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lmdz_ratqs_main.F90 @ 4678

Last change on this file since 4678 was 4613, checked in by fhourdin, 11 months ago
Integration/replay_isation travail Louis (ratqs)
Property copyright set to Name of program: LMDZ Creation date: 1984 Version: LMDZ5 License: CeCILL version 2 Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539 See the license file in the root directory
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1	MODULE lmdz_ratqs_main
2
3	CONTAINS
4
5	SUBROUTINE ratqs_main(klon,klev,nbsrf,prt_level,lunout, &
6	iflag_ratqs,iflag_con,iflag_cld_th,pdtphys, &
7	ratqsbas,ratqshaut,ratqsp0,ratqsdp, &
8	pctsrf,s_pblh,zstd, &
9	tau_ratqs,fact_cldcon,wake_s, wake_deltaq, &
10	ptconv,ptconvth,clwcon0th, rnebcon0th, &
11	paprs,pplay,t_seri,q_seri, &
12	qtc_cv, sigt_cv,detrain_cv,fm_cv,fqd,fqcomp,sigd,zqsat, &
13	omega,tke,tke_dissip,lmix,wprime, &
14	t2m,q2m,fm_therm,entr_therm,detr_therm,cell_area,&
15	ratqs,ratqsc,ratqs_inter_)
16
17
18	USE lmdz_ratqs_multi, ONLY: ratqs_inter, ratqs_oro, ratqs_hetero, ratqs_tke
19
20	implicit none
21
22	!========================================================================
23	! Computation of ratqs, the width of the subrid scale water distribution
24	! (normalized by the mean value)
25	! Various options controled by flags iflag_con and iflag_ratqs
26	! F Hourdin 2012/12/06
27	!========================================================================
28
29	! Declarations
30
31	! Input
32	integer,intent(in) :: klon,klev,nbsrf,prt_level,lunout
33	integer,intent(in) :: iflag_con,iflag_cld_th,iflag_ratqs
34	real,intent(in) :: pdtphys,ratqsbas,ratqshaut,fact_cldcon,tau_ratqs
35	real,intent(in) :: ratqsp0, ratqsdp
36	real, dimension(klon,klev),intent(in) :: omega
37	real, dimension(klon,klev+1),intent(in) :: paprs,tke,tke_dissip,lmix,wprime
38	real, dimension(klon,klev),intent(in) :: pplay,t_seri,q_seri,zqsat
39	real, dimension(klon,klev),intent(in) :: entr_therm,detr_therm,qtc_cv, sigt_cv
40	real, dimension(klon,klev) :: detrain_cv,fm_cv,fqd,fqcomp
41	real, dimension(klon) :: sigd
42
43	real, dimension(klon,klev+1),intent(in) :: fm_therm
44	logical, dimension(klon,klev),intent(in) :: ptconv
45	real, dimension(klon,klev),intent(in) :: rnebcon0th,clwcon0th
46	real, dimension(klon,klev),intent(in) :: wake_deltaq,wake_s
47	real, dimension(klon,nbsrf),intent(in) :: t2m,q2m
48	real, dimension(klon), intent(in) :: cell_area
49	real, dimension(klon,nbsrf),intent(in) :: pctsrf
50	real, dimension(klon),intent(in) :: s_pblh
51	real, dimension(klon),intent(in) :: zstd
52
53	! Output
54	real, dimension(klon,klev),intent(inout) :: ratqs,ratqsc,ratqs_inter_
55
56	logical, dimension(klon,klev),intent(inout) :: ptconvth
57
58	! local
59	integer i,k
60	real, dimension(klon,klev) :: ratqss
61	real facteur,zfratqs1,zfratqs2
62	real, dimension(klon,klev) :: ratqs_hetero_,ratqs_oro_,ratqs_tke_
63	real resol,resolmax,fact
64
65	!-------------------------------------------------------------------------
66	! Caclul des ratqs
67	!-------------------------------------------------------------------------
68
69	! print*,'calcul des ratqs'
70	! ratqs convectifs a l'ancienne en fonction de q(z=0)-q / q
71	! ----------------
72	! on ecrase le tableau ratqsc calcule par clouds_gno
73	if (iflag_cld_th.eq.1) then
74	do k=1,klev
75	do i=1,klon
76	if(ptconv(i,k)) then
77	ratqsc(i,k)=ratqsbas &
78	+fact_cldcon*(q_seri(i,1)-q_seri(i,k))/q_seri(i,k)
79	else
80	ratqsc(i,k)=0.
81	endif
82	enddo
83	enddo
84
85	!-----------------------------------------------------------------------
86	! par nversion de la fonction log normale
87	!-----------------------------------------------------------------------
88	else if (iflag_cld_th.eq.4) then
89	ptconvth(:,:)=.false.
90	ratqsc(:,:)=0.
91	if(prt_level.ge.9) print*,'avant clouds_gno thermique'
92	call clouds_gno &
93	(klon,klev,q_seri,zqsat,clwcon0th,ptconvth,ratqsc,rnebcon0th)
94	if(prt_level.ge.9) print*,' CLOUDS_GNO OK'
95
96	endif
97
98	! ratqs stables
99	! -------------
100
101	if (iflag_ratqs.eq.0) then
102
103	! Le cas iflag_ratqs=0 correspond a la version IPCC 2005 du modele.
104	do k=1,klev
105	do i=1, klon
106	ratqss(i,k)=ratqsbas+(ratqshaut-ratqsbas)* &
107	min((paprs(i,1)-pplay(i,k))/(paprs(i,1)-30000.),1.)
108	enddo
109	enddo
110
111	! Pour iflag_ratqs=1 ou 2, le ratqs est constant au dessus de
112	! 300 hPa (ratqshaut), varie lineariement en fonction de la pression
113	! entre 600 et 300 hPa et est soit constant (ratqsbas) pour iflag_ratqs=1
114	! soit lineaire (entre 0 a la surface et ratqsbas) pour iflag_ratqs=2
115	! Il s'agit de differents tests dans la phase de reglage du modele
116	! avec thermiques.
117
118	else if (iflag_ratqs.eq.1) then
119
120	do k=1,klev
121	do i=1, klon
122	if (pplay(i,k).ge.60000.) then
123	ratqss(i,k)=ratqsbas
124	else if ((pplay(i,k).ge.30000.).and.(pplay(i,k).lt.60000.)) then
125	ratqss(i,k)=ratqsbas+(ratqshaut-ratqsbas)*(60000.-pplay(i,k))/(60000.-30000.)
126	else
127	ratqss(i,k)=ratqshaut
128	endif
129	enddo
130	enddo
131
132	else if (iflag_ratqs.eq.2) then
133
134	do k=1,klev
135	do i=1, klon
136	if (pplay(i,k).ge.60000.) then
137	ratqss(i,k)=ratqsbas*(paprs(i,1)-pplay(i,k))/(paprs(i,1)-60000.)
138	else if ((pplay(i,k).ge.30000.).and.(pplay(i,k).lt.60000.)) then
139	ratqss(i,k)=ratqsbas+(ratqshaut-ratqsbas)*(60000.-pplay(i,k))/(60000.-30000.)
140	else
141	ratqss(i,k)=ratqshaut
142	endif
143	enddo
144	enddo
145
146	else if (iflag_ratqs==3) then
147	do k=1,klev
148	ratqss(:,k)=ratqsbas+(ratqshaut-ratqsbas) &
149	min( ((paprs(:,1)-pplay(:,k))/70000.)*2 , 1. )
150	enddo
151
152	else if (iflag_ratqs==4) then
153	do k=1,klev
154	ratqss(:,k)=ratqsbas+0.5*(ratqshaut-ratqsbas) &
155	! *( tanh( (50000.-pplay(:,k))/20000.) + 1.)
156	*( tanh( (ratqsp0-pplay(:,k))/ratqsdp) + 1.)
157	enddo
158
159
160	else if (iflag_ratqs==5) then
161	! Dependency of ratqs on model resolution
162	! Audran, Meryl, Lea, Gwendal and Etienne
163	! April 2023
164	resolmax=sqrt(maxval(cell_area))
165	do k=1,klev
166	do i=1,klon
167	resol=sqrt(cell_area(i))
168	fact=sqrt(resol/resolmax)
169	ratqss(i,k)=ratqsbasfact+0.5(ratqshaut-ratqsbas)*fact &
170	*( tanh( (ratqsp0-pplay(i,k))/ratqsdp) + 1.)
171	enddo
172	enddo
173
174
175	else if (iflag_ratqs .GT. 9) then
176
177	! interactive ratqs calculations that depend on cold pools, orography, surface heterogeneity and small-scale turbulence
178	! This should help getting a more realistic ratqs in the low and mid troposphere
179	! We however need a "background" ratqs to account for subgrid distribution of qt (or qt/qs)
180	! in the high troposphere
181
182	! background ratqs and initialisations
183	do k=1,klev
184	do i=1,klon
185	ratqss(i,k)=ratqsbas+0.5*(ratqshaut-ratqsbas) &
186	*( tanh( (ratqsp0-pplay(i,k))/ratqsdp) + 1.)
187	ratqss(i,k)=max(ratqss(i,k),0.0)
188	ratqs_hetero_(i,k)=0.
189	ratqs_oro_(i,k)=0.
190	ratqs_tke_(i,k)=0.
191	ratqs_inter_(i,k)=0
192	enddo
193	enddo
194
195	if (iflag_ratqs .EQ. 10) then
196	! interactive ratqs in presence of cold pools
197	call ratqs_inter(klon,klev,iflag_ratqs,pdtphys,paprs, &
198	ratqsbas,wake_deltaq,wake_s,q_seri,qtc_cv, sigt_cv, &
199	fm_therm,entr_therm,detr_therm,detrain_cv,fm_cv,fqd,fqcomp,sigd, &
200	ratqs_inter_)
201	do k=1,klev
202	do i=1,klon
203	ratqs_inter_(i,k)=ratqs_inter_(i,k)-0.5ratqs_inter_(i,k)(tanh((ratqsp0-pplay(i,k))/ratqsdp)+1.)
204	enddo
205	enddo
206	ratqss=ratqss+ratqs_inter_
207	else if (iflag_ratqs .EQ. 11) then
208	print*,'avant ratqs_inter'
209	! interactive ratqs with several sources
210	call ratqs_inter(klon,klev,iflag_ratqs,pdtphys,paprs, &
211	ratqsbas,wake_deltaq,wake_s,q_seri,qtc_cv, sigt_cv, &
212	fm_therm,entr_therm,detr_therm,detrain_cv,fm_cv,fqd,fqcomp,sigd, &
213	ratqs_inter_)
214	ratqss=ratqss+ratqs_inter_
215	else if (iflag_ratqs .EQ. 12) then
216	! contribution of surface heterogeneities to ratqs
217	call ratqs_hetero(klon,klev,pctsrf,s_pblh,t2m,q2m,t_seri,q_seri,pplay,paprs,ratqs_hetero_)
218	ratqss=ratqss+ratqs_hetero_
219	else if (iflag_ratqs .EQ. 13) then
220	! contribution of ubgrid orography to ratqs
221	call ratqs_oro(klon,klev,pctsrf,zstd,zqsat,t_seri,pplay,paprs,ratqs_oro_)
222	ratqss=ratqss+ratqs_oro_
223	else if (iflag_ratqs .EQ. 14) then
224	! effect of subgrid-scale TKE on ratqs (in development)
225	call ratqs_tke(klon,klev,pdtphys,t_seri,q_seri,zqsat,pplay,paprs,omega,tke,tke_dissip,lmix,wprime,ratqs_tke_)
226	ratqss=ratqss+ratqs_tke_
227	endif
228
229
230	endif
231
232
233	! ratqs final
234	! -----------
235
236	if (iflag_cld_th.eq.1 .or.iflag_cld_th.eq.2.or.iflag_cld_th.eq.4) then
237
238	! On ajoute une constante au ratqsc*2 pour tenir compte de
239	! fluctuations turbulentes de petite echelle
240
241	do k=1,klev
242	do i=1,klon
243	if ((fm_therm(i,k)>1.e-10)) then
244	ratqsc(i,k)=sqrt(ratqsc(i,k)2+0.052)
245	endif
246	enddo
247	enddo
248
249	! les ratqs sont une combinaison de ratqss et ratqsc
250	if(prt_level.ge.9) write(lunout,*)'PHYLMD NOUVEAU TAU_RATQS ',tau_ratqs
251
252	if (tau_ratqs>1.e-10) then
253	facteur=exp(-pdtphys/tau_ratqs)
254	else
255	facteur=0.
256	endif
257	ratqs(:,:)=ratqsc(:,:)(1.-facteur)+ratqs(:,:)facteur
258	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
259	! FH 22/09/2009
260	! La ligne ci-dessous faisait osciller le modele et donnait une solution
261	! assymptotique bidon et dépendant fortement du pas de temps.
262	! ratqs(:,:)=sqrt(ratqs(:,:)2+ratqss(:,:)2)
263	!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
264	ratqs(:,:)=max(ratqs(:,:),ratqss(:,:))
265	else if (iflag_cld_th<=6) then
266	! on ne prend que le ratqs stable pour fisrtilp
267	ratqs(:,:)=ratqss(:,:)
268	else
269	zfratqs1=exp(-pdtphys/10800.)
270	zfratqs2=exp(-pdtphys/10800.)
271	do k=1,klev
272	do i=1,klon
273	if (ratqsc(i,k).gt.1.e-10) then
274	ratqs(i,k)=ratqs(i,k)zfratqs2+(iflag_cld_th/100.)ratqsc(i,k)*(1.-zfratqs2)
275	endif
276	ratqs(i,k)=min(ratqs(i,k)zfratqs1+ratqss(i,k)(1.-zfratqs1),0.5)
277	enddo
278	enddo
279	endif
280
281
282	return
283	END SUBROUTINE ratqs_main
284
285	END MODULE lmdz_ratqs_main

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