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closea.F90 @ 2456

Last change on this file since 2456 was 2456, checked in by acosce, 9 years ago
Add new configuration IPSLCM6CHT
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1	MODULE closea
2	!!======================================================================
3	!! * MODULE closea *
4	!! Closed Seas : specific treatments associated with closed seas
5	!!======================================================================
6	!! History : 8.2 ! 00-05 (O. Marti) Original code
7	!! 8.5 ! 02-06 (E. Durand, G. Madec) F90
8	!! 9.0 ! 06-07 (G. Madec) add clo_rnf, clo_ups, clo_bat
9	!! NEMO 3.4 ! 03-12 (P.G. Fogli) sbc_clo bug fix & mpp reproducibility
10	!!----------------------------------------------------------------------
11
12	!!----------------------------------------------------------------------
13	!! dom_clo : modification of the ocean domain for closed seas cases
14	!! sbc_clo : Special handling of closed seas
15	!! clo_rnf : set close sea outflows as river mouths (see sbcrnf)
16	!! clo_ups : set mixed centered/upstream scheme in closed sea (see traadv_cen2)
17	!! clo_bat : set to zero a field over closed sea (see domzrg)
18	!!----------------------------------------------------------------------
19	USE oce ! dynamics and tracers
20	USE dom_oce ! ocean space and time domain
21	USE phycst ! physical constants
22	USE in_out_manager ! I/O manager
23	!USE iom ! I/O manager library
24	USE sbc_oce ! ocean surface boundary conditions
25	USE lib_fortran, ONLY: glob_sum, DDPDD
26	USE lbclnk ! lateral boundary condition - MPP exchanges
27	USE lib_mpp ! MPP library
28	USE timing
29
30	IMPLICIT NONE
31	PRIVATE
32
33	PUBLIC dom_clo ! routine called by domain module
34	PUBLIC sbc_clo ! routine called by step module
35	PUBLIC clo_rnf ! routine called by sbcrnf module
36	PUBLIC clo_ups ! routine called in traadv_cen2(_jki) module
37	PUBLIC clo_bat ! routine called in domzgr module
38
39	INTEGER, PUBLIC, PARAMETER :: jpncs = 4 !: number of closed sea
40	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncstt !: Type of closed sea
41	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncsi1, ncsj1 !: south-west closed sea limits (i,j)
42	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncsi2, ncsj2 !: north-east closed sea limits (i,j)
43	INTEGER, PUBLIC, DIMENSION(jpncs) :: ncsnr !: number of point where run-off pours
44	INTEGER, PUBLIC, DIMENSION(jpncs,4) :: ncsir, ncsjr !: Location of runoff
45
46	REAL(wp), DIMENSION (:,:), ALLOCATABLE :: clo_mask !: Defines area where excess run-off is distributed
47
48	REAL(wp), DIMENSION (jpncs+1) :: surf !: Closed sea surface
49
50	INTEGER :: dia_closea_alloc
51
52	!! * Substitutions
53	# include "vectopt_loop_substitute.h90"
54	!!----------------------------------------------------------------------
55	!! NEMO/OPA 3.3 , NEMO Consortium (2010)
56	!! $Id: closea.F90 4162 2013-11-07 10:19:49Z cetlod $
57	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
58	!!----------------------------------------------------------------------
59	CONTAINS
60
61	SUBROUTINE dom_clo
62	!!---------------------------------------------------------------------
63	!! * ROUTINE dom_clo *
64	!!
65	!! ** Purpose : Closed sea domain initialization
66	!!
67	!! ** Method : if a closed sea is located only in a model grid point
68	!! just the thermodynamic processes are applied.
69	!!
70	!! ** Action : ncsi1(), ncsj1() : south-west closed sea limits (i,j)
71	!! ncsi2(), ncsj2() : north-east Closed sea limits (i,j)
72	!! ncsir(), ncsjr() : Location of runoff
73	!! ncsnr : number of point where run-off pours
74	!! ncstt : Type of closed sea
75	!! =0 spread over the world ocean
76	!! =2 put at location runoff
77	!!----------------------------------------------------------------------
78	INTEGER :: jc ! dummy loop indices
79	REAL(wp):: ztmp
80	!!----------------------------------------------------------------------
81
82	IF(lwp) WRITE(numout,*)
83	IF(lwp) WRITE(numout,*)'dom_clo : closed seas '
84	IF(lwp) WRITE(numout,*)'~~~~~~~'
85
86	! Initial values
87	ncsnr(:) = 1 ; ncsi1(:) = 1 ; ncsi2(:) = 1 ; ncsir(:,:) = 1
88	ncstt(:) = 0 ; ncsj1(:) = 1 ; ncsj2(:) = 1 ; ncsjr(:,:) = 1
89
90	! set the closed seas (in data domain indices)
91	! -------------------
92
93	IF( cp_cfg == "orca" ) THEN
94	!
95	SELECT CASE ( jp_cfg )
96	! ! =======================
97	CASE ( 1 ) ! ORCA_R1 configuration
98	! ! =======================
99	ncsnr(1) = 1 ; ncstt(1) = 0 ! Caspian Sea
100	ncsi1(1) = 332 ; ncsj1(1) = 203 ! spread over the globe
101	ncsi2(1) = 344 ; ncsj2(1) = 235
102	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
103	!
104	ncsnr(2) = 4 ; ncstt(2) = 2 ! Great North American Lakes
105	ncsi1(2) = 198 ; ncsj1(2) = 209 ! put at St Laurent mouth
106	ncsi2(2) = 213 ; ncsj2(2) = 223
107	ncsir(1,2) = 225 ; ncsjr(1,2) = 220
108	ncsir(1,2) = 225 ; ncsjr(1,2) = 221
109	ncsir(1,2) = 226 ; ncsjr(1,2) = 220
110	ncsir(1,2) = 226 ; ncsjr(1,2) = 221
111
112	!
113	! ! =======================
114	CASE ( 2 ) ! ORCA_R2 configuration
115	! ! =======================
116	! ! Caspian Sea
117	ncsnr(1) = 1 ; ncstt(1) = 0 ! spread over the globe
118	ncsi1(1) = 11 ; ncsj1(1) = 103
119	ncsi2(1) = 17 ; ncsj2(1) = 112
120	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
121	! ! Great North American Lakes
122	ncsnr(2) = 1 ; ncstt(2) = 2 ! put at St Laurent mouth
123	ncsi1(2) = 97 ; ncsj1(2) = 107
124	ncsi2(2) = 103 ; ncsj2(2) = 111
125	ncsir(2,1) = 110 ; ncsjr(2,1) = 111
126	! ! Black Sea (crossed by the cyclic boundary condition)
127	ncsnr(3:4) = 4 ; ncstt(3:4) = 2 ! put in Med Sea (north of Aegean Sea)
128	ncsir(3:4,1) = 171; ncsjr(3:4,1) = 106 !
129	ncsir(3:4,2) = 170; ncsjr(3:4,2) = 106
130	ncsir(3:4,3) = 171; ncsjr(3:4,3) = 105
131	ncsir(3:4,4) = 170; ncsjr(3:4,4) = 105
132	ncsi1(3) = 174 ; ncsj1(3) = 107 ! 1 : west part of the Black Sea
133	ncsi2(3) = 181 ; ncsj2(3) = 112 ! (ie west of the cyclic b.c.)
134	ncsi1(4) = 2 ; ncsj1(4) = 107 ! 2 : east part of the Black Sea
135	ncsi2(4) = 6 ; ncsj2(4) = 112 ! (ie east of the cyclic b.c.)
136
137
138
139	! ! =======================
140	CASE ( 4 ) ! ORCA_R4 configuration
141	! ! =======================
142	! ! Caspian Sea
143	ncsnr(1) = 1 ; ncstt(1) = 0
144	ncsi1(1) = 4 ; ncsj1(1) = 53
145	ncsi2(1) = 4 ; ncsj2(1) = 56
146	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
147	! ! Great North American Lakes
148	ncsnr(2) = 1 ; ncstt(2) = 2
149	ncsi1(2) = 49 ; ncsj1(2) = 55
150	ncsi2(2) = 51 ; ncsj2(2) = 56
151	ncsir(2,1) = 57 ; ncsjr(2,1) = 55
152	! ! Black Sea
153	ncsnr(3) = 4 ; ncstt(3) = 2
154	ncsi1(3) = 88 ; ncsj1(3) = 55
155	ncsi2(3) = 91 ; ncsj2(3) = 56
156	ncsir(3,1) = 86 ; ncsjr(3,1) = 53
157	ncsir(3,2) = 87 ; ncsjr(3,2) = 53
158	ncsir(3,3) = 86 ; ncsjr(3,3) = 52
159	ncsir(3,4) = 87 ; ncsjr(3,4) = 52
160	! ! Baltic Sea
161	ncsnr(4) = 1 ; ncstt(4) = 2
162	ncsi1(4) = 75 ; ncsj1(4) = 59
163	ncsi2(4) = 76 ; ncsj2(4) = 61
164	ncsir(4,1) = 84 ; ncsjr(4,1) = 59
165	! ! =======================
166	CASE ( 025 ) ! ORCA_R025 configuration
167	! ! =======================
168	ncsnr(1) = 1 ; ncstt(1) = 0 ! Caspian + Aral sea
169	ncsi1(1) = 1330 ; ncsj1(1) = 645
170	ncsi2(1) = 1400 ; ncsj2(1) = 795
171	ncsir(1,1) = 1 ; ncsjr(1,1) = 1
172	!
173	ncsnr(2) = 1 ; ncstt(2) = 0 ! Azov Sea
174	ncsi1(2) = 1284 ; ncsj1(2) = 722
175	ncsi2(2) = 1304 ; ncsj2(2) = 747
176	ncsir(2,1) = 1 ; ncsjr(2,1) = 1
177	!
178	END SELECT
179	!
180	ENDIF
181
182	! convert the position in local domain indices
183	! --------------------------------------------
184	DO jc = 1, jpncs
185	ncsi1(jc) = mi0( ncsi1(jc) )
186	ncsj1(jc) = mj0( ncsj1(jc) )
187
188	ncsi2(jc) = mi1( ncsi2(jc) )
189	ncsj2(jc) = mj1( ncsj2(jc) )
190	END DO
191
192	!
193	END SUBROUTINE dom_clo
194
195
196	SUBROUTINE sbc_clo( kt )
197	!!---------------------------------------------------------------------
198	!! * ROUTINE sbc_clo *
199	!!
200	!! ** Purpose : Special handling of closed seas
201	!!
202	!! ** Method : Water flux is forced to zero over closed sea
203	!! Excess is shared between remaining ocean, or
204	!! put as run-off in open ocean.
205	!!
206	!! ** Action : emp updated surface freshwater fluxes and associated heat content at kt
207	!!----------------------------------------------------------------------
208	INTEGER, INTENT(in) :: kt ! ocean model time step
209	!
210	INTEGER :: ji, jj, jc, jn ! dummy loop indices
211	REAL(wp), PARAMETER :: rsmall = 1.e-20_wp ! Closed sea correction epsilon
212	REAL(wp) :: zze2, ztmp, zcorr !
213	REAL(wp) :: zcoef, zcoef1 !
214	COMPLEX(wp) :: ctmp
215	REAL(wp), DIMENSION(jpncs) :: zfwf ! 1D workspace
216	!!----------------------------------------------------------------------
217	!
218	IF( nn_timing == 1 ) CALL timing_start('sbc_clo')
219	! !------------------!
220	IF( kt == nit000 ) THEN ! Initialisation !
221	! !------------------!
222	IF(lwp) WRITE(numout,*)
223	IF(lwp) WRITE(numout,*)'sbc_clo : closed seas '
224	IF(lwp) WRITE(numout,*)'~~~~~~~'
225	!
226	! Mask
227	! --------------------------------------------
228	ALLOCATE ( clo_mask (jpi, jpj), STAT=dia_closea_alloc)
229	IF(dia_closea_alloc /= 0) CALL ctl_warn('dia_closea_alloc: failed to allocate arrays.')
230
231	clo_mask (:,:) = tmask (:,:,1)
232
233	! Latitude limits
234	WHERE ( gphit (:,:) .GT. 30.0_wp ) clo_mask (:,:) = 0.0_wp
235	WHERE ( gphit (:,:) .LT. -30.0_wp ) clo_mask (:,:) = 0.0_wp
236	!
237	! Remove closed seas from mask
238	DO jc = 1, jpncs
239	DO jj = ncsj1(jc), ncsj2(jc)
240	DO ji = ncsi1(jc), ncsi2(jc)
241	clo_mask (ji, jj) = 0.0_wp
242	END DO
243	END DO
244	END DO
245
246	IF( lk_mpp ) CALL lbc_lnk ( clo_mask, 'T', 1._wp)
247
248	!
249	surf(:) = 0.e0_wp
250	!
251	surf(jpncs+1) = glob_sum( e1e2t(:,:) * clo_mask (:,:) ) ! surface of the ocean where excess run-off goes
252	!
253	! ! surface of closed seas
254	IF( lk_mpp_rep ) THEN ! MPP reproductible calculation
255	DO jc = 1, jpncs
256	ctmp = CMPLX( 0.e0, 0.e0, wp )
257	DO jj = ncsj1(jc), ncsj2(jc)
258	DO ji = ncsi1(jc), ncsi2(jc)
259	ztmp = e1e2t(ji,jj) * tmask_i(ji,jj)
260	CALL DDPDD( CMPLX( ztmp, 0.e0, wp ), ctmp )
261	END DO
262	END DO
263	IF( lk_mpp ) CALL mpp_sum( ctmp )
264	surf(jc) = REAL(ctmp,wp)
265	END DO
266	ELSE ! Standard calculation
267	DO jc = 1, jpncs
268	DO jj = ncsj1(jc), ncsj2(jc)
269	DO ji = ncsi1(jc), ncsi2(jc)
270	surf(jc) = surf(jc) + e1e2t(ji,jj) * tmask_i(ji,jj) ! surface of closed seas
271	END DO
272	END DO
273	END DO
274	IF( lk_mpp ) CALL mpp_sum ( surf, jpncs ) ! mpp: sum over all the global domain
275	ENDIF
276
277	IF(lwp) WRITE(numout,*)' Closed sea surfaces'
278	DO jc = 1, jpncs
279	IF(lwp)WRITE(numout,FMT='(1I3,4I4,5X,F16.2)') jc, ncsi1(jc), ncsi2(jc), ncsj1(jc), ncsj2(jc), surf(jc)
280	END DO
281
282	IF(lwp) WRITE(numout,*)' Surface for redistribution in closea ', surf(jpncs+1)
283
284	!
285	ENDIF
286	!
287	! !--------------------!
288	! ! update emp !
289	zfwf = 0.e0_wp !--------------------!
290	IF( lk_mpp_rep ) THEN ! MPP reproductible calculation
291	DO jc = 1, jpncs
292	ctmp = CMPLX( 0.e0, 0.e0, wp )
293	DO jj = ncsj1(jc), ncsj2(jc)
294	DO ji = ncsi1(jc), ncsi2(jc)
295	ztmp = e1e2t(ji,jj) * ( emp(ji,jj)-rnf(ji,jj) ) * tmask_i(ji,jj)
296	CALL DDPDD( CMPLX( ztmp, 0.e0, wp ), ctmp )
297	END DO
298	END DO
299	IF( lk_mpp ) CALL mpp_sum( ctmp )
300	zfwf(jc) = REAL(ctmp,wp)
301	END DO
302	ELSE ! Standard calculation
303	DO jc = 1, jpncs
304	DO jj = ncsj1(jc), ncsj2(jc)
305	DO ji = ncsi1(jc), ncsi2(jc)
306	zfwf(jc) = zfwf(jc) + e1e2t(ji,jj) * ( emp(ji,jj)-rnf(ji,jj) ) * tmask_i(ji,jj)
307	END DO
308	END DO
309	END DO
310	IF( lk_mpp ) CALL mpp_sum ( zfwf(:) , jpncs ) ! mpp: sum over all the global domain
311	ENDIF
312
313	IF( cp_cfg == "orca" .AND. jp_cfg == 2 ) THEN ! Black Sea case for ORCA_R2 configuration
314	zze2 = ( zfwf(3) + zfwf(4) ) * 0.5_wp
315	zfwf(3) = zze2
316	zfwf(4) = zze2
317	ENDIF
318
319	zcorr = 0._wp
320
321	DO jc = 1, jpncs
322	!
323	! The following if avoids the redistribution of the round off
324	IF ( ABS(zfwf(jc) / surf(jpncs+1) ) > rsmall) THEN
325	!
326	IF( ncstt(jc) == 0 ) THEN ! water/evap excess is shared by all open ocean
327	zcoef = zfwf(jc) / surf(jpncs+1)
328	zcoef1 = rcp * zcoef
329	emp(:,:) = emp(:,:) + zcoef * clo_mask (:,:)
330	qns(:,:) = qns(:,:) - zcoef1 * sst_m(:,:) * clo_mask (:,:)
331	!
332	ELSEIF( ncstt(jc) == 1 ) THEN ! Excess water in open sea, at outflow location, excess evap shared
333	IF ( zfwf(jc) <= 0.e0_wp ) THEN
334	DO jn = 1, ncsnr(jc)
335	ji = mi0(ncsir(jc,jn))
336	jj = mj0(ncsjr(jc,jn)) ! Location of outflow in open ocean
337	IF ( ji > 1 .AND. ji < jpi &
338	.AND. jj > 1 .AND. jj < jpj ) THEN
339	zcoef = zfwf(jc) / ( REAL(ncsnr(jc)) * e1e2t(ji,jj) )
340	zcoef1 = rcp * zcoef
341	emp(ji,jj) = emp(ji,jj) + zcoef
342	qns(ji,jj) = qns(ji,jj) - zcoef1 * sst_m(ji,jj)
343	ENDIF
344	END DO
345	ELSE
346	zcoef = zfwf(jc) / surf(jpncs+1)
347	zcoef1 = rcp * zcoef
348	emp(:,:) = emp(:,:) + zcoef * clo_mask (:,:)
349	qns(:,:) = qns(:,:) - zcoef1 * sst_m(:,:) * clo_mask (:,:)
350	ENDIF
351	ELSEIF( ncstt(jc) == 2 ) THEN ! Excess e-p-r (either sign) goes to open ocean, at outflow location
352	DO jn = 1, ncsnr(jc)
353	ji = mi0(ncsir(jc,jn))
354	jj = mj0(ncsjr(jc,jn)) ! Location of outflow in open ocean
355	IF( ji > 1 .AND. ji < jpi &
356	.AND. jj > 1 .AND. jj < jpj ) THEN
357	zcoef = zfwf(jc) / ( REAL(ncsnr(jc)) * e1e2t(ji,jj) )
358	zcoef1 = rcp * zcoef
359	emp(ji,jj) = emp(ji,jj) + zcoef
360	qns(ji,jj) = qns(ji,jj) - zcoef1 * sst_m(ji,jj)
361	ENDIF
362	END DO
363	ENDIF
364	!
365	DO jj = ncsj1(jc), ncsj2(jc)
366	DO ji = ncsi1(jc), ncsi2(jc)
367	zcoef = zfwf(jc) / surf(jc)
368	zcoef1 = rcp * zcoef
369	emp(ji,jj) = emp(ji,jj) - zcoef
370	qns(ji,jj) = qns(ji,jj) + zcoef1 * sst_m(ji,jj)
371	END DO
372	END DO
373	!
374	END IF
375	END DO
376
377	emp (:,:) = emp (:,:) * tmask(:,:,1)
378	qns (:,:) = qns (:,:) * tmask(:,:,1)
379	!
380	CALL lbc_lnk( emp , 'T', 1._wp )
381	CALL lbc_lnk( qns , 'T', 1._wp )
382	!
383	IF( nn_timing == 1 ) CALL timing_stop('sbc_clo')
384	!
385	END SUBROUTINE sbc_clo
386
387
388	SUBROUTINE clo_rnf( p_rnfmsk )
389	!!---------------------------------------------------------------------
390	!! * ROUTINE sbc_rnf *
391	!!
392	!! ** Purpose : allow the treatment of closed sea outflow grid-points
393	!! to be the same as river mouth grid-points
394	!!
395	!! ** Method : set to 1 the runoff mask (mskrnf, see sbcrnf module)
396	!! at the closed sea outflow grid-point.
397	!!
398	!! ** Action : update (p_)mskrnf (set 1 at closed sea outflow)
399	!!----------------------------------------------------------------------
400	REAL(wp), DIMENSION(jpi,jpj), INTENT(inout) :: p_rnfmsk ! river runoff mask (rnfmsk array)
401	!
402	INTEGER :: jc, jn, ji, jj ! dummy loop indices
403	!!----------------------------------------------------------------------
404	!
405	DO jc = 1, jpncs
406	IF( ncstt(jc) >= 1 ) THEN ! runoff mask set to 1 at closed sea outflows
407	DO jn = 1, 4
408	DO jj = mj0( ncsjr(jc,jn) ), mj1( ncsjr(jc,jn) )
409	DO ji = mi0( ncsir(jc,jn) ), mi1( ncsir(jc,jn) )
410	p_rnfmsk(ji,jj) = MAX( p_rnfmsk(ji,jj), 1.0_wp )
411	END DO
412	END DO
413	END DO
414	ENDIF
415	END DO
416	!
417	END SUBROUTINE clo_rnf
418
419
420	SUBROUTINE clo_ups( p_upsmsk )
421	!!---------------------------------------------------------------------
422	!! * ROUTINE sbc_rnf *
423	!!
424	!! ** Purpose : allow the treatment of closed sea outflow grid-points
425	!! to be the same as river mouth grid-points
426	!!
427	!! ** Method : set to 0.5 the upstream mask (upsmsk, see traadv_cen2
428	!! module) over the closed seas.
429	!!
430	!! ** Action : update (p_)upsmsk (set 0.5 over closed seas)
431	!!----------------------------------------------------------------------
432	REAL(wp), DIMENSION(jpi,jpj), INTENT(inout) :: p_upsmsk ! upstream mask (upsmsk array)
433	!
434	INTEGER :: jc, ji, jj ! dummy loop indices
435	!!----------------------------------------------------------------------
436	!
437	DO jc = 1, jpncs
438	DO jj = ncsj1(jc), ncsj2(jc)
439	DO ji = ncsi1(jc), ncsi2(jc)
440	p_upsmsk(ji,jj) = 0.5_wp ! mixed upstream/centered scheme over closed seas
441	END DO
442	END DO
443	END DO
444	!
445	END SUBROUTINE clo_ups
446
447
448	SUBROUTINE clo_bat( pbat, kbat )
449	!!---------------------------------------------------------------------
450	!! * ROUTINE clo_bat *
451	!!
452	!! ** Purpose : suppress closed sea from the domain
453	!!
454	!! ** Method : set to 0 the meter and level bathymetry (given in
455	!! arguments) over the closed seas.
456	!!
457	!! ** Action : set pbat=0 and kbat=0 over closed seas
458	!!----------------------------------------------------------------------
459	REAL(wp), DIMENSION(jpi,jpj), INTENT(inout) :: pbat ! bathymetry in meters (bathy array)
460	INTEGER , DIMENSION(jpi,jpj), INTENT(inout) :: kbat ! bathymetry in levels (mbathy array)
461	!
462	INTEGER :: jc, ji, jj ! dummy loop indices
463	!!----------------------------------------------------------------------
464	!
465	DO jc = 1, jpncs
466	DO jj = ncsj1(jc), ncsj2(jc)
467	DO ji = ncsi1(jc), ncsi2(jc)
468	pbat(ji,jj) = 0._wp
469	kbat(ji,jj) = 0
470	END DO
471	END DO
472	END DO
473	!
474	END SUBROUTINE clo_bat
475
476	!!======================================================================
477	END MODULE closea
478

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