the precipitation flux within thermals is equal to the precipitation flux
2410    ! at mesh-scale divided by  thermals fraction
2411   
2412    fp2=0.
2413    fp1=0.
2414    IF (fraca(ind2p1) .GT. 0.) THEN
2415    fp2=-qith(ind2p2)*rho(ind2p2)*vith(ind2p2)*fraca(ind2p2)! flux defined positive upward
2416    fp1=-qith(ind2p1)*rho(ind2p1)*vith(ind2p1)*fraca(ind2p1)
2417    ENDIF
2418
2419    precip_term=-1./deltazlev(ind2p1)*(fp2-fp1)
2420
2421    ! Calculation in a top-to-bottom loop
2422
2423    IF (fm_therm(ind1,ind2p1) .GT. 0.) THEN
2424          qi= 1./fm_therm(ind1,ind2p1)* &
2425              (deltazlev(ind2p1)*(-rim_term-dep_term-det_term-precip_term) + &
2426              fm_therm(ind1,ind2p2)*(qith(ind2p1)))
2427    END IF
2428
2429    ENDIF ! top thermals
2430
2431    qith(ind2)=MAX(0.,qi)
2432
2433    RETURN
2434
2435END SUBROUTINE ICE_MPC_BL_CLOUDS
2436
2437
2438
2439
2440END MODULE cloudth_mod
2441
2442
2443
2444
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