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limthd_lac.F90 in branches/2013/dev_r4028_CNRS_LIM3/NEMOGCM/NEMO/LIM_SRC_3 – NEMO

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source: branches/2013/dev_r4028_CNRS_LIM3/NEMOGCM/NEMO/LIM_SRC_3/limthd_lac.F90 @ 4649

Last change on this file since 4649 was 4649, checked in by clem, 10 years ago
finalizing LIM3 heat budget conservation + multiple minor bugs corrections
Property svn:keywords set to `Id`
File size: 26.5 KB

Line
1	MODULE limthd_lac
2	!!======================================================================
3	!! * MODULE limthd_lac *
4	!! lateral thermodynamic growth of the ice
5	!!======================================================================
6	!! History : LIM ! 2005-12 (M. Vancoppenolle) Original code
7	!! - ! 2006-01 (M. Vancoppenolle) add ITD
8	!! 3.0 ! 2007-07 (M. Vancoppenolle) Mass and energy conservation tested
9	!! 4.0 ! 2011-02 (G. Madec) dynamical allocation
10	!!----------------------------------------------------------------------
11	#if defined key_lim3
12	!!----------------------------------------------------------------------
13	!! 'key_lim3' LIM3 sea-ice model
14	!!----------------------------------------------------------------------
15	!! lim_lat_acr : lateral accretion of ice
16	!!----------------------------------------------------------------------
17	USE par_oce ! ocean parameters
18	USE dom_oce ! domain variables
19	USE phycst ! physical constants
20	USE sbc_oce ! Surface boundary condition: ocean fields
21	USE sbc_ice ! Surface boundary condition: ice fields
22	USE thd_ice ! LIM thermodynamics
23	USE dom_ice ! LIM domain
24	USE par_ice ! LIM parameters
25	USE ice ! LIM variables
26	USE limtab ! LIM 2D <==> 1D
27	USE limcons ! LIM conservation
28	USE in_out_manager ! I/O manager
29	USE lib_mpp ! MPP library
30	USE wrk_nemo ! work arrays
31	USE lib_fortran ! Fortran utilities (allows no signed zero when 'key_nosignedzero' defined)
32	USE limthd_ent
33
34	IMPLICIT NONE
35	PRIVATE
36
37	PUBLIC lim_thd_lac ! called by lim_thd
38
39	REAL(wp) :: epsi10 = 1.e-10_wp !
40	REAL(wp) :: epsi20 = 1.e-20_wp !
41
42	!!----------------------------------------------------------------------
43	!! NEMO/LIM3 4.0 , UCL - NEMO Consortium (2011)
44	!! $Id$
45	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
46	!!----------------------------------------------------------------------
47	CONTAINS
48
49	SUBROUTINE lim_thd_lac
50	!!-------------------------------------------------------------------
51	!! * ROUTINE lim_thd_lac *
52	!!
53	!! ** Purpose : Computation of the evolution of the ice thickness and
54	!! concentration as a function of the heat balance in the leads.
55	!! It is only used for lateral accretion
56	!!
57	!! ** Method : Ice is formed in the open water when ocean lose heat
58	!! (heat budget of open water Bl is negative) .
59	!! Computation of the increase of 1-A (ice concentration) fol-
60	!! lowing the law :
61	!! (dA/dt)acc = F[ (1-A)/(1-a) ] * [ Bl / (Li*h0) ]
62	!! where - h0 is the thickness of ice created in the lead
63	!! - a is a minimum fraction for leads
64	!! - F is a monotonic non-increasing function defined as:
65	!! F(X)=( 1 - Xexld )(1.0/exld)
66	!! - exld is the exponent closure rate (=2 default val.)
67	!!
68	!! ** Action : - Adjustment of snow and ice thicknesses and heat
69	!! content in brine pockets
70	!! - Updating ice internal temperature
71	!! - Computation of variation of ice volume and mass
72	!! - Computation of frldb after lateral accretion and
73	!! update ht_s_b, ht_i_b and tbif_1d(:,:)
74	!!------------------------------------------------------------------------
75	INTEGER :: ji,jj,jk,jl,jm ! dummy loop indices
76	INTEGER :: layer, nbpac ! local integers
77	INTEGER :: ii, ij, iter ! - -
78	REAL(wp) :: ztmelts, zdv, zfrazb, zweight, zindb, zinda, zde ! local scalars
79	REAL(wp) :: zgamafr, zvfrx, zvgx, ztaux, ztwogp, zf , zhicol_new ! - -
80	REAL(wp) :: ztenagm, zvfry, zvgy, ztauy, zvrel2, zfp, zsqcd , zhicrit ! - -
81	LOGICAL :: iterate_frazil ! iterate frazil ice collection thickness
82	CHARACTER (len = 15) :: fieldid
83
84	REAL(wp) :: zQm ! enthalpy exchanged with the ocean (J/m2, >0 towards ocean)
85	REAL(wp) :: zEi ! sea ice specific enthalpy (J/kg)
86	REAL(wp) :: zEw ! seawater specific enthalpy (J/kg)
87	REAL(wp) :: zfmdt ! mass flux x time step (kg/m2, >0 towards ocean)
88
89	REAL(wp) :: zv_newfra
90
91	INTEGER , POINTER, DIMENSION(:) :: jcat ! indexes of categories where new ice grows
92	REAL(wp), POINTER, DIMENSION(:) :: zswinew ! switch for new ice or not
93
94	REAL(wp), POINTER, DIMENSION(:) :: zv_newice ! volume of accreted ice
95	REAL(wp), POINTER, DIMENSION(:) :: za_newice ! fractional area of accreted ice
96	REAL(wp), POINTER, DIMENSION(:) :: zh_newice ! thickness of accreted ice
97	REAL(wp), POINTER, DIMENSION(:) :: ze_newice ! heat content of accreted ice
98	REAL(wp), POINTER, DIMENSION(:) :: zs_newice ! salinity of accreted ice
99	REAL(wp), POINTER, DIMENSION(:) :: zo_newice ! age of accreted ice
100	REAL(wp), POINTER, DIMENSION(:) :: zdv_res ! residual volume in case of excessive heat budget
101	REAL(wp), POINTER, DIMENSION(:) :: zda_res ! residual area in case of excessive heat budget
102	REAL(wp), POINTER, DIMENSION(:) :: zat_i_1d ! total ice fraction
103	REAL(wp), POINTER, DIMENSION(:) :: zat_i_lev ! total ice fraction for level ice only (type 1)
104	REAL(wp), POINTER, DIMENSION(:) :: zv_frazb ! accretion of frazil ice at the ice bottom
105	REAL(wp), POINTER, DIMENSION(:) :: zvrel_1d ! relative ice / frazil velocity (1D vector)
106
107	REAL(wp), POINTER, DIMENSION(:,:) :: zv_old ! old volume of ice in category jl
108	REAL(wp), POINTER, DIMENSION(:,:) :: za_old ! old area of ice in category jl
109	REAL(wp), POINTER, DIMENSION(:,:) :: za_i_1d ! 1-D version of a_i
110	REAL(wp), POINTER, DIMENSION(:,:) :: zv_i_1d ! 1-D version of v_i
111	REAL(wp), POINTER, DIMENSION(:,:) :: zoa_i_1d ! 1-D version of oa_i
112	REAL(wp), POINTER, DIMENSION(:,:) :: zsmv_i_1d ! 1-D version of smv_i
113
114	REAL(wp), POINTER, DIMENSION(:,:,:) :: ze_i_1d !: 1-D version of e_i
115
116	REAL(wp), POINTER, DIMENSION(:,:) :: zvrel ! relative ice / frazil velocity
117	!!-----------------------------------------------------------------------!
118
119	CALL wrk_alloc( jpij, jcat ) ! integer
120	CALL wrk_alloc( jpij, zswinew, zv_newice, za_newice, zh_newice, ze_newice, zs_newice, zo_newice )
121	CALL wrk_alloc( jpij, zdv_res, zda_res, zat_i_1d, zat_i_lev, zv_frazb, zvrel_1d )
122	CALL wrk_alloc( jpij,jpl, zv_old, za_old, za_i_1d, zv_i_1d, zoa_i_1d, zsmv_i_1d )
123	CALL wrk_alloc( jpij,jkmax,jpl, ze_i_1d )
124	CALL wrk_alloc( jpi,jpj, zvrel )
125
126	!------------------------------------------------------------------------------\|
127	! 2) Convert units for ice internal energy
128	!------------------------------------------------------------------------------\|
129	DO jl = 1, jpl
130	DO jk = 1, nlay_i
131	DO jj = 1, jpj
132	DO ji = 1, jpi
133	!Energy of melting q(S,T) [J.m-3]
134	zindb = 1._wp - MAX( 0._wp , SIGN( 1._wp , -v_i(ji,jj,jl) + epsi10 ) ) !0 if no ice and 1 if yes
135	e_i(ji,jj,jk,jl) = zindb * e_i(ji,jj,jk,jl) / ( area(ji,jj) * MAX( v_i(ji,jj,jl) , epsi10 ) ) * REAL( nlay_i )
136	e_i(ji,jj,jk,jl) = e_i(ji,jj,jk,jl) * unit_fac
137	END DO
138	END DO
139	END DO
140	END DO
141
142	!------------------------------------------------------------------------------!
143	! 3) Collection thickness of ice formed in leads and polynyas
144	!------------------------------------------------------------------------------!
145	! hicol is the thickness of new ice formed in open water
146	! hicol can be either prescribed (frazswi = 0)
147	! or computed (frazswi = 1)
148	! Frazil ice forms in open water, is transported by wind
149	! accumulates at the edge of the consolidated ice edge
150	! where it forms aggregates of a specific thickness called
151	! collection thickness.
152
153	! Note : the following algorithm currently breaks vectorization
154	!
155
156	zvrel(:,:) = 0._wp
157
158	! Default new ice thickness
159	hicol(:,:) = hiccrit(1)
160
161	IF( fraz_swi == 1._wp ) THEN
162
163	!--------------------
164	! Physical constants
165	!--------------------
166	hicol(:,:) = 0._wp
167
168	zhicrit = 0.04 ! frazil ice thickness
169	ztwogp = 2. * rau0 / ( grav * 0.3 * ( rau0 - rhoic ) ) ! reduced grav
170	zsqcd = 1.0 / SQRT( 1.3 * cai ) ! 1/SQRT(airdensity*drag)
171	zgamafr = 0.03
172
173	DO jj = 1, jpj
174	DO ji = 1, jpi
175
176	IF ( qlead(ji,jj) < 0._wp ) THEN
177	!-------------
178	! Wind stress
179	!-------------
180	! C-grid wind stress components
181	ztaux = ( utau_ice(ji-1,jj ) * tmu(ji-1,jj ) &
182	& + utau_ice(ji ,jj ) * tmu(ji ,jj ) ) * 0.5_wp
183	ztauy = ( vtau_ice(ji ,jj-1) * tmv(ji ,jj-1) &
184	& + vtau_ice(ji ,jj ) * tmv(ji ,jj ) ) * 0.5_wp
185	! Square root of wind stress
186	ztenagm = SQRT( SQRT( ztaux2 + ztauy2 ) )
187
188	!---------------------
189	! Frazil ice velocity
190	!---------------------
191	zindb = MAX( 0._wp, SIGN( 1._wp , ztenagm - epsi10 ) )
192	zvfrx = zindb * zgamafr * zsqcd * ztaux / MAX( ztenagm, epsi10 )
193	zvfry = zindb * zgamafr * zsqcd * ztauy / MAX( ztenagm, epsi10 )
194
195	!-------------------
196	! Pack ice velocity
197	!-------------------
198	! C-grid ice velocity
199	zindb = MAX( 0._wp, SIGN( 1._wp , at_i(ji,jj) ) )
200	zvgx = zindb * ( u_ice(ji-1,jj ) * tmu(ji-1,jj ) &
201	& + u_ice(ji,jj ) * tmu(ji ,jj ) ) * 0.5_wp
202	zvgy = zindb * ( v_ice(ji ,jj-1) * tmv(ji ,jj-1) &
203	& + v_ice(ji,jj ) * tmv(ji ,jj ) ) * 0.5_wp
204
205	!-----------------------------------
206	! Relative frazil/pack ice velocity
207	!-----------------------------------
208	! absolute relative velocity
209	zvrel2 = MAX( ( zvfrx - zvgx ) * ( zvfrx - zvgx ) &
210	& + ( zvfry - zvgy ) * ( zvfry - zvgy ) , 0.15 * 0.15 )
211	zvrel(ji,jj) = SQRT( zvrel2 )
212
213	!---------------------
214	! Iterative procedure
215	!---------------------
216	hicol(ji,jj) = zhicrit + 0.1
217	hicol(ji,jj) = zhicrit + hicol(ji,jj) &
218	& / ( hicol(ji,jj) * hicol(ji,jj) - zhicrit * zhicrit ) * ztwogp * zvrel2
219
220	!!gm better coding: above: hicol(ji,jj) * hicol(ji,jj) = (zhicrit + 0.1)*(zhicrit + 0.1)
221	!!gm = zhicrit*2 + 0.2zhicrit +0.01
222	!!gm therefore the 2 lines with hicol can be replaced by 1 line:
223	!!gm hicol(ji,jj) = zhicrit + (zhicrit + 0.1) / ( 0.2 * zhicrit + 0.01 ) * ztwogp * zvrel2
224	!!gm further more (zhicrit + 0.1)/(0.2 * zhicrit + 0.01 )*ztwogp can be computed one for all outside the DO loop
225
226	iter = 1
227	iterate_frazil = .true.
228
229	DO WHILE ( iter .LT. 100 .AND. iterate_frazil )
230	zf = ( hicol(ji,jj) - zhicrit ) * ( hicol(ji,jj)2 - zhicrit2 ) &
231	- hicol(ji,jj) * zhicrit * ztwogp * zvrel2
232	zfp = ( hicol(ji,jj) - zhicrit ) * ( 3.0*hicol(ji,jj) + zhicrit ) &
233	- zhicrit * ztwogp * zvrel2
234	zhicol_new = hicol(ji,jj) - zf/zfp
235	hicol(ji,jj) = zhicol_new
236
237	iter = iter + 1
238
239	END DO ! do while
240
241	ENDIF ! end of selection of pixels where ice forms
242
243	END DO ! loop on ji ends
244	END DO ! loop on jj ends
245
246	ENDIF ! End of computation of frazil ice collection thickness
247
248	!------------------------------------------------------------------------------!
249	! 4) Identify grid points where new ice forms
250	!------------------------------------------------------------------------------!
251
252	!-------------------------------------
253	! Select points for new ice formation
254	!-------------------------------------
255	! This occurs if open water energy budget is negative
256	nbpac = 0
257	DO jj = 1, jpj
258	DO ji = 1, jpi
259	IF ( qlead(ji,jj) < 0._wp ) THEN
260	nbpac = nbpac + 1
261	npac( nbpac ) = (jj - 1) * jpi + ji
262	ENDIF
263	END DO
264	END DO
265
266	! debug point to follow
267	jiindex_1d = 0
268	IF( ln_nicep ) THEN
269	DO ji = mi0(jiindx), mi1(jiindx)
270	DO jj = mj0(jjindx), mj1(jjindx)
271	IF ( qlead(ji,jj) < 0._wp ) THEN
272	jiindex_1d = (jj - 1) * jpi + ji
273	ENDIF
274	END DO
275	END DO
276	ENDIF
277
278	IF( ln_nicep ) WRITE(numout,*) 'lim_thd_lac : nbpac = ', nbpac
279
280	!------------------------------
281	! Move from 2-D to 1-D vectors
282	!------------------------------
283	! If ocean gains heat do nothing
284	! 0therwise compute new ice formation
285
286	IF ( nbpac > 0 ) THEN
287
288	CALL tab_2d_1d( nbpac, zat_i_1d (1:nbpac) , at_i , jpi, jpj, npac(1:nbpac) )
289	DO jl = 1, jpl
290	CALL tab_2d_1d( nbpac, za_i_1d (1:nbpac,jl), a_i (:,:,jl), jpi, jpj, npac(1:nbpac) )
291	CALL tab_2d_1d( nbpac, zv_i_1d (1:nbpac,jl), v_i (:,:,jl), jpi, jpj, npac(1:nbpac) )
292	CALL tab_2d_1d( nbpac, zoa_i_1d (1:nbpac,jl), oa_i (:,:,jl), jpi, jpj, npac(1:nbpac) )
293	CALL tab_2d_1d( nbpac, zsmv_i_1d(1:nbpac,jl), smv_i(:,:,jl), jpi, jpj, npac(1:nbpac) )
294	DO jk = 1, nlay_i
295	CALL tab_2d_1d( nbpac, ze_i_1d(1:nbpac,jk,jl), e_i(:,:,jk,jl) , jpi, jpj, npac(1:nbpac) )
296	END DO ! jk
297	END DO ! jl
298
299	CALL tab_2d_1d( nbpac, qlead_1d (1:nbpac) , qlead , jpi, jpj, npac(1:nbpac) )
300	CALL tab_2d_1d( nbpac, t_bo_b (1:nbpac) , t_bo , jpi, jpj, npac(1:nbpac) )
301	CALL tab_2d_1d( nbpac, sfx_opw_1d(1:nbpac) , sfx_opw, jpi, jpj, npac(1:nbpac) )
302	CALL tab_2d_1d( nbpac, wfx_opw_1d(1:nbpac) , wfx_opw, jpi, jpj, npac(1:nbpac) )
303	CALL tab_2d_1d( nbpac, wfx_opw_1d(1:nbpac) , wfx_opw, jpi, jpj, npac(1:nbpac) )
304	CALL tab_2d_1d( nbpac, hicol_b (1:nbpac) , hicol , jpi, jpj, npac(1:nbpac) )
305	CALL tab_2d_1d( nbpac, zvrel_1d (1:nbpac) , zvrel , jpi, jpj, npac(1:nbpac) )
306
307	CALL tab_2d_1d( nbpac, hfx_thd_1d(1:nbpac) , hfx_thd, jpi, jpj, npac(1:nbpac) )
308	CALL tab_2d_1d( nbpac, hfx_opw_1d(1:nbpac) , hfx_opw, jpi, jpj, npac(1:nbpac) )
309
310	!------------------------------------------------------------------------------!
311	! 5) Compute thickness, salinity, enthalpy, age, area and volume of new ice
312	!------------------------------------------------------------------------------!
313
314	!-----------------------------------------
315	! Keep old ice areas and volume in memory
316	!-----------------------------------------
317	zv_old(:,:) = zv_i_1d(:,:)
318	za_old(:,:) = za_i_1d(:,:)
319
320	!----------------------
321	! Thickness of new ice
322	!----------------------
323	DO ji = 1, nbpac
324	zh_newice(ji) = hiccrit(1)
325	END DO
326	IF( fraz_swi == 1.0 ) zh_newice(:) = hicol_b(:)
327
328	!----------------------
329	! Salinity of new ice
330	!----------------------
331
332	SELECT CASE ( num_sal )
333	CASE ( 1 ) ! Sice = constant
334	zs_newice(:) = bulk_sal
335	CASE ( 2 ) ! Sice = F(z,t) [Vancoppenolle et al (2005)]
336	DO ji = 1, nbpac
337	ii = MOD( npac(ji) - 1 , jpi ) + 1
338	ij = ( npac(ji) - 1 ) / jpi + 1
339	zs_newice(ji) = MIN( 4.606 + 0.91 / zh_newice(ji) , s_i_max , 0.5 * sss_m(ii,ij) )
340	END DO
341	CASE ( 3 ) ! Sice = F(z) [multiyear ice]
342	zs_newice(:) = 2.3
343	END SELECT
344
345
346	!-------------------------
347	! Heat content of new ice
348	!-------------------------
349	! We assume that new ice is formed at the seawater freezing point
350	DO ji = 1, nbpac
351	ztmelts = - tmut * zs_newice(ji) + rtt ! Melting point (K)
352	ze_newice(ji) = rhoic * ( cpic * ( ztmelts - t_bo_b(ji) ) &
353	& + lfus * ( 1.0 - ( ztmelts - rtt ) / MIN( t_bo_b(ji) - rtt, -epsi10 ) ) &
354	& - rcp * ( ztmelts - rtt ) )
355	END DO ! ji
356	!----------------
357	! Age of new ice
358	!----------------
359	DO ji = 1, nbpac
360	zo_newice(ji) = 0._wp
361	END DO ! ji
362
363	!-------------------
364	! Volume of new ice
365	!-------------------
366	DO ji = 1, nbpac
367
368	zEi = - ze_newice(ji) / rhoic ! specific enthalpy of forming ice [J/kg]
369
370	zEw = rcp * ( t_bo_b(ji) - rt0 ) ! specific enthalpy of seawater at t_bo_b [J/kg]
371	! clem: we suppose we are already at the freezing point (condition qlead<0 is satisfyied)
372
373	zdE = zEi - zEw ! specific enthalpy difference [J/kg]
374
375	zfmdt = - qlead_1d(ji) / zdE ! Fm.dt [kg/m2] (<0)
376	! clem: we use qlead instead of zqld (limthd) because we suppose we are at the freezing point
377	zv_newice(ji) = - zfmdt / rhoic
378
379	zQm = zfmdt * zEw ! heat to the ocean >0 associated with mass flux
380
381	! Contribution to heat flux to the ocean [W.m-2], >0
382	hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * zEw * r1_rdtice
383	! Total heat flux used in this process [W.m-2]
384	hfx_opw_1d(ji) = hfx_opw_1d(ji) - zfmdt * zdE * r1_rdtice
385	! mass flux
386	wfx_opw_1d(ji) = wfx_opw_1d(ji) - zv_newice(ji) * rhoic * r1_rdtice
387	! salt flux
388	sfx_opw_1d(ji) = sfx_opw_1d(ji) - zv_newice(ji) * rhoic * zs_newice(ji) * r1_rdtice
389
390	! A fraction zfrazb of frazil ice is accreted at the ice bottom
391	zinda = 1._wp - MAX( 0._wp, SIGN( 1._wp , - zat_i_1d(ji) ) )
392	zfrazb = zinda * ( TANH ( Cfrazb * ( zvrel_1d(ji) - vfrazb ) ) + 1.0 ) * 0.5 * maxfrazb
393	zv_frazb(ji) = zfrazb * zv_newice(ji)
394	zv_newice(ji) = ( 1.0 - zfrazb ) * zv_newice(ji)
395	END DO
396
397
398	!-----------------
399	! Area of new ice
400	!-----------------
401	DO ji = 1, nbpac
402	za_newice(ji) = zv_newice(ji) / zh_newice(ji)
403	END DO
404
405	!------------------------------------------------------------------------------!
406	! 6) Redistribute new ice area and volume into ice categories !
407	!------------------------------------------------------------------------------!
408
409	!-------------------------------------------
410	! Compute excessive new ice area and volume
411	!-------------------------------------------
412	! If lateral ice growth gives an ice concentration gt 1, then
413	! we keep the excessive volume in memory and attribute it later to bottom accretion
414	DO ji = 1, nbpac
415	IF ( za_newice(ji) > ( amax - zat_i_1d(ji) ) ) THEN
416	zda_res(ji) = za_newice(ji) - ( amax - zat_i_1d(ji) )
417	zdv_res(ji) = zda_res (ji) * zh_newice(ji)
418	za_newice(ji) = za_newice(ji) - zda_res (ji)
419	zv_newice(ji) = zv_newice(ji) - zdv_res (ji)
420	ELSE
421	zda_res(ji) = 0._wp
422	zdv_res(ji) = 0._wp
423	ENDIF
424	END DO ! ji
425
426	!------------------------------------------------
427	! Laterally redistribute new ice volume and area
428	!------------------------------------------------
429	zat_i_1d(:) = 0._wp
430	DO jl = 1, jpl
431	DO ji = 1, nbpac
432	IF( zh_newice(ji) > hi_max(jl-1) .AND. zh_newice(ji) <= hi_max(jl) ) THEN
433	za_i_1d (ji,jl) = za_i_1d (ji,jl) + za_newice(ji)
434	zv_i_1d (ji,jl) = zv_i_1d (ji,jl) + zv_newice(ji)
435	jcat (ji) = jl
436	ENDIF
437	zat_i_1d(ji) = zat_i_1d(ji) + za_i_1d (ji,jl)
438	END DO
439	END DO
440
441	!----------------------------------
442	! Heat content - lateral accretion
443	!----------------------------------
444	DO ji = 1, nbpac
445	jl = jcat(ji) ! categroy in which new ice is put
446	zswinew (ji) = MAX( 0._wp , SIGN( 1._wp , - za_old(ji,jl) ) ) ! 0 if old ice
447	END DO
448
449	DO jk = 1, nlay_i
450	DO ji = 1, nbpac
451	jl = jcat(ji)
452	zinda = MAX( 0._wp, SIGN( 1._wp , zv_i_1d(ji,jl) - epsi20 ) )
453	ze_i_1d(ji,jk,jl) = zswinew(ji) * ze_newice(ji) + &
454	& ( 1.0 - zswinew(ji) ) * ( ze_newice(ji) * zv_newice(ji) + ze_i_1d(ji,jk,jl) * zv_old(ji,jl) ) &
455	& * zinda / MAX( zv_i_1d(ji,jl), epsi20 )
456	END DO
457	END DO
458
459	!-----------------------------------------------
460	! Add excessive volume of new ice at the bottom
461	!-----------------------------------------------
462	DO jl = 1, jpl
463	h_i_old (1:nbpac,0:nlay_i+1) = 0._wp
464	qh_i_old(1:nbpac,0:nlay_i+1) = 0._wp
465
466	DO jk = 1, nlay_i
467	DO ji = 1, nbpac
468	h_i_old (ji,jk) = zv_i_1d(ji,jl) / REAL( nlay_i )
469	qh_i_old(ji,jk) = ze_i_1d(ji,jk,jl) * h_i_old(ji,jk)
470	END DO
471	END DO
472
473	DO ji = 1, nbpac
474	zinda = MAX( 0._wp, SIGN( 1._wp , zat_i_1d(ji) - epsi20 ) )
475	zv_newfra = zinda * ( zdv_res(ji) + zv_frazb(ji) ) * za_i_1d(ji,jl) / MAX( zat_i_1d(ji) , epsi20 )
476	za_i_1d(ji,jl) = zinda * za_i_1d(ji,jl)
477
478	h_i_old (ji,nlay_i+1) = zv_newfra
479	qh_i_old(ji,nlay_i+1) = ze_newice(ji) * zv_newfra
480
481	zv_i_1d(ji,jl) = zv_i_1d(ji,jl) + zv_newfra
482	ENDDO
483
484	! --- Ice enthalpy remapping --- !
485	CALL lim_thd_ent( 1, nbpac, jl, ze_i_1d(1:nbpac,:,jl) )
486
487	ENDDO
488
489	!------------
490	! Update age
491	!------------
492	DO jl = 1, jpl
493	DO ji = 1, nbpac
494	zindb = 1._wp - MAX( 0._wp , SIGN( 1._wp , - za_i_1d(ji,jl) + epsi20 ) ) ! 0 if no ice and 1 if yes
495	zoa_i_1d(ji,jl) = za_old(ji,jl) * zoa_i_1d(ji,jl) / MAX( za_i_1d(ji,jl) , epsi20 ) * zindb
496	END DO
497	END DO
498
499	!-----------------
500	! Update salinity
501	!-----------------
502	!clem IF( num_sal == 2 ) THEN
503	DO jl = 1, jpl
504	DO ji = 1, nbpac
505	zdv = zv_i_1d(ji,jl) - zv_old(ji,jl)
506	zsmv_i_1d(ji,jl) = zsmv_i_1d(ji,jl) + zdv * zs_newice(ji)
507	END DO
508	END DO
509	!clem ENDIF
510
511	!------------------------------------------------------------------------------!
512	! 8) Change 2D vectors to 1D vectors
513	!------------------------------------------------------------------------------!
514	DO jl = 1, jpl
515	CALL tab_1d_2d( nbpac, a_i (:,:,jl), npac(1:nbpac), za_i_1d (1:nbpac,jl), jpi, jpj )
516	CALL tab_1d_2d( nbpac, v_i (:,:,jl), npac(1:nbpac), zv_i_1d (1:nbpac,jl), jpi, jpj )
517	CALL tab_1d_2d( nbpac, oa_i(:,:,jl), npac(1:nbpac), zoa_i_1d(1:nbpac,jl), jpi, jpj )
518	CALL tab_1d_2d( nbpac, smv_i (:,:,jl), npac(1:nbpac), zsmv_i_1d(1:nbpac,jl) , jpi, jpj )
519	DO jk = 1, nlay_i
520	CALL tab_1d_2d( nbpac, e_i(:,:,jk,jl), npac(1:nbpac), ze_i_1d(1:nbpac,jk,jl), jpi, jpj )
521	END DO
522	END DO
523	CALL tab_1d_2d( nbpac, sfx_opw, npac(1:nbpac), sfx_opw_1d(1:nbpac), jpi, jpj )
524	CALL tab_1d_2d( nbpac, wfx_opw, npac(1:nbpac), wfx_opw_1d(1:nbpac), jpi, jpj )
525	CALL tab_1d_2d( nbpac, wfx_opw, npac(1:nbpac), wfx_opw_1d(1:nbpac), jpi, jpj )
526
527	CALL tab_1d_2d( nbpac, hfx_thd, npac(1:nbpac), hfx_thd_1d(1:nbpac), jpi, jpj )
528	CALL tab_1d_2d( nbpac, hfx_opw, npac(1:nbpac), hfx_opw_1d(1:nbpac), jpi, jpj )
529	!
530	ENDIF ! nbpac > 0
531
532	!------------------------------------------------------------------------------!
533	! 9) Change units for e_i
534	!------------------------------------------------------------------------------!
535	DO jl = 1, jpl
536	DO jk = 1, nlay_i
537	DO jj = 1, jpj
538	DO ji = 1, jpi
539	! heat content in Joules
540	e_i(ji,jj,jk,jl) = e_i(ji,jj,jk,jl) * area(ji,jj) * v_i(ji,jj,jl) / ( REAL( nlay_i ) * unit_fac )
541	END DO
542	END DO
543	END DO
544	END DO
545
546	!
547	CALL wrk_dealloc( jpij, jcat ) ! integer
548	CALL wrk_dealloc( jpij, zswinew, zv_newice, za_newice, zh_newice, ze_newice, zs_newice, zo_newice )
549	CALL wrk_dealloc( jpij, zdv_res, zda_res, zat_i_1d, zat_i_lev, zv_frazb, zvrel_1d )
550	CALL wrk_dealloc( jpij,jpl, zv_old, za_old, za_i_1d, zv_i_1d, zoa_i_1d, zsmv_i_1d )
551	CALL wrk_dealloc( jpij,jkmax,jpl, ze_i_1d )
552	CALL wrk_dealloc( jpi,jpj, zvrel )
553	!
554	END SUBROUTINE lim_thd_lac
555
556	#else
557	!!----------------------------------------------------------------------
558	!! Default option NO LIM3 sea-ice model
559	!!----------------------------------------------------------------------
560	CONTAINS
561	SUBROUTINE lim_thd_lac ! Empty routine
562	END SUBROUTINE lim_thd_lac
563	#endif
564
565	!!======================================================================
566	END MODULE limthd_lac

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