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sbcisf.F90 in branches/2014/dev_r4879_UKMO_NOC_MERGE/NEMOGCM/NEMO/OPA_SRC/SBC – NEMO

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source: branches/2014/dev_r4879_UKMO_NOC_MERGE/NEMOGCM/NEMO/OPA_SRC/SBC/sbcisf.F90 @ 4945

Last change on this file since 4945 was 4945, checked in by acc, 9 years ago
Branch dev_r4879_UKMO_NOC_MERGE. Final commits to ensure successful AGRIF SETTE tests
File size: 44.5 KB

Line
1	MODULE sbcisf
2	!!======================================================================
3	!! * MODULE sbcisf *
4	!! Surface module : update surface ocean boundary condition under ice
5	!! shelf
6	!!======================================================================
7	!! History : 3.2 ! 2011-02 (C.Harris ) Original code isf cav
8	!! X.X ! 2006-02 (C. Wang ) Original code bg03
9	!! 3.4 ! 2013-03 (P. Mathiot) Merging
10	!!----------------------------------------------------------------------
11
12	!!----------------------------------------------------------------------
13	!! sbc_isf : update sbc under ice shelf
14	!!----------------------------------------------------------------------
15	USE oce ! ocean dynamics and tracers
16	USE dom_oce ! ocean space and time domain
17	USE phycst ! physical constants
18	USE eosbn2 ! equation of state
19	USE sbc_oce ! surface boundary condition: ocean fields
20	USE lbclnk !
21	USE iom ! I/O manager library
22	USE in_out_manager ! I/O manager
23	USE wrk_nemo ! Memory allocation
24	USE timing ! Timing
25	USE lib_fortran ! glob_sum
26	USE zdfbfr
27	USE fldread ! read input field at current time step
28
29
30
31	IMPLICIT NONE
32	PRIVATE
33
34	PUBLIC sbc_isf, sbc_isf_div, sbc_isf_alloc ! routine called in sbcmod and divcur
35
36	! public in order to be able to output then
37
38	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: risf_tsc_b, risf_tsc
39	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: fwfisf_b, fwfisf !: evaporation damping [kg/m2/s]
40	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: qisf !: net heat flux from ice shelf
41	REAL(wp), PUBLIC :: rn_hisf_tbl !: thickness of top boundary layer [m]
42	LOGICAL , PUBLIC :: ln_divisf !: flag to correct divergence
43	INTEGER , PUBLIC :: nn_isfblk !:
44	INTEGER , PUBLIC :: nn_gammablk !:
45	LOGICAL , PUBLIC :: ln_conserve !:
46	REAL(wp), PUBLIC :: rn_gammat0 !: temperature exchange coeficient
47	REAL(wp), PUBLIC :: rn_gammas0 !: salinity exchange coeficient
48	REAL(wp), PUBLIC :: rdivisf !: flag to test if fwf apply on divergence
49
50	REAL(wp) , PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: rzisf_tbl !:depth of calving front (shallowest point) nn_isf ==2/3
51	REAL(wp) , PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: rhisf_tbl, rhisf_tbl_0 !:thickness of tbl
52	REAL(wp) , PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: r1_hisf_tbl !:1/thickness of tbl
53	REAL(wp) , PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: ralpha !:proportion of bottom cell influenced by tbl
54	REAL(wp) , PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: risfLeff !:effective length (Leff) BG03 nn_isf==2
55	REAL(wp) , PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: ttbl, stbl, utbl, vtbl !:top boundary layer variable at T point
56	#ifdef key_agrif
57	! AGRIF can not handle these arrays as integers. The reason is a mystery but problems avoided by declaring them as reals
58	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: misfkt, misfkb !:Level of ice shelf base
59	!: (first wet level and last level include in the tbl)
60	#else
61	INTEGER, PUBLIC, ALLOCATABLE, SAVE, DIMENSION (:,:) :: misfkt, misfkb !:Level of ice shelf base
62	#endif
63	!: (first wet level and last level include in the tbl)
64
65	REAL(wp), PUBLIC, SAVE :: rcpi = 2000.0_wp ! phycst ?
66	REAL(wp), PUBLIC, SAVE :: kappa = 1.54e-6_wp ! phycst ?
67	REAL(wp), PUBLIC, SAVE :: rhoisf = 920.0_wp ! phycst ?
68	REAL(wp), PUBLIC, SAVE :: tsurf = -20.0_wp ! phycst ?
69	REAL(wp), PUBLIC, SAVE :: lfusisf= 0.334e6_wp ! phycst ?
70
71	!: Variable used in fldread to read the forcing file (nn_isf == 4 .OR. nn_isf == 3)
72	CHARACTER(len=100), PUBLIC :: cn_dirisf = './' !: Root directory for location of ssr files
73	TYPE(FLD_N) , PUBLIC :: sn_qisf, sn_fwfisf !: information about the runoff file to be read
74	TYPE(FLD), ALLOCATABLE, DIMENSION(:) :: sf_qisf, sf_fwfisf
75	TYPE(FLD_N) , PUBLIC :: sn_rnfisf !: information about the runoff file to be read
76	TYPE(FLD), ALLOCATABLE, DIMENSION(:) :: sf_rnfisf
77	TYPE(FLD_N) , PUBLIC :: sn_depmax_isf, sn_depmin_isf, sn_Leff_isf !: information about the runoff file to be read
78
79	!! * Substitutions
80	# include "domzgr_substitute.h90"
81	!!----------------------------------------------------------------------
82	!! NEMO/OPA 3.0 , LOCEAN-IPSL (2008)
83	!! $Id: sbcice_if.F90 1730 2009-11-16 14:34:19Z smasson $
84	!! Software governed by the CeCILL licence (modipsl/doc/NEMO_CeCILL.txt)
85	!!----------------------------------------------------------------------
86
87	CONTAINS
88
89	SUBROUTINE sbc_isf(kt)
90	INTEGER, INTENT(in) :: kt ! ocean time step
91	INTEGER :: ji, jj, jk, ijkmin, inum, ierror
92	INTEGER :: ikt, ikb ! top and bottom level of the isf boundary layer
93	REAL(wp) :: rmin
94	REAL(wp) :: zhk
95	CHARACTER(len=256) :: cfisf, cvarzisf, cvarhisf ! name for isf file
96	CHARACTER(LEN=256) :: cnameis ! name of iceshelf file
97	CHARACTER (LEN=32) :: cvarLeff ! variable name for efficient Length scale
98	INTEGER :: ios ! Local integer output status for namelist read
99	!
100	!!---------------------------------------------------------------------
101	NAMELIST/namsbc_isf/ nn_isfblk, rn_hisf_tbl, ln_divisf, ln_conserve, rn_gammat0, rn_gammas0, nn_gammablk, &
102	& sn_fwfisf, sn_qisf, sn_rnfisf, sn_depmax_isf, sn_depmin_isf, sn_Leff_isf
103	!
104	!
105	! ! ====================== !
106	IF( kt == nit000 ) THEN ! First call kt=nit000 !
107	! ! ====================== !
108	REWIND( numnam_ref ) ! Namelist namsbc_rnf in reference namelist : Runoffs
109	READ ( numnam_ref, namsbc_isf, IOSTAT = ios, ERR = 901)
110	901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namsbc_isf in reference namelist', lwp )
111
112	REWIND( numnam_cfg ) ! Namelist namsbc_rnf in configuration namelist : Runoffs
113	READ ( numnam_cfg, namsbc_isf, IOSTAT = ios, ERR = 902 )
114	902 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namsbc_isf in configuration namelist', lwp )
115	IF(lwm) WRITE ( numond, namsbc_isf )
116
117
118	IF ( lwp ) WRITE(numout,*)
119	IF ( lwp ) WRITE(numout,*) 'sbc_isf: heat flux of the ice shelf'
120	IF ( lwp ) WRITE(numout,*) '~~~~~~~~~'
121	IF ( lwp ) WRITE(numout,*) 'sbcisf :'
122	IF ( lwp ) WRITE(numout,*) '~~~~~~~~'
123	IF ( lwp ) WRITE(numout,*) ' nn_isf = ', nn_isf
124	IF ( lwp ) WRITE(numout,*) ' nn_isfblk = ', nn_isfblk
125	IF ( lwp ) WRITE(numout,*) ' rn_hisf_tbl = ', rn_hisf_tbl
126	IF ( lwp ) WRITE(numout,*) ' ln_divisf = ', ln_divisf
127	IF ( lwp ) WRITE(numout,*) ' nn_gammablk = ', nn_gammablk
128	IF ( lwp ) WRITE(numout,*) ' rn_tfri2 = ', rn_tfri2
129	IF (ln_divisf) THEN ! keep it in the namelist ??? used true anyway as for runoff ? (PM)
130	rdivisf = 1._wp
131	ELSE
132	rdivisf = 0._wp
133	END IF
134	!
135	! Allocate public variable
136	IF ( sbc_isf_alloc() /= 0 ) CALL ctl_stop( 'STOP', 'sbc_isf : unable to allocate arrays' )
137	!
138	! initialisation
139	qisf(:,:) = 0._wp ; fwfisf(:,:) = 0._wp
140	risf_tsc(:,:,:) = 0._wp
141	!
142	! define isf tbl tickness, top and bottom indice
143	IF (nn_isf == 1) THEN
144	rhisf_tbl(:,:) = rn_hisf_tbl
145	misfkt(:,:) = mikt(:,:) ! same indice for bg03 et cav => used in isfdiv
146	ELSE IF ((nn_isf == 3) .OR. (nn_isf == 2)) THEN
147	ALLOCATE( sf_rnfisf(1), STAT=ierror )
148	ALLOCATE( sf_rnfisf(1)%fnow(jpi,jpj,1), sf_rnfisf(1)%fdta(jpi,jpj,1,2) )
149	CALL fld_fill( sf_rnfisf, (/ sn_rnfisf /), cn_dirisf, 'sbc_isf_init', 'read fresh water flux isf data', 'namsbc_isf' )
150
151	!: read effective lenght (BG03)
152	IF (nn_isf == 2) THEN
153	! Read Data and save some integral values
154	CALL iom_open( sn_Leff_isf%clname, inum )
155	cvarLeff = 'soLeff' !: variable name for Efficient Length scale
156	CALL iom_get( inum, jpdom_data, cvarLeff, risfLeff , 1)
157	CALL iom_close(inum)
158	!
159	risfLeff = risfLeff*1000 !: convertion in m
160	END IF
161
162	! read depth of the top and bottom of the isf top boundary layer (in this case, isf front depth and grounding line depth)
163	CALL iom_open( sn_depmax_isf%clname, inum )
164	cvarhisf = TRIM(sn_depmax_isf%clvar)
165	CALL iom_get( inum, jpdom_data, cvarhisf, rhisf_tbl, 1) !: depth of deepest point of the ice shelf base
166	CALL iom_close(inum)
167	!
168	CALL iom_open( sn_depmin_isf%clname, inum )
169	cvarzisf = TRIM(sn_depmin_isf%clvar)
170	CALL iom_get( inum, jpdom_data, cvarzisf, rzisf_tbl, 1) !: depth of shallowest point of the ice shelves base
171	CALL iom_close(inum)
172	!
173	rhisf_tbl(:,:) = rhisf_tbl(:,:) - rzisf_tbl(:,:) !: tickness isf boundary layer
174
175	!! compute first level of the top boundary layer
176	DO ji = 1, jpi
177	DO jj = 1, jpj
178	jk = 2
179	DO WHILE ( jk .LE. mbkt(ji,jj) .AND. fsdepw(ji,jj,jk) < rzisf_tbl(ji,jj) ) ; jk = jk + 1 ; END DO
180	misfkt(ji,jj) = jk-1
181	END DO
182	END DO
183
184	ELSE IF ( nn_isf == 4 ) THEN
185	! as in nn_isf == 1
186	rhisf_tbl(:,:) = rn_hisf_tbl
187	misfkt(:,:) = mikt(:,:) ! same indice for bg03 et cav => used in isfdiv
188
189	! load variable used in fldread (use for temporal interpolation of isf fwf forcing)
190	ALLOCATE( sf_fwfisf(1), sf_qisf(1), STAT=ierror )
191	ALLOCATE( sf_fwfisf(1)%fnow(jpi,jpj,1), sf_fwfisf(1)%fdta(jpi,jpj,1,2) )
192	ALLOCATE( sf_qisf(1)%fnow(jpi,jpj,1), sf_qisf(1)%fdta(jpi,jpj,1,2) )
193	CALL fld_fill( sf_fwfisf, (/ sn_fwfisf /), cn_dirisf, 'sbc_isf_init', 'read fresh water flux isf data', 'namsbc_isf' )
194	!CALL fld_fill( sf_qisf , (/ sn_qisf /), cn_dirisf, 'sbc_isf_init', 'read heat flux isf data' , 'namsbc_isf' )
195	END IF
196
197	rhisf_tbl_0(:,:) = rhisf_tbl(:,:)
198
199	! compute bottom level of isf tbl and thickness of tbl below the ice shelf
200	DO jj = 1,jpj
201	DO ji = 1,jpi
202	ikt = misfkt(ji,jj)
203	ikb = misfkt(ji,jj)
204	! thickness of boundary layer at least the top level thickness
205	rhisf_tbl(ji,jj) = MAX(rhisf_tbl_0(ji,jj), fse3t_n(ji,jj,ikt))
206
207	! determine the deepest level influenced by the boundary layer
208	! test on tmask useless ?????
209	DO jk = ikt, mbkt(ji,jj)
210	IF ( (SUM(fse3t_n(ji,jj,ikt:jk-1)) .LT. rhisf_tbl(ji,jj)) .AND. (tmask(ji,jj,jk) == 1) ) ikb = jk
211	END DO
212	rhisf_tbl(ji,jj) = MIN(rhisf_tbl(ji,jj), SUM(fse3t_n(ji,jj,ikt:ikb))) ! limit the tbl to water thickness.
213	misfkb(ji,jj) = ikb ! last wet level of the tbl
214	r1_hisf_tbl(ji,jj) = 1._wp / rhisf_tbl(ji,jj)
215
216	zhk = SUM( fse3t(ji, jj, ikt:ikb - 1)) * r1_hisf_tbl(ji,jj) ! proportion of tbl cover by cell from ikt to ikb - 1
217	ralpha(ji,jj) = rhisf_tbl(ji,jj) * (1._wp - zhk ) / fse3t(ji,jj,ikb) ! proportion of bottom cell influenced by boundary layer
218	END DO
219	END DO
220
221	END IF
222
223	! ! ---------------------------------------- !
224	IF( kt /= nit000 ) THEN ! Swap of forcing fields !
225	! ! ---------------------------------------- !
226	fwfisf_b (:,: ) = fwfisf (:,: ) ! Swap the ocean forcing fields except at nit000
227	risf_tsc_b(:,:,:) = risf_tsc(:,:,:) ! where before fields are set at the end of the routine
228	!
229	ENDIF
230
231	IF( MOD( kt-1, nn_fsbc) == 0 ) THEN
232
233
234	! compute salf and heat flux
235	IF (nn_isf == 1) THEN
236	! realistic ice shelf formulation
237	! compute T/S/U/V for the top boundary layer
238	CALL sbc_isf_tbl(tsn(:,:,:,jp_tem),ttbl(:,:),'T')
239	CALL sbc_isf_tbl(tsn(:,:,:,jp_sal),stbl(:,:),'T')
240	CALL sbc_isf_tbl(un(:,:,:),utbl(:,:),'U')
241	CALL sbc_isf_tbl(vn(:,:,:),vtbl(:,:),'V')
242	! iom print
243	CALL iom_put('ttbl',ttbl(:,:))
244	CALL iom_put('stbl',stbl(:,:))
245	CALL iom_put('utbl',utbl(:,:))
246	CALL iom_put('vtbl',vtbl(:,:))
247	! compute fwf and heat flux
248	CALL sbc_isf_cav (kt)
249
250	ELSE IF (nn_isf == 2) THEN
251	! Beckmann and Goosse parametrisation
252	stbl(:,:) = soce
253	CALL sbc_isf_bg03(kt)
254
255	ELSE IF (nn_isf == 3) THEN
256	! specified runoff in depth (Mathiot et al., XXXX in preparation)
257	CALL fld_read ( kt, nn_fsbc, sf_rnfisf )
258	fwfisf(:,:) = - sf_rnfisf(1)%fnow(:,:,1) ! fresh water flux from the isf (fwfisf <0 mean melting)
259	qisf(:,:) = fwfisf(:,:) * lfusisf ! heat flux
260	stbl(:,:) = soce
261
262	ELSE IF (nn_isf == 4) THEN
263	! specified fwf and heat flux forcing beneath the ice shelf
264	CALL fld_read ( kt, nn_fsbc, sf_fwfisf )
265	!CALL fld_read ( kt, nn_fsbc, sf_qisf )
266	fwfisf(:,:) = sf_fwfisf(1)%fnow(:,:,1) ! fwf
267	qisf(:,:) = fwfisf(:,:) * lfusisf ! heat flux
268	!qisf(:,:) = sf_qisf(1)%fnow(:,:,1) ! heat flux
269	stbl(:,:) = soce
270
271	END IF
272	! compute tsc due to isf
273	! WARNING water add at temp = 0C, correction term is added in trasbc, maybe better here but need a 3D variable).
274	risf_tsc(:,:,jp_tem) = qisf(:,:) * r1_rau0_rcp !
275
276	! salt effect already take into account in vertical advection
277	risf_tsc(:,:,jp_sal) = (1.0_wp-rdivisf) * fwfisf(:,:) * stbl(:,:) * r1_rau0
278
279	! lbclnk
280	CALL lbc_lnk(risf_tsc(:,:,jp_tem),'T',1.)
281	CALL lbc_lnk(risf_tsc(:,:,jp_sal),'T',1.)
282	CALL lbc_lnk(fwfisf(:,:) ,'T',1.)
283	CALL lbc_lnk(qisf(:,:) ,'T',1.)
284
285	IF( kt == nit000 ) THEN ! set the forcing field at nit000 - 1 !
286	IF( ln_rstart .AND. & ! Restart: read in restart file
287	& iom_varid( numror, 'fwf_isf_b', ldstop = .FALSE. ) > 0 ) THEN
288	IF(lwp) WRITE(numout,*) ' nit000-1 isf tracer content forcing fields read in the restart file'
289	CALL iom_get( numror, jpdom_autoglo, 'fwf_isf_b', fwfisf_b(:,:) ) ! before salt content isf_tsc trend
290	CALL iom_get( numror, jpdom_autoglo, 'isf_sc_b', risf_tsc_b(:,:,jp_sal) ) ! before salt content isf_tsc trend
291	CALL iom_get( numror, jpdom_autoglo, 'isf_hc_b', risf_tsc_b(:,:,jp_tem) ) ! before salt content isf_tsc trend
292	ELSE
293	fwfisf_b(:,:) = fwfisf(:,:)
294	risf_tsc_b(:,:,:)= risf_tsc(:,:,:)
295	END IF
296	ENDIF
297	!
298	! output
299	CALL iom_put('qisf' , qisf)
300	CALL iom_put('fwfisf', fwfisf * stbl(:,:) / soce )
301	END IF
302
303	END SUBROUTINE sbc_isf
304
305	INTEGER FUNCTION sbc_isf_alloc()
306	!!----------------------------------------------------------------------
307	!! * FUNCTION sbc_isf_rnf_alloc *
308	!!----------------------------------------------------------------------
309	sbc_isf_alloc = 0 ! set to zero if no array to be allocated
310	IF( .NOT. ALLOCATED( qisf ) ) THEN
311	ALLOCATE( risf_tsc(jpi,jpj,jpts), risf_tsc_b(jpi,jpj,jpts) , &
312	& qisf(jpi,jpj) , fwfisf(jpi,jpj) , fwfisf_b(jpi,jpj) , &
313	& rhisf_tbl(jpi,jpj), r1_hisf_tbl(jpi,jpj), rzisf_tbl(jpi,jpj) , &
314	& ttbl(jpi,jpj) , stbl(jpi,jpj) , utbl(jpi,jpj) , &
315	& vtbl(jpi, jpj) , risfLeff(jpi,jpj) , rhisf_tbl_0(jpi,jpj), &
316	& ralpha(jpi,jpj) , misfkt(jpi,jpj) , misfkb(jpi,jpj) , &
317	& STAT= sbc_isf_alloc )
318	!
319	IF( lk_mpp ) CALL mpp_sum ( sbc_isf_alloc )
320	IF( sbc_isf_alloc /= 0 ) CALL ctl_warn('sbc_isf_alloc: failed to allocate arrays.')
321	!
322	ENDIF
323	END FUNCTION
324
325	SUBROUTINE sbc_isf_bg03(kt)
326	!!==========================================================================
327	!! * SUBROUTINE sbcisf_bg03 *
328	!! add net heat and fresh water flux from ice shelf melting
329	!! into the adjacent ocean using the parameterisation by
330	!! Beckmann and Goosse (2003), "A parameterization of ice shelf-ocean
331	!! interaction for climate models", Ocean Modelling 5(2003) 157-170.
332	!! (hereafter BG)
333	!!==========================================================================
334	!!----------------------------------------------------------------------
335	!! sbc_isf_bg03 : routine called from sbcmod
336	!!----------------------------------------------------------------------
337	!!
338	!! ** Purpose : Add heat and fresh water fluxes due to ice shelf melting
339	!! ** Reference : Beckmann et Goosse, 2003, Ocean Modelling
340	!!
341	!! History :
342	!! ! 06-02 (C. Wang) Original code
343	!!----------------------------------------------------------------------
344
345	INTEGER, INTENT ( in ) :: kt
346
347	INTEGER :: ji, jj, jk, jish !temporary integer
348	INTEGER :: ijkmin
349	INTEGER :: ii, ij, ik
350	INTEGER :: inum
351
352	REAL(wp) :: zt_sum ! sum of the temperature between 200m and 600m
353	REAL(wp) :: zt_ave ! averaged temperature between 200m and 600m
354	REAL(wp) :: zt_frz ! freezing point temperature at depth z
355	REAL(wp) :: zpress ! pressure to compute the freezing point in depth
356
357	!!----------------------------------------------------------------------
358	IF ( nn_timing == 1 ) CALL timing_start('sbc_isf_bg03')
359	!
360
361	! This test is false only in the very first time step of a run (JMM ???- Initialy build to skip 1rst year of run )
362	DO ji = 1, jpi
363	DO jj = 1, jpj
364	ik = misfkt(ji,jj)
365	!! Initialize arrays to 0 (each step)
366	zt_sum = 0.e0_wp
367	IF ( ik .GT. 1 ) THEN
368	! 3. -----------the average temperature between 200m and 600m ---------------------
369	DO jk = misfkt(ji,jj),misfkb(ji,jj)
370	! freezing point temperature at ice shelf base BG eq. 2 (JMM sign pb ??? +7.64e-4 !!!)
371	! after verif with UNESCO, wrong sign in BG eq. 2
372	! Calculate freezing temperature
373	zpress = gravrau0fsdept(ji,jj,ik)*1.e-04
374	zt_frz = tfreez1D(tsb(ji,jj,ik,jp_sal), zpress)
375	zt_sum = zt_sum + (tsn(ji,jj,ik,jp_tem)-zt_frz) * fse3t(ji,jj,ik) * tmask(ji,jj,ik) ! sum temp
376	ENDDO
377	zt_ave = zt_sum/rhisf_tbl(ji,jj) ! calcul mean value
378
379	! 4. ------------Net heat flux and fresh water flux due to the ice shelf
380	! For those corresponding to zonal boundary
381	qisf(ji,jj) = - rau0 * rcp * rn_gammat0 * risfLeff(ji,jj) * e1t(ji,jj) * zt_ave &
382	& / (e1t(ji,jj) * e2t(ji,jj)) * tmask(ji,jj,ik)
383
384	fwfisf(ji,jj) = qisf(ji,jj) / lfusisf !fresh water flux kg/(m2s)
385	fwfisf(ji,jj) = fwfisf(ji,jj) * ( soce / stbl(ji,jj) )
386	!add to salinity trend
387	ELSE
388	qisf(ji,jj) = 0._wp ; fwfisf(ji,jj) = 0._wp
389	END IF
390	ENDDO
391	ENDDO
392	!
393	IF( nn_timing == 1 ) CALL timing_stop('sbc_isf_bg03')
394	END SUBROUTINE sbc_isf_bg03
395
396	SUBROUTINE sbc_isf_cav( kt )
397	!!---------------------------------------------------------------------
398	!! * ROUTINE sbc_isf_cav *
399	!!
400	!! ** Purpose : handle surface boundary condition under ice shelf
401	!!
402	!! ** Method : -
403	!!
404	!! ** Action : utau, vtau : remain unchanged
405	!! taum, wndm : remain unchanged
406	!! qns : update heat flux below ice shelf
407	!! emp, emps : update freshwater flux below ice shelf
408	!!---------------------------------------------------------------------
409	INTEGER, INTENT(in) :: kt ! ocean time step
410	!
411	LOGICAL :: ln_isomip = .true.
412	REAL(wp), DIMENSION(:,:), POINTER :: zfrz,zpress,zti
413	REAL(wp), DIMENSION(:,:), POINTER :: zgammat2d, zgammas2d
414	!REAL(wp), DIMENSION(:,:), POINTER :: zqisf, zfwfisf
415	REAL(wp) :: zlamb1, zlamb2, zlamb3
416	REAL(wp) :: zeps1,zeps2,zeps3,zeps4,zeps6,zeps7
417	REAL(wp) :: zaqe,zbqe,zcqe,zaqer,zdis,zsfrz,zcfac
418	REAL(wp) :: zfwflx, zhtflx, zhtflx_b
419	REAL(wp) :: zgammat, zgammas
420	REAL(wp) :: zeps = -1.e-20_wp !== Local constant initialization ==!
421	INTEGER :: ji, jj ! dummy loop indices
422	INTEGER :: ii0, ii1, ij0, ij1 ! temporary integers
423	INTEGER :: ierror ! return error code
424	LOGICAL :: lit=.TRUE.
425	INTEGER :: nit
426	!!---------------------------------------------------------------------
427	!
428	! coeficient for linearisation of tfreez
429	zlamb1=-0.0575
430	zlamb2=0.0901
431	zlamb3=-7.61e-04
432	IF( nn_timing == 1 ) CALL timing_start('sbc_isf_cav')
433	!
434	CALL wrk_alloc( jpi,jpj, zfrz,zpress,zti, zgammat2d, zgammas2d )
435
436	zcfac=0.0_wp
437	IF (ln_conserve) zcfac=1.0_wp
438	zpress(:,:)=0.0_wp
439	zgammat2d(:,:)=0.0_wp
440	zgammas2d(:,:)=0.0_wp
441	!
442	!
443	!CDIR COLLAPSE
444	DO jj = 1, jpj
445	DO ji = 1, jpi
446	! Crude approximation for pressure (but commonly used)
447	! 1e-04 to convert from Pa to dBar
448	zpress(ji,jj)=gravrau0fsdepw(ji,jj,mikt(ji,jj))*1.e-04
449	!
450	END DO
451	END DO
452
453	! Calculate in-situ temperature (ref to surface)
454	zti(:,:)=tinsitu( ttbl, stbl, zpress )
455	! Calculate freezing temperature
456	zfrz(:,:)=tfreez( sss_m(:,:), zpress )
457
458
459	zhtflx=0._wp ; zfwflx=0._wp
460	IF (nn_isfblk == 1) THEN
461	DO jj = 1, jpj
462	DO ji = 1, jpi
463	IF (mikt(ji,jj) > 1 ) THEN
464	nit = 1; lit = .TRUE.; zgammat=rn_gammat0; zgammas=rn_gammas0; zhtflx_b=0._wp
465	DO WHILE ( lit )
466	! compute gamma
467	CALL sbc_isf_gammats(zgammat, zgammas, zhtflx, zfwflx, ji, jj, lit)
468	! zhtflx is upward heat flux (out of ocean)
469	zhtflx = zgammatrcprau0*(zti(ji,jj)-zfrz(ji,jj))
470	! zwflx is upward water flux
471	zfwflx = - zhtflx/lfusisf
472	! test convergence and compute gammat
473	IF ( (zhtflx - zhtflx_b) .LE. 0.01 ) lit = .FALSE.
474
475	nit = nit + 1
476	IF (nit .GE. 100) THEN
477	!WRITE(numout,*) "sbcisf : too many iteration ... ", zhtflx, zhtflx_b,zgammat, rn_gammat0, rn_tfri2, nn_gammablk, ji,jj
478	!WRITE(numout,*) "sbcisf : too many iteration ... ", (zhtflx - zhtflx_b)/zhtflx
479	CALL ctl_stop( 'STOP', 'sbc_isf_hol99 : too many iteration ...' )
480	END IF
481	! save gammat and compute zhtflx_b
482	zgammat2d(ji,jj)=zgammat
483	zhtflx_b = zhtflx
484	END DO
485
486	qisf(ji,jj) = - zhtflx
487	! For genuine ISOMIP protocol this should probably be something like
488	fwfisf(ji,jj) = zfwflx * ( soce / MAX(stbl(ji,jj),zeps))
489	ELSE
490	fwfisf(ji,jj) = 0._wp
491	qisf(ji,jj) = 0._wp
492	END IF
493	!
494	END DO
495	END DO
496
497	ELSE IF (nn_isfblk == 2 ) THEN
498
499	! More complicated 3 equation thermodynamics as in MITgcm
500	!CDIR COLLAPSE
501	DO jj = 2, jpj
502	DO ji = 2, jpi
503	IF (mikt(ji,jj) > 1 ) THEN
504	nit=1; lit=.TRUE.; zgammat=rn_gammat0; zgammas=rn_gammas0; zhtflx_b=0._wp; zhtflx=0._wp
505	DO WHILE ( lit )
506	CALL sbc_isf_gammats(zgammat, zgammas, zhtflx, zfwflx, ji, jj, lit)
507
508	zeps1=rcprau0zgammat
509	zeps2=lfusisfrau0zgammas
510	zeps3=rhoisfrcpikappa/risfdep(ji,jj)
511	zeps4=zlamb2+zlamb3*risfdep(ji,jj)
512	zeps6=zeps4-zti(ji,jj)
513	zeps7=zeps4-tsurf
514	zaqe=zlamb1 * (zeps1 + zeps3)
515	zaqer=0.5/zaqe
516	zbqe=zeps1zeps6+zeps3zeps7-zeps2
517	zcqe=zeps2*stbl(ji,jj)
518	zdis=zbqezbqe-4.0zaqe*zcqe
519	! Presumably zdis can never be negative because gammas is very small compared to gammat
520	zsfrz=(-zbqe-SQRT(zdis))*zaqer
521	IF (zsfrz .lt. 0.0) zsfrz=(-zbqe+SQRT(zdis))*zaqer
522	zfrz(ji,jj)=zeps4+zlamb1*zsfrz
523
524	! zfwflx is upward water flux
525	zfwflx= rau0 * zgammas * ( (zsfrz-stbl(ji,jj)) / zsfrz )
526	! zhtflx is upward heat flux (out of ocean)
527	! If non conservative we have zcfac=0.0 so zhtflx is as ISOMIP but with different zfrz value
528	zhtflx = ( zgammatrau0 - zcfaczfwflx ) * rcp * (zti(ji,jj) - zfrz(ji,jj) )
529	! zwflx is upward water flux
530	! If non conservative we have zcfac=0.0 so what follows is then zfwflx*sss_m/zsfrz
531	zfwflx = ( zgammasrau0 - zcfaczfwflx ) * (zsfrz - stbl(ji,jj)) / stbl(ji,jj)
532	! test convergence and compute gammat
533	IF (( zhtflx - zhtflx_b) .LE. 0.01 ) lit = .FALSE.
534
535	nit = nit + 1
536	IF (nit .GE. 51) THEN
537	WRITE(numout,*) "sbcisf : too many iteration ... ", zhtflx, zhtflx_b, zgammat, zgammas, nn_gammablk, ji, jj, mikt(ji,jj), narea
538	CALL ctl_stop( 'STOP', 'sbc_isf_hol99 : too many iteration ...' )
539	END IF
540	! save gammat and compute zhtflx_b
541	zgammat2d(ji,jj)=zgammat
542	zgammas2d(ji,jj)=zgammas
543	zhtflx_b = zhtflx
544
545	END DO
546	! If non conservative we have zcfac=0.0 so zhtflx is as ISOMIP but with different zfrz value
547	qisf(ji,jj) = - zhtflx
548	! If non conservative we have zcfac=0.0 so what follows is then zfwflx*sss_m/zsfrz
549	fwfisf(ji,jj) = zfwflx
550	ELSE
551	fwfisf(ji,jj) = 0._wp
552	qisf(ji,jj) = 0._wp
553	ENDIF
554	!
555	END DO
556	END DO
557	ENDIF
558	! lbclnk
559	CALL lbc_lnk(zgammas2d(:,:),'T',1.)
560	CALL lbc_lnk(zgammat2d(:,:),'T',1.)
561	! output
562	CALL iom_put('isfgammat', zgammat2d)
563	CALL iom_put('isfgammas', zgammas2d)
564	!
565	!CALL wrk_dealloc( jpi,jpj, zfrz,zpress,zti, zqisf, zfwfisf )
566	CALL wrk_dealloc( jpi,jpj, zfrz,zpress,zti, zgammat2d, zgammas2d )
567	!
568	IF( nn_timing == 1 ) CALL timing_stop('sbc_isf_cav')
569
570	END SUBROUTINE sbc_isf_cav
571
572	SUBROUTINE sbc_isf_gammats(gt, gs, zqhisf, zqwisf, ji, jj, lit )
573	!!----------------------------------------------------------------------
574	!! ** Purpose : compute the coefficient echange for heat flux
575	!!
576	!! ** Method : gamma assume constant or depends of u* and stability
577	!!
578	!! ** References : Holland and Jenkins, 1999, JPO, p1787-1800, eq 14
579	!! Jenkins et al., 2010, JPO, p2298-2312
580	!!---------------------------------------------------------------------
581	REAL(wp), INTENT(inout) :: gt, gs, zqhisf, zqwisf
582	INTEGER , INTENT(in) :: ji,jj
583	LOGICAL , INTENT(inout) :: lit
584
585	INTEGER :: ikt ! loop index
586	REAL(wp) :: zut, zvt, zustar ! U, V at T point and friction velocity
587	REAL(wp) :: zdku, zdkv ! U, V shear
588	REAL(wp) :: zPr, zSc, zRc ! Prandtl, Scmidth and Richardson number
589	REAL(wp) :: zmob, zmols ! Monin Obukov length, coriolis factor at T point
590	REAL(wp) :: zbuofdep, zhnu ! Bouyancy length scale, sublayer tickness
591	REAL(wp) :: zhmax ! limitation of mol
592	REAL(wp) :: zetastar ! stability parameter
593	REAL(wp) :: zgmolet, zgmoles, zgturb ! contribution of modelecular sublayer and turbulence
594	REAL(wp) :: zcoef ! temporary coef
595	REAL(wp) :: zrhos, zalbet, zbeta, zthermal, zhalin
596	REAL(wp) :: zt, zs, zh
597	REAL(wp), PARAMETER :: zxsiN = 0.052 ! dimensionless constant
598	REAL(wp), PARAMETER :: epsln = 1.0e-20 ! a small positive number
599	REAL(wp), PARAMETER :: znu = 1.95e-6 ! kinamatic viscosity of sea water (m2.s-1)
600	REAL(wp) :: rcs = 1.0e-3_wp ! conversion: mm/s ==> m/s
601	!!---------------------------------------------------------------------
602	!
603	IF( nn_gammablk == 0 ) THEN
604	!! gamma is constant (specified in namelist)
605	gt = rn_gammat0
606	gs = rn_gammas0
607	lit = .FALSE.
608	ELSE IF ( nn_gammablk == 1 ) THEN
609	!! gamma is assume to be proportional to u*
610	!! WARNING in case of Losh 2008 tbl parametrization,
611	!! you have to used the mean value of u in the boundary layer)
612	!! not yet coded
613	!! Jenkins et al., 2010, JPO, p2298-2312
614	ikt = mikt(ji,jj)
615	!! Compute U and V at T points
616	! zut = 0.5 * ( utbl(ji-1,jj ) + utbl(ji,jj) )
617	! zvt = 0.5 * ( vtbl(ji ,jj-1) + vtbl(ji,jj) )
618	zut = utbl(ji,jj)
619	zvt = vtbl(ji,jj)
620
621	!! compute ustar
622	zustar = SQRT( rn_tfri2 * (zut * zut + zvt * zvt) )
623	!! Compute mean value over the TBL
624
625	!! Compute gammats
626	gt = zustar * rn_gammat0
627	gs = zustar * rn_gammas0
628	lit = .FALSE.
629	ELSE IF ( nn_gammablk == 2 ) THEN
630	!! gamma depends of stability of boundary layer
631	!! WARNING in case of Losh 2008 tbl parametrization,
632	!! you have to used the mean value of u in the boundary layer)
633	!! not yet coded
634	!! Holland and Jenkins, 1999, JPO, p1787-1800, eq 14
635	!! as MOL depends of flux and flux depends of MOL, best will be iteration (TO DO)
636	ikt = mikt(ji,jj)
637
638	!! Compute U and V at T points
639	zut = 0.5 * ( utbl(ji-1,jj ) + utbl(ji,jj) )
640	zvt = 0.5 * ( vtbl(ji ,jj-1) + vtbl(ji,jj) )
641
642	!! compute ustar
643	zustar = SQRT( rn_tfri2 * (zut * zut + zvt * zvt) )
644	IF (zustar == 0._wp) THEN ! only for kt = 1 I think
645	gt = rn_gammat0
646	gs = rn_gammas0
647	ELSE
648	!! compute Rc number (as done in zdfric.F90)
649	zcoef = 0.5 / fse3w(ji,jj,ikt)
650	! ! shear of horizontal velocity
651	zdku = zcoef * ( un(ji-1,jj ,ikt ) + un(ji,jj,ikt ) &
652	& -un(ji-1,jj ,ikt+1) - un(ji,jj,ikt+1) )
653	zdkv = zcoef * ( vn(ji ,jj-1,ikt ) + vn(ji,jj,ikt ) &
654	& -vn(ji ,jj-1,ikt+1) - vn(ji,jj,ikt+1) )
655	! ! richardson number (minimum value set to zero)
656	zRc = rn2(ji,jj,ikt+1) / ( zdkuzdku + zdkvzdkv + 1.e-20 )
657
658	!! compute Pr and Sc number (can be improved)
659	zPr = 13.8
660	zSc = 2432.0
661
662	!! compute gamma mole
663	zgmolet = 12.5 * zPr ** (2.0/3.0) - 6.0
664	zgmoles = 12.5 * zSc ** (2.0/3.0) -6.0
665
666	!! compute bouyancy
667	IF( nn_eos < 1) THEN
668	zt = ttbl(ji,jj)
669	zs = stbl(ji,jj) - 35.0
670	zh = fsdepw(ji,jj,ikt)
671	! potential volumic mass
672	zrhos = rhop(ji,jj,ikt)
673	zalbet = ( ( ( - 0.255019e-07 * zt + 0.298357e-05 ) * zt & ! ratio alpha/beta
674	& - 0.203814e-03 ) * zt &
675	& + 0.170907e-01 ) * zt &
676	& + 0.665157e-01 &
677	& + ( - 0.678662e-05 * zs &
678	& - 0.846960e-04 * zt + 0.378110e-02 ) * zs &
679	& + ( ( - 0.302285e-13 * zh &
680	& - 0.251520e-11 * zs &
681	& + 0.512857e-12 * zt * zt ) * zh &
682	& - 0.164759e-06 * zs &
683	& +( 0.791325e-08 * zt - 0.933746e-06 ) * zt &
684	& + 0.380374e-04 ) * zh
685
686	zbeta = ( ( -0.415613e-09 * zt + 0.555579e-07 ) * zt & ! beta
687	& - 0.301985e-05 ) * zt &
688	& + 0.785567e-03 &
689	& + ( 0.515032e-08 * zs &
690	& + 0.788212e-08 * zt - 0.356603e-06 ) * zs &
691	& +( ( 0.121551e-17 * zh &
692	& - 0.602281e-15 * zs &
693	& - 0.175379e-14 * zt + 0.176621e-12 ) * zh &
694	& + 0.408195e-10 * zs &
695	& + ( - 0.213127e-11 * zt + 0.192867e-09 ) * zt &
696	& - 0.121555e-07 ) * zh
697
698	zthermal = zbeta * zalbet / ( rcp * zrhos + epsln )
699	zhalin = zbeta * stbl(ji,jj) * rcs
700	ELSE
701	zrhos = rhop(ji,jj,ikt) + rau0 * ( 1. - tmask(ji,jj,ikt) )
702	zthermal = rn_alpha / ( rcp * zrhos + epsln )
703	zhalin = rn_beta * stbl(ji,jj) * rcs
704	ENDIF
705	!! compute length scale
706	zbuofdep = grav * ( zthermal * zqhisf - zhalin * zqwisf ) !!!!!!!!!!!!!!!!!!!!!!!!!!!!
707
708	!! compute Monin Obukov Length
709	! Maximum boundary layer depth
710	zhmax = fsdept(ji,jj,mbkt(ji,jj)) - fsdepw(ji,jj,mikt(ji,jj)) -0.001
711	! Compute Monin obukhov length scale at the surface and Ekman depth:
712	zmob = zustar ** 3 / (vkarmn * (zbuofdep + epsln))
713	zmols = SIGN(1._wp, zmob) * MIN(ABS(zmob), zhmax) * tmask(ji,jj,ikt)
714
715	!! compute eta* (stability parameter)
716	zetastar = 1 / ( SQRT(1 + MAX(zxsiN * zustar / ( ABS(ff(ji,jj)) * zmols * zRc ), 0.0)))
717
718	!! compute the sublayer thickness
719	zhnu = 5 * znu / zustar
720	!! compute gamma turb
721	zgturb = 1/vkarmn * LOG(zustar * zxsiN * zetastar * zetastar / ( ABS(ff(ji,jj)) * zhnu )) &
722	& + 1 / ( 2 * zxsiN * zetastar ) - 1/vkarmn
723
724	!! compute gammats
725	gt = zustar / (zgturb + zgmolet)
726	gs = zustar / (zgturb + zgmoles)
727	END IF
728	END IF
729
730	END SUBROUTINE
731
732	SUBROUTINE sbc_isf_tbl( varin, varout, cptin )
733	!!----------------------------------------------------------------------
734	!! * SUBROUTINE sbc_isf_tbl *
735	!!
736	!! ** Purpose : compute mean T/S/U/V in the boundary layer
737	!!
738	!!----------------------------------------------------------------------
739	REAL(wp), DIMENSION(:,:,:), INTENT(in) :: varin
740	REAL(wp), DIMENSION(:,:) , INTENT(out):: varout
741
742	CHARACTER(len=1), INTENT(in) :: cptin ! point of variable in/out
743
744	REAL(wp) :: ze3, zhk
745	REAL(wp), DIMENSION(:,:), POINTER :: zikt
746
747	INTEGER :: ji,jj,jk
748	INTEGER :: ikt,ikb
749	INTEGER, DIMENSION(:,:), POINTER :: mkt, mkb
750
751	CALL wrk_alloc( jpi,jpj, mkt, mkb )
752	CALL wrk_alloc( jpi,jpj, zikt )
753
754	! get first and last level of tbl
755	mkt(:,:) = misfkt(:,:)
756	mkb(:,:) = misfkb(:,:)
757
758	varout(:,:)=0._wp
759	DO jj = 2,jpj
760	DO ji = 2,jpi
761	IF (ssmask(ji,jj) == 1) THEN
762	ikt = mkt(ji,jj)
763	ikb = mkb(ji,jj)
764
765	! level fully include in the ice shelf boundary layer
766	DO jk = ikt, ikb - 1
767	ze3 = fse3t_n(ji,jj,jk)
768	IF (cptin == 'T' ) varout(ji,jj) = varout(ji,jj) + varin(ji,jj,jk) * r1_hisf_tbl(ji,jj) * ze3
769	IF (cptin == 'U' ) varout(ji,jj) = varout(ji,jj) + 0.5_wp * (varin(ji,jj,jk) + varin(ji-1,jj,jk)) &
770	& * r1_hisf_tbl(ji,jj) * ze3
771	IF (cptin == 'V' ) varout(ji,jj) = varout(ji,jj) + 0.5_wp * (varin(ji,jj,jk) + varin(ji,jj-1,jk)) &
772	& * r1_hisf_tbl(ji,jj) * ze3
773	END DO
774
775	! level partially include in ice shelf boundary layer
776	zhk = SUM( fse3t_n(ji, jj, ikt:ikb - 1)) * r1_hisf_tbl(ji,jj)
777	IF (cptin == 'T') varout(ji,jj) = varout(ji,jj) + varin(ji,jj,ikb) * (1._wp - zhk)
778	IF (cptin == 'U') varout(ji,jj) = varout(ji,jj) + 0.5_wp * (varin(ji,jj,ikb) + varin(ji-1,jj,ikb)) * (1._wp - zhk)
779	IF (cptin == 'V') varout(ji,jj) = varout(ji,jj) + 0.5_wp * (varin(ji,jj,ikb) + varin(ji,jj-1,ikb)) * (1._wp - zhk)
780	END IF
781	END DO
782	END DO
783
784	CALL wrk_dealloc( jpi,jpj, mkt, mkb )
785	CALL wrk_dealloc( jpi,jpj, zikt )
786
787	IF (cptin == 'T') CALL lbc_lnk(varout,'T',1.)
788	IF (cptin == 'U' .OR. cptin == 'V') CALL lbc_lnk(varout,'T',-1.)
789
790	END SUBROUTINE sbc_isf_tbl
791
792
793	SUBROUTINE sbc_isf_div( phdivn )
794	!!----------------------------------------------------------------------
795	!! * SUBROUTINE sbc_isf_div *
796	!!
797	!! ** Purpose : update the horizontal divergence with the runoff inflow
798	!!
799	!! ** Method :
800	!! CAUTION : risf_tsc(:,:,jp_sal) is negative (outflow) increase the
801	!! divergence and expressed in m/s
802	!!
803	!! ** Action : phdivn decreased by the runoff inflow
804	!!----------------------------------------------------------------------
805	REAL(wp), DIMENSION(:,:,:), INTENT(inout) :: phdivn ! horizontal divergence
806	!!
807	INTEGER :: ji, jj, jk ! dummy loop indices
808	INTEGER :: ikt, ikb
809	INTEGER :: nk_isf
810	REAL(wp) :: zhk, z1_hisf_tbl, zhisf_tbl
811	REAL(wp) :: zfact ! local scalar
812	!!----------------------------------------------------------------------
813	!
814	zfact = 0.5_wp
815	!
816	IF (lk_vvl) THEN ! need to re compute level distribution of isf fresh water
817	DO jj = 1,jpj
818	DO ji = 1,jpi
819	ikt = misfkt(ji,jj)
820	ikb = misfkt(ji,jj)
821	! thickness of boundary layer at least the top level thickness
822	rhisf_tbl(ji,jj) = MAX(rhisf_tbl_0(ji,jj), fse3t(ji,jj,ikt))
823
824	! determine the deepest level influenced by the boundary layer
825	! test on tmask useless ?????
826	DO jk = ikt, mbkt(ji,jj)
827	! IF ( (SUM(fse3t(ji,jj,ikt:jk-1)) .LT. rhisf_tbl(ji,jj)) .AND. (tmask(ji,jj,jk) == 1) ) ikb = jk
828	END DO
829	rhisf_tbl(ji,jj) = MIN(rhisf_tbl(ji,jj), SUM(fse3t(ji,jj,ikt:ikb))) ! limit the tbl to water thickness.
830	misfkb(ji,jj) = ikb ! last wet level of the tbl
831	r1_hisf_tbl(ji,jj) = 1._wp / rhisf_tbl(ji,jj)
832
833	zhk = SUM( fse3t(ji, jj, ikt:ikb - 1)) * r1_hisf_tbl(ji,jj) ! proportion of tbl cover by cell from ikt to ikb - 1
834	ralpha(ji,jj) = rhisf_tbl(ji,jj) * (1._wp - zhk ) / fse3t(ji,jj,ikb) ! proportion of bottom cell influenced by boundary layer
835	END DO
836	END DO
837	END IF ! vvl case
838	!
839	DO jj = 1,jpj
840	DO ji = 1,jpi
841	ikt = misfkt(ji,jj)
842	ikb = misfkb(ji,jj)
843	! level fully include in the ice shelf boundary layer
844	DO jk = ikt, ikb - 1
845	phdivn(ji,jj,jk) = phdivn(ji,jj,jk) + ( fwfisf(ji,jj) + fwfisf_b(ji,jj) ) * r1_hisf_tbl(ji,jj) * r1_rau0 * zfact
846	END DO
847	! level partially include in ice shelf boundary layer
848	phdivn(ji,jj,ikb) = phdivn(ji,jj,ikb) + ( fwfisf(ji,jj) + fwfisf_b(ji,jj) ) * r1_hisf_tbl(ji,jj) * r1_rau0 * zfact * ralpha(ji,jj)
849	!== ice shelf melting mass distributed over several levels ==!
850	END DO
851	END DO
852	!
853	END SUBROUTINE sbc_isf_div
854
855	FUNCTION tinsitu( ptem, psal, ppress ) RESULT( pti )
856	!!----------------------------------------------------------------------
857	!! * ROUTINE eos_init *
858	!!
859	!! ** Purpose : Compute the in-situ temperature [Celcius]
860	!!
861	!! ** Method :
862	!!
863	!! Reference : Bryden,h.,1973,deep-sea res.,20,401-408
864	!!----------------------------------------------------------------------
865	REAL(wp), DIMENSION(jpi,jpj), INTENT(in ) :: ptem ! potential temperature [Celcius]
866	REAL(wp), DIMENSION(jpi,jpj), INTENT(in ) :: psal ! salinity [psu]
867	REAL(wp), DIMENSION(jpi,jpj), INTENT(in ) :: ppress ! pressure [dBar]
868	REAL(wp), DIMENSION(:,:), POINTER :: pti ! in-situ temperature [Celcius]
869	! REAL(wp) :: fsatg
870	! REAL(wp) :: pfps, pfpt, pfphp
871	REAL(wp) :: zt, zs, zp, zh, zq, zxk
872	INTEGER :: ji, jj ! dummy loop indices
873	!
874	CALL wrk_alloc( jpi,jpj, pti )
875	!
876	DO jj=1,jpj
877	DO ji=1,jpi
878	zh = ppress(ji,jj)
879	! Theta1
880	zt = ptem(ji,jj)
881	zs = psal(ji,jj)
882	zp = 0.0
883	zxk= zh * fsatg( zs, zt, zp )
884	zt = zt + 0.5 * zxk
885	zq = zxk
886	! Theta2
887	zp = zp + 0.5 * zh
888	zxk= zh*fsatg( zs, zt, zp )
889	zt = zt + 0.29289322 * ( zxk - zq )
890	zq = 0.58578644 * zxk + 0.121320344 * zq
891	! Theta3
892	zxk= zh * fsatg( zs, zt, zp )
893	zt = zt + 1.707106781 * ( zxk - zq )
894	zq = 3.414213562 * zxk - 4.121320344 * zq
895	! Theta4
896	zp = zp + 0.5 * zh
897	zxk= zh * fsatg( zs, zt, zp )
898	pti(ji,jj) = zt + ( zxk - 2.0 * zq ) / 6.0
899	END DO
900	END DO
901	!
902	CALL wrk_dealloc( jpi,jpj, pti )
903	!
904	END FUNCTION tinsitu
905	!
906	FUNCTION fsatg( pfps, pfpt, pfphp )
907	!!----------------------------------------------------------------------
908	!! * FUNCTION fsatg *
909	!!
910	!! ** Purpose : Compute the Adiabatic laspse rate [Celcius].[decibar]^-1
911	!!
912	!! ** Reference : Bryden,h.,1973,deep-sea res.,20,401-408
913	!!
914	!! ** units : pressure pfphp decibars
915	!! temperature pfpt deg celsius (ipts-68)
916	!! salinity pfps (ipss-78)
917	!! adiabatic fsatg deg. c/decibar
918	!!----------------------------------------------------------------------
919	REAL(wp) :: pfps, pfpt, pfphp
920	REAL(wp) :: fsatg
921	!
922	fsatg = (((-2.1687e-16pfpt+1.8676e-14)pfpt-4.6206e-13)*pfphp &
923	& +((2.7759e-12pfpt-1.1351e-10)(pfps-35.)+((-5.4481e-14*pfpt &
924	& +8.733e-12)pfpt-6.7795e-10)pfpt+1.8741e-8))*pfphp &
925	& +(-4.2393e-8pfpt+1.8932e-6)(pfps-35.) &
926	& +((6.6228e-10pfpt-6.836e-8)pfpt+8.5258e-6)*pfpt+3.5803e-5
927	!
928	END FUNCTION fsatg
929	!!======================================================================
930	END MODULE sbcisf

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