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limthd_dh.F90 in branches/2015/nemo_v3_6_STABLE/NEMOGCM/NEMO/LIM_SRC_3 – NEMO

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source: branches/2015/nemo_v3_6_STABLE/NEMOGCM/NEMO/LIM_SRC_3/limthd_dh.F90 @ 6399

Last change on this file since 6399 was 6399, checked in by clem, 8 years ago
solve issues for 1)wrong fresh water budget sent to passive tracers and 2)ice-air coupling. See tickets #1694 #1696 #1697 and #1698
Property svn:keywords set to `Id`
File size: 37.6 KB

Rev	Line
[825]	1	MODULE limthd_dh
[1572]	2	!!======================================================================
	3	!! * MODULE limthd_dh *
	4	!! LIM-3 : thermodynamic growth and decay of the ice
	5	!!======================================================================
	6	!! History : LIM ! 2003-05 (M. Vancoppenolle) Original code in 1D
	7	!! ! 2005-06 (M. Vancoppenolle) 3D version
[4688]	8	!! 3.2 ! 2009-07 (M. Vancoppenolle, Y. Aksenov, G. Madec) bug correction in wfx_snw & wfx_ice
[3625]	9	!! 3.4 ! 2011-02 (G. Madec) dynamical allocation
	10	!! 3.5 ! 2012-10 (G. Madec & co) salt flux + bug fixes
[1572]	11	!!----------------------------------------------------------------------
[825]	12	#if defined key_lim3
[834]	13	!!----------------------------------------------------------------------
	14	!! 'key_lim3' LIM3 sea-ice model
	15	!!----------------------------------------------------------------------
[3625]	16	!! lim_thd_dh : vertical accr./abl. and lateral ablation of sea ice
[825]	17	!!----------------------------------------------------------------------
[3625]	18	USE par_oce ! ocean parameters
	19	USE phycst ! physical constants (OCE directory)
	20	USE sbc_oce ! Surface boundary condition: ocean fields
	21	USE ice ! LIM variables
	22	USE thd_ice ! LIM thermodynamics
	23	USE in_out_manager ! I/O manager
	24	USE lib_mpp ! MPP library
	25	USE wrk_nemo ! work arrays
	26	USE lib_fortran ! Fortran utilities (allows no signed zero when 'key_nosignedzero' defined)
[4688]	27
[825]	28	IMPLICIT NONE
	29	PRIVATE
	30
[5407]	31	PUBLIC lim_thd_dh ! called by lim_thd
[5487]	32	PUBLIC lim_thd_snwblow ! called in sbcblk/sbcclio/sbccpl and here
[825]	33
[5407]	34	INTERFACE lim_thd_snwblow
	35	MODULE PROCEDURE lim_thd_snwblow_1d, lim_thd_snwblow_2d
	36	END INTERFACE
	37
[825]	38	!!----------------------------------------------------------------------
[4161]	39	!! NEMO/LIM3 4.0 , UCL - NEMO Consortium (2010)
[1156]	40	!! $Id$
[2715]	41	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
[825]	42	!!----------------------------------------------------------------------
	43	CONTAINS
	44
[4688]	45	SUBROUTINE lim_thd_dh( kideb, kiut )
[921]	46	!!------------------------------------------------------------------
	47	!! * ROUTINE lim_thd_dh *
	48	!!
[1572]	49	!! ** Purpose : determines variations of ice and snow thicknesses.
[921]	50	!!
[1572]	51	!! ** Method : Ice/Snow surface melting arises from imbalance in surface fluxes
	52	!! Bottom accretion/ablation arises from flux budget
	53	!! Snow thickness can increase by precipitation and decrease by sublimation
	54	!! If snow load excesses Archmiede limit, snow-ice is formed by
	55	!! the flooding of sea-water in the snow
[921]	56	!!
[1572]	57	!! 1) Compute available flux of heat for surface ablation
	58	!! 2) Compute snow and sea ice enthalpies
	59	!! 3) Surface ablation and sublimation
	60	!! 4) Bottom accretion/ablation
	61	!! 5) Case of Total ablation
	62	!! 6) Snow ice formation
[921]	63	!!
[1572]	64	!! References : Bitz and Lipscomb, 1999, J. Geophys. Res.
	65	!! Fichefet T. and M. Maqueda 1997, J. Geophys. Res., 102(C6), 12609-12646
	66	!! Vancoppenolle, Fichefet and Bitz, 2005, Geophys. Res. Let.
	67	!! Vancoppenolle et al.,2009, Ocean Modelling
[921]	68	!!------------------------------------------------------------------
[1572]	69	INTEGER , INTENT(in) :: kideb, kiut ! Start/End point on which the the computation is applied
	70	!!
	71	INTEGER :: ji , jk ! dummy loop indices
[4161]	72	INTEGER :: ii, ij ! 2D corresponding indices to ji
[1572]	73	INTEGER :: iter
[825]	74
[4688]	75	REAL(wp) :: ztmelts ! local scalar
[6399]	76	REAL(wp) :: zdum
[1572]	77	REAL(wp) :: zfracs ! fractionation coefficient for bottom salt entrapment
[5407]	78	REAL(wp) :: zs_snic ! snow-ice salinity
[1572]	79	REAL(wp) :: zswi1 ! switch for computation of bottom salinity
	80	REAL(wp) :: zswi12 ! switch for computation of bottom salinity
	81	REAL(wp) :: zswi2 ! switch for computation of bottom salinity
	82	REAL(wp) :: zgrr ! bottom growth rate
[4688]	83	REAL(wp) :: zt_i_new ! bottom formation temperature
	84
	85	REAL(wp) :: zQm ! enthalpy exchanged with the ocean (J/m2), >0 towards the ocean
	86	REAL(wp) :: zEi ! specific enthalpy of sea ice (J/kg)
	87	REAL(wp) :: zEw ! specific enthalpy of exchanged water (J/kg)
	88	REAL(wp) :: zdE ! specific enthalpy difference (J/kg)
	89	REAL(wp) :: zfmdt ! exchange mass flux x time step (J/m2), >0 towards the ocean
	90	REAL(wp) :: zsstK ! SST in Kelvin
	91
	92	REAL(wp), POINTER, DIMENSION(:) :: zqprec ! energy of fallen snow (J.m-3)
	93	REAL(wp), POINTER, DIMENSION(:) :: zq_su ! heat for surface ablation (J.m-2)
	94	REAL(wp), POINTER, DIMENSION(:) :: zq_bo ! heat for bottom ablation (J.m-2)
	95	REAL(wp), POINTER, DIMENSION(:) :: zq_rema ! remaining heat at the end of the routine (J.m-2)
[5123]	96	REAL(wp), POINTER, DIMENSION(:) :: zf_tt ! Heat budget to determine melting or freezing(W.m-2)
[6399]	97	REAL(wp), POINTER, DIMENSION(:) :: zevap_rema ! remaining mass flux from sublimation (kg.m-2)
[3294]	98
[3625]	99	REAL(wp), POINTER, DIMENSION(:) :: zdh_s_mel ! snow melt
	100	REAL(wp), POINTER, DIMENSION(:) :: zdh_s_pre ! snow precipitation
	101	REAL(wp), POINTER, DIMENSION(:) :: zdh_s_sub ! snow sublimation
[3294]	102
	103	REAL(wp), POINTER, DIMENSION(:,:) :: zdeltah
[4688]	104	REAL(wp), POINTER, DIMENSION(:,:) :: zh_i ! ice layer thickness
[5202]	105	INTEGER , POINTER, DIMENSION(:,:) :: icount ! number of layers vanished by melting
[3294]	106
[4688]	107	REAL(wp), POINTER, DIMENSION(:) :: zqh_i ! total ice heat content (J.m-2)
[5407]	108	REAL(wp), POINTER, DIMENSION(:) :: zsnw ! distribution of snow after wind blowing
[3294]	109
[5123]	110	REAL(wp) :: zswitch_sal
[4161]	111
[3294]	112	! Heat conservation
[4688]	113	INTEGER :: num_iter_max
	114
[1572]	115	!!------------------------------------------------------------------
[825]	116
[5123]	117	! Discriminate between varying salinity (nn_icesal=2) and prescribed cases (other values)
	118	SELECT CASE( nn_icesal ) ! varying salinity or not
[4688]	119	CASE( 1, 3, 4 ) ; zswitch_sal = 0 ! prescribed salinity profile
	120	CASE( 2 ) ; zswitch_sal = 1 ! varying salinity profile
	121	END SELECT
[825]	122
[6399]	123	CALL wrk_alloc( jpij, zqprec, zq_su, zq_bo, zf_tt, zq_rema, zsnw, zevap_rema )
	124	CALL wrk_alloc( jpij, zdh_s_mel, zdh_s_pre, zdh_s_sub, zqh_i )
[5202]	125	CALL wrk_alloc( jpij, nlay_i, zdeltah, zh_i )
	126	CALL wrk_alloc( jpij, nlay_i, icount )
[5487]	127
[6399]	128	dh_i_surf (:) = 0._wp ; dh_i_bott (:) = 0._wp ; dh_snowice(:) = 0._wp ; dh_i_sub(:) = 0._wp
[4688]	129	dsm_i_se_1d(:) = 0._wp ; dsm_i_si_1d(:) = 0._wp
[2715]	130
[5487]	131	zqprec (:) = 0._wp ; zq_su (:) = 0._wp ; zq_bo (:) = 0._wp ; zf_tt(:) = 0._wp
[6399]	132	zq_rema (:) = 0._wp ; zsnw (:) = 0._wp ; zevap_rema(:) = 0._wp ;
[5487]	133	zdh_s_mel(:) = 0._wp ; zdh_s_pre(:) = 0._wp ; zdh_s_sub(:) = 0._wp ; zqh_i(:) = 0._wp
[4161]	134
[5487]	135	zdeltah(:,:) = 0._wp ; zh_i(:,:) = 0._wp
	136	icount (:,:) = 0
[4688]	137
[5487]	138
[5167]	139	! Initialize enthalpy at nlay_i+1
	140	DO ji = kideb, kiut
	141	q_i_1d(ji,nlay_i+1) = 0._wp
	142	END DO
	143
[4688]	144	! initialize layer thicknesses and enthalpies
	145	h_i_old (:,0:nlay_i+1) = 0._wp
	146	qh_i_old(:,0:nlay_i+1) = 0._wp
	147	DO jk = 1, nlay_i
	148	DO ji = kideb, kiut
[5123]	149	h_i_old (ji,jk) = ht_i_1d(ji) * r1_nlay_i
[4872]	150	qh_i_old(ji,jk) = q_i_1d(ji,jk) * h_i_old(ji,jk)
[4688]	151	ENDDO
	152	ENDDO
[921]	153	!
	154	!------------------------------------------------------------------------------!
[4688]	155	! 1) Calculate available heat for surface and bottom ablation !
[921]	156	!------------------------------------------------------------------------------!
	157	!
[2715]	158	DO ji = kideb, kiut
[6399]	159	zdum = qns_ice_1d(ji) + ( 1._wp - i0(ji) ) * qsr_ice_1d(ji) - fc_su(ji)
[4990]	160	zf_tt(ji) = fc_bo_i(ji) + fhtur_1d(ji) + fhld_1d(ji)
[4688]	161
[6399]	162	zq_su (ji) = MAX( 0._wp, zdum * rdt_ice ) * MAX( 0._wp , SIGN( 1._wp, t_su_1d(ji) - rt0 ) )
[4688]	163	zq_bo (ji) = MAX( 0._wp, zf_tt(ji) * rdt_ice )
	164	END DO
	165
[921]	166	!
	167	!------------------------------------------------------------------------------!
[4688]	168	! If snow temperature is above freezing point, then snow melts
	169	! (should not happen but sometimes it does)
[921]	170	!------------------------------------------------------------------------------!
[4688]	171	DO ji = kideb, kiut
[5123]	172	IF( t_s_1d(ji,1) > rt0 ) THEN !!! Internal melting
[4688]	173	! Contribution to heat flux to the ocean [W.m-2], < 0
[4872]	174	hfx_res_1d(ji) = hfx_res_1d(ji) + q_s_1d(ji,1) * ht_s_1d(ji) * a_i_1d(ji) * r1_rdtice
[4688]	175	! Contribution to mass flux
[4872]	176	wfx_snw_1d(ji) = wfx_snw_1d(ji) + rhosn * ht_s_1d(ji) * a_i_1d(ji) * r1_rdtice
[4688]	177	! updates
[4872]	178	ht_s_1d(ji) = 0._wp
	179	q_s_1d (ji,1) = 0._wp
[5123]	180	t_s_1d (ji,1) = rt0
[4688]	181	END IF
	182	END DO
	183
	184	!------------------------------------------------------------!
	185	! 2) Computing layer thicknesses and enthalpies. !
	186	!------------------------------------------------------------!
[921]	187	!
[825]	188	DO jk = 1, nlay_i
[2715]	189	DO ji = kideb, kiut
[5123]	190	zh_i(ji,jk) = ht_i_1d(ji) * r1_nlay_i
[4872]	191	zqh_i(ji) = zqh_i(ji) + q_i_1d(ji,jk) * zh_i(ji,jk)
[825]	192	END DO
	193	END DO
[921]	194	!
	195	!------------------------------------------------------------------------------\|
	196	! 3) Surface ablation and sublimation \|
	197	!------------------------------------------------------------------------------\|
	198	!
[834]	199	!-------------------------
	200	! 3.1 Snow precips / melt
	201	!-------------------------
[825]	202	! Snow accumulation in one thermodynamic time step
	203	! snowfall is partitionned between leads and ice
	204	! if snow fall was uniform, a fraction (1-at_i) would fall into leads
	205	! but because of the winds, more snow falls on leads than on sea ice
	206	! and a greater fraction (1-at_i)^beta of the total mass of snow
[834]	207	! (beta < 1) falls in leads.
[825]	208	! In reality, beta depends on wind speed,
	209	! and should decrease with increasing wind speed but here, it is
[834]	210	! considered as a constant. an average value is 0.66
[825]	211	! Martin Vancoppenolle, December 2006
	212
[5487]	213	CALL lim_thd_snwblow( 1. - at_i_1d(kideb:kiut), zsnw(kideb:kiut) ) ! snow distribution over ice after wind blowing
	214
[5167]	215	zdeltah(:,:) = 0._wp
[825]	216	DO ji = kideb, kiut
[4688]	217	!-----------
	218	! Snow fall
	219	!-----------
	220	! thickness change
[5407]	221	zdh_s_pre(ji) = zsnw(ji) * sprecip_1d(ji) * rdt_ice * r1_rhosn / at_i_1d(ji)
	222	! enthalpy of the precip (>0, J.m-3)
	223	zqprec (ji) = - qprec_ice_1d(ji)
[4688]	224	IF( sprecip_1d(ji) == 0._wp ) zqprec(ji) = 0._wp
	225	! heat flux from snow precip (>0, W.m-2)
[4872]	226	hfx_spr_1d(ji) = hfx_spr_1d(ji) + zdh_s_pre(ji) * a_i_1d(ji) * zqprec(ji) * r1_rdtice
[4688]	227	! mass flux, <0
[4872]	228	wfx_spr_1d(ji) = wfx_spr_1d(ji) - rhosn * a_i_1d(ji) * zdh_s_pre(ji) * r1_rdtice
[825]	229
[4688]	230	!---------------------
	231	! Melt of falling snow
	232	!---------------------
	233	! thickness change
[5134]	234	rswitch = MAX( 0._wp , SIGN( 1._wp , zqprec(ji) - epsi20 ) )
[5167]	235	zdeltah (ji,1) = - rswitch * zq_su(ji) / MAX( zqprec(ji) , epsi20 )
	236	zdeltah (ji,1) = MAX( - zdh_s_pre(ji), zdeltah(ji,1) ) ! bound melting
[4688]	237	! heat used to melt snow (W.m-2, >0)
[5167]	238	hfx_snw_1d(ji) = hfx_snw_1d(ji) - zdeltah(ji,1) * a_i_1d(ji) * zqprec(ji) * r1_rdtice
[4688]	239	! snow melting only = water into the ocean (then without snow precip), >0
[5167]	240	wfx_snw_1d(ji) = wfx_snw_1d(ji) - rhosn * a_i_1d(ji) * zdeltah(ji,1) * r1_rdtice
	241	! updates available heat + precipitations after melting
	242	zq_su (ji) = MAX( 0._wp , zq_su (ji) + zdeltah(ji,1) * zqprec(ji) )
	243	zdh_s_pre (ji) = zdh_s_pre(ji) + zdeltah(ji,1)
[4688]	244
[5167]	245	! update thickness
	246	ht_s_1d(ji) = MAX( 0._wp , ht_s_1d(ji) + zdh_s_pre(ji) )
[825]	247	END DO
	248
[5167]	249	! If heat still available (zq_su > 0), then melt more snow
	250	zdeltah(:,:) = 0._wp
[825]	251	DO jk = 1, nlay_s
	252	DO ji = kideb, kiut
[4688]	253	! thickness change
[4990]	254	rswitch = 1._wp - MAX( 0._wp, SIGN( 1._wp, - ht_s_1d(ji) ) )
[5134]	255	rswitch = rswitch * ( MAX( 0._wp, SIGN( 1._wp, q_s_1d(ji,jk) - epsi20 ) ) )
[4990]	256	zdeltah (ji,jk) = - rswitch * zq_su(ji) / MAX( q_s_1d(ji,jk), epsi20 )
[5167]	257	zdeltah (ji,jk) = MAX( zdeltah(ji,jk) , - ht_s_1d(ji) ) ! bound melting
[4688]	258	zdh_s_mel(ji) = zdh_s_mel(ji) + zdeltah(ji,jk)
	259	! heat used to melt snow(W.m-2, >0)
[4872]	260	hfx_snw_1d(ji) = hfx_snw_1d(ji) - zdeltah(ji,jk) * a_i_1d(ji) * q_s_1d(ji,jk) * r1_rdtice
[4688]	261	! snow melting only = water into the ocean (then without snow precip)
[4872]	262	wfx_snw_1d(ji) = wfx_snw_1d(ji) - rhosn * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice
[4688]	263	! updates available heat + thickness
[5123]	264	zq_su (ji) = MAX( 0._wp , zq_su (ji) + zdeltah(ji,jk) * q_s_1d(ji,jk) )
[4872]	265	ht_s_1d(ji) = MAX( 0._wp , ht_s_1d(ji) + zdeltah(ji,jk) )
[1572]	266	END DO
	267	END DO
[825]	268
[6399]	269	!------------------------------
	270	! 3.2 Sublimation (part1: snow)
	271	!------------------------------
[4688]	272	! qla_ice is always >=0 (upwards), heat goes to the atmosphere, therefore snow sublimates
[5167]	273	! clem comment: not counted in mass/heat exchange in limsbc since this is an exchange with atm. (not ocean)
	274	zdeltah(:,:) = 0._wp
[5407]	275	DO ji = kideb, kiut
[6399]	276	zdh_s_sub(ji) = MAX( - ht_s_1d(ji) , - evap_ice_1d(ji) * r1_rhosn * rdt_ice )
	277	! remaining evap in kg.m-2 (used for ice melting later on)
	278	zevap_rema(ji) = evap_ice_1d(ji) * rdt_ice + zdh_s_sub(ji) * rhosn
	279	! Heat flux by sublimation [W.m-2], < 0 (sublimate first snow that had fallen, then pre-existing snow)
[5407]	280	zdeltah(ji,1) = MAX( zdh_s_sub(ji), - zdh_s_pre(ji) )
	281	hfx_sub_1d(ji) = hfx_sub_1d(ji) + ( zdeltah(ji,1) * zqprec(ji) + ( zdh_s_sub(ji) - zdeltah(ji,1) ) * q_s_1d(ji,1) &
	282	& ) * a_i_1d(ji) * r1_rdtice
	283	! Mass flux by sublimation
	284	wfx_sub_1d(ji) = wfx_sub_1d(ji) - rhosn * a_i_1d(ji) * zdh_s_sub(ji) * r1_rdtice
	285	! new snow thickness
	286	ht_s_1d(ji) = MAX( 0._wp , ht_s_1d(ji) + zdh_s_sub(ji) )
	287	! update precipitations after sublimation and correct sublimation
	288	zdh_s_pre(ji) = zdh_s_pre(ji) + zdeltah(ji,1)
	289	zdh_s_sub(ji) = zdh_s_sub(ji) - zdeltah(ji,1)
	290	END DO
	291
[4688]	292	! --- Update snow diags --- !
[825]	293	DO ji = kideb, kiut
[5167]	294	dh_s_tot(ji) = zdh_s_mel(ji) + zdh_s_pre(ji) + zdh_s_sub(ji)
	295	END DO
[825]	296
[4688]	297	!-------------------------------------------
	298	! 3.3 Update temperature, energy
	299	!-------------------------------------------
	300	! new temp and enthalpy of the snow (remaining snow precip + remaining pre-existing snow)
[825]	301	DO jk = 1, nlay_s
	302	DO ji = kideb,kiut
[6399]	303	rswitch = MAX( 0._wp , SIGN( 1._wp, ht_s_1d(ji) - epsi20 ) )
	304	q_s_1d(ji,jk) = rswitch / MAX( ht_s_1d(ji), epsi20 ) * &
	305	& ( ( zdh_s_pre(ji) ) * zqprec(ji) + &
	306	& ( ht_s_1d(ji) - zdh_s_pre(ji) ) * rhosn * ( cpic * ( rt0 - t_s_1d(ji,jk) ) + lfus ) )
[825]	307	END DO
	308	END DO
	309
[4688]	310	!--------------------------
	311	! 3.4 Surface ice ablation
	312	!--------------------------
	313	zdeltah(:,:) = 0._wp ! important
	314	DO jk = 1, nlay_i
[5167]	315	DO ji = kideb, kiut
[5202]	316	ztmelts = - tmut * s_i_1d(ji,jk) + rt0 ! Melting point of layer k [K]
	317
	318	IF( t_i_1d(ji,jk) >= ztmelts ) THEN !!! Internal melting
[4688]	319
[5202]	320	zEi = - q_i_1d(ji,jk) * r1_rhoic ! Specific enthalpy of layer k [J/kg, <0]
	321	zdE = 0._wp ! Specific enthalpy difference (J/kg, <0)
	322	! set up at 0 since no energy is needed to melt water...(it is already melted)
	323	zdeltah(ji,jk) = MIN( 0._wp , - zh_i(ji,jk) ) ! internal melting occurs when the internal temperature is above freezing
	324	! this should normally not happen, but sometimes, heat diffusion leads to this
	325	zfmdt = - zdeltah(ji,jk) * rhoic ! Mass flux x time step > 0
	326
	327	dh_i_surf(ji) = dh_i_surf(ji) + zdeltah(ji,jk) ! Cumulate surface melt
	328
	329	zfmdt = - rhoic * zdeltah(ji,jk) ! Recompute mass flux [kg/m2, >0]
[4688]	330
[5202]	331	! Contribution to heat flux to the ocean [W.m-2], <0 (ice enthalpy zEi is "sent" to the ocean)
	332	hfx_res_1d(ji) = hfx_res_1d(ji) + zfmdt * a_i_1d(ji) * zEi * r1_rdtice
	333
	334	! Contribution to salt flux (clem: using sm_i_1d and not s_i_1d(jk) is ok)
	335	sfx_res_1d(ji) = sfx_res_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * sm_i_1d(ji) * r1_rdtice
	336
	337	! Contribution to mass flux
	338	wfx_res_1d(ji) = wfx_res_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice
[4688]	339
[5202]	340	ELSE !!! Surface melting
	341
	342	zEi = - q_i_1d(ji,jk) * r1_rhoic ! Specific enthalpy of layer k [J/kg, <0]
	343	zEw = rcp * ( ztmelts - rt0 ) ! Specific enthalpy of resulting meltwater [J/kg, <0]
	344	zdE = zEi - zEw ! Specific enthalpy difference < 0
	345
	346	zfmdt = - zq_su(ji) / zdE ! Mass flux to the ocean [kg/m2, >0]
	347
	348	zdeltah(ji,jk) = - zfmdt * r1_rhoic ! Melt of layer jk [m, <0]
	349
	350	zdeltah(ji,jk) = MIN( 0._wp , MAX( zdeltah(ji,jk) , - zh_i(ji,jk) ) ) ! Melt of layer jk cannot exceed the layer thickness [m, <0]
	351
	352	zq_su(ji) = MAX( 0._wp , zq_su(ji) - zdeltah(ji,jk) * rhoic * zdE ) ! update available heat
	353
	354	dh_i_surf(ji) = dh_i_surf(ji) + zdeltah(ji,jk) ! Cumulate surface melt
	355
	356	zfmdt = - rhoic * zdeltah(ji,jk) ! Recompute mass flux [kg/m2, >0]
	357
	358	zQm = zfmdt * zEw ! Energy of the melt water sent to the ocean [J/m2, <0]
	359
[6399]	360	! Contribution to salt flux >0 (clem: using sm_i_1d and not s_i_1d(jk) is ok)
[5202]	361	sfx_sum_1d(ji) = sfx_sum_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * sm_i_1d(ji) * r1_rdtice
	362
	363	! Contribution to heat flux [W.m-2], < 0
	364	hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice
	365
	366	! Total heat flux used in this process [W.m-2], > 0
	367	hfx_sum_1d(ji) = hfx_sum_1d(ji) - zfmdt * a_i_1d(ji) * zdE * r1_rdtice
	368
	369	! Contribution to mass flux
	370	wfx_sum_1d(ji) = wfx_sum_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice
	371
[5167]	372	END IF
[6399]	373	! ----------------------
	374	! Sublimation part2: ice
	375	! ----------------------
	376	zdum = MAX( - ( zh_i(ji,jk) + zdeltah(ji,jk) ) , - zevap_rema(ji) * r1_rhoic )
	377	zdeltah(ji,jk) = zdeltah(ji,jk) + zdum
	378	dh_i_sub(ji) = dh_i_sub(ji) + zdum
	379	! Salt flux > 0 (clem2016: flux is sent to the ocean for simplicity but salt should remain in the ice except if all ice is melted.
	380	! It must be corrected at some point)
	381	sfx_sub_1d(ji) = sfx_sub_1d(ji) - rhoic * a_i_1d(ji) * zdum * sm_i_1d(ji) * r1_rdtice
	382	! Heat flux [W.m-2], < 0
	383	hfx_sub_1d(ji) = hfx_sub_1d(ji) + zdum * q_i_1d(ji,jk) * a_i_1d(ji) * r1_rdtice
	384	! Mass flux > 0
	385	wfx_sub_1d(ji) = wfx_sub_1d(ji) - rhoic * a_i_1d(ji) * zdum * r1_rdtice
	386	! update remaining mass flux
	387	zevap_rema(ji) = zevap_rema(ji) + zdum * rhoic
	388
[4688]	389	! record which layers have disappeared (for bottom melting)
	390	! => icount=0 : no layer has vanished
	391	! => icount=5 : 5 layers have vanished
[5202]	392	rswitch = MAX( 0._wp , SIGN( 1._wp , - ( zh_i(ji,jk) + zdeltah(ji,jk) ) ) )
	393	icount(ji,jk) = NINT( rswitch )
	394	zh_i(ji,jk) = MAX( 0._wp , zh_i(ji,jk) + zdeltah(ji,jk) )
[6399]	395
[4688]	396	! update heat content (J.m-2) and layer thickness
[4872]	397	qh_i_old(ji,jk) = qh_i_old(ji,jk) + zdeltah(ji,jk) * q_i_1d(ji,jk)
[4688]	398	h_i_old (ji,jk) = h_i_old (ji,jk) + zdeltah(ji,jk)
[825]	399	END DO
[921]	400	END DO
[4688]	401	! update ice thickness
	402	DO ji = kideb, kiut
[6399]	403	ht_i_1d(ji) = MAX( 0._wp , ht_i_1d(ji) + dh_i_surf(ji) + dh_i_sub(ji) )
[4688]	404	END DO
[825]	405
[6399]	406	! remaining "potential" evap is sent to ocean
	407	DO ji = kideb, kiut
	408	ii = MOD( npb(ji) - 1, jpi ) + 1 ; ij = ( npb(ji) - 1 ) / jpi + 1
	409	wfx_err_sub(ii,ij) = wfx_err_sub(ii,ij) - zevap_rema(ji) * a_i_1d(ji) * r1_rdtice ! <=0 (net evap for the ocean in kg.m-2.s-1)
	410	END DO
	411
[921]	412	!
	413	!------------------------------------------------------------------------------!
	414	! 4) Basal growth / melt !
	415	!------------------------------------------------------------------------------!
	416	!
[4688]	417	!------------------
	418	! 4.1 Basal growth
	419	!------------------
	420	! Basal growth is driven by heat imbalance at the ice-ocean interface,
	421	! between the inner conductive flux (fc_bo_i), from the open water heat flux
	422	! (fhld) and the turbulent ocean flux (fhtur).
	423	! fc_bo_i is positive downwards. fhtur and fhld are positive to the ice
[825]	424
[4688]	425	! If salinity varies in time, an iterative procedure is required, because
	426	! the involved quantities are inter-dependent.
	427	! Basal growth (dh_i_bott) depends upon new ice specific enthalpy (zEi),
	428	! which depends on forming ice salinity (s_i_new), which depends on dh/dt (dh_i_bott)
	429	! -> need for an iterative procedure, which converges quickly
	430
[5167]	431	num_iter_max = 1
	432	IF( nn_icesal == 2 ) num_iter_max = 5
[825]	433
[4688]	434	! Iterative procedure
	435	DO iter = 1, num_iter_max
	436	DO ji = kideb, kiut
	437	IF( zf_tt(ji) < 0._wp ) THEN
[825]	438
[4688]	439	! New bottom ice salinity (Cox & Weeks, JGR88 )
	440	!--- zswi1 if dh/dt < 2.0e-8
	441	!--- zswi12 if 2.0e-8 < dh/dt < 3.6e-7
	442	!--- zswi2 if dh/dt > 3.6e-7
	443	zgrr = MIN( 1.0e-3, MAX ( dh_i_bott(ji) * r1_rdtice , epsi10 ) )
	444	zswi2 = MAX( 0._wp , SIGN( 1._wp , zgrr - 3.6e-7 ) )
	445	zswi12 = MAX( 0._wp , SIGN( 1._wp , zgrr - 2.0e-8 ) ) * ( 1.0 - zswi2 )
	446	zswi1 = 1. - zswi2 * zswi12
	447	zfracs = MIN ( zswi1 * 0.12 + zswi12 * ( 0.8925 + 0.0568 * LOG( 100.0 * zgrr ) ) &
	448	& + zswi2 * 0.26 / ( 0.26 + 0.74 * EXP ( - 724300.0 * zgrr ) ) , 0.5 )
[825]	449
[4688]	450	ii = MOD( npb(ji) - 1, jpi ) + 1 ; ij = ( npb(ji) - 1 ) / jpi + 1
[825]	451
[4688]	452	s_i_new(ji) = zswitch_sal * zfracs * sss_m(ii,ij) & ! New ice salinity
[4872]	453	+ ( 1. - zswitch_sal ) * sm_i_1d(ji)
[4688]	454	! New ice growth
[5123]	455	ztmelts = - tmut * s_i_new(ji) + rt0 ! New ice melting point (K)
[825]	456
[4872]	457	zt_i_new = zswitch_sal * t_bo_1d(ji) + ( 1. - zswitch_sal) * t_i_1d(ji, nlay_i)
[4688]	458
	459	zEi = cpic * ( zt_i_new - ztmelts ) & ! Specific enthalpy of forming ice (J/kg, <0)
[5123]	460	& - lfus * ( 1.0 - ( ztmelts - rt0 ) / ( zt_i_new - rt0 ) ) &
	461	& + rcp * ( ztmelts-rt0 )
[4688]	462
[4872]	463	zEw = rcp * ( t_bo_1d(ji) - rt0 ) ! Specific enthalpy of seawater (J/kg, < 0)
[4688]	464
	465	zdE = zEi - zEw ! Specific enthalpy difference (J/kg, <0)
	466
	467	dh_i_bott(ji) = rdt_ice * MAX( 0._wp , zf_tt(ji) / ( zdE * rhoic ) )
	468
[4872]	469	q_i_1d(ji,nlay_i+1) = -zEi * rhoic ! New ice energy of melting (J/m3, >0)
[4688]	470
[5134]	471	ENDIF
	472	END DO
	473	END DO
[4688]	474
	475	! Contribution to Energy and Salt Fluxes
[825]	476	DO ji = kideb, kiut
[4688]	477	IF( zf_tt(ji) < 0._wp ) THEN
	478	! New ice growth
	479
	480	zfmdt = - rhoic * dh_i_bott(ji) ! Mass flux x time step (kg/m2, < 0)
	481
[5123]	482	ztmelts = - tmut * s_i_new(ji) + rt0 ! New ice melting point (K)
[4688]	483
[4872]	484	zt_i_new = zswitch_sal * t_bo_1d(ji) + ( 1. - zswitch_sal) * t_i_1d(ji, nlay_i)
[4688]	485
	486	zEi = cpic * ( zt_i_new - ztmelts ) & ! Specific enthalpy of forming ice (J/kg, <0)
[5123]	487	& - lfus * ( 1.0 - ( ztmelts - rt0 ) / ( zt_i_new - rt0 ) ) &
	488	& + rcp * ( ztmelts-rt0 )
[4688]	489
[4872]	490	zEw = rcp * ( t_bo_1d(ji) - rt0 ) ! Specific enthalpy of seawater (J/kg, < 0)
[4688]	491
	492	zdE = zEi - zEw ! Specific enthalpy difference (J/kg, <0)
	493
	494	! Contribution to heat flux to the ocean [W.m-2], >0
[4872]	495	hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice
[4688]	496
	497	! Total heat flux used in this process [W.m-2], <0
[4872]	498	hfx_bog_1d(ji) = hfx_bog_1d(ji) - zfmdt * a_i_1d(ji) * zdE * r1_rdtice
[4688]	499
	500	! Contribution to salt flux, <0
[5167]	501	sfx_bog_1d(ji) = sfx_bog_1d(ji) - rhoic * a_i_1d(ji) * dh_i_bott(ji) * s_i_new(ji) * r1_rdtice
[4688]	502
	503	! Contribution to mass flux, <0
[4872]	504	wfx_bog_1d(ji) = wfx_bog_1d(ji) - rhoic * a_i_1d(ji) * dh_i_bott(ji) * r1_rdtice
[4688]	505
	506	! update heat content (J.m-2) and layer thickness
[4872]	507	qh_i_old(ji,nlay_i+1) = qh_i_old(ji,nlay_i+1) + dh_i_bott(ji) * q_i_1d(ji,nlay_i+1)
[4688]	508	h_i_old (ji,nlay_i+1) = h_i_old (ji,nlay_i+1) + dh_i_bott(ji)
[825]	509	ENDIF
	510	END DO
	511
[4688]	512	!----------------
	513	! 4.2 Basal melt
	514	!----------------
	515	zdeltah(:,:) = 0._wp ! important
[825]	516	DO jk = nlay_i, 1, -1
	517	DO ji = kideb, kiut
[5202]	518	IF( zf_tt(ji) > 0._wp .AND. jk > icount(ji,jk) ) THEN ! do not calculate where layer has already disappeared by surface melting
[825]	519
[5123]	520	ztmelts = - tmut * s_i_1d(ji,jk) + rt0 ! Melting point of layer jk (K)
[825]	521
[4872]	522	IF( t_i_1d(ji,jk) >= ztmelts ) THEN !!! Internal melting
[825]	523
[5123]	524	zEi = - q_i_1d(ji,jk) * r1_rhoic ! Specific enthalpy of melting ice (J/kg, <0)
[4688]	525	zdE = 0._wp ! Specific enthalpy difference (J/kg, <0)
	526	! set up at 0 since no energy is needed to melt water...(it is already melted)
[5202]	527	zdeltah (ji,jk) = MIN( 0._wp , - zh_i(ji,jk) ) ! internal melting occurs when the internal temperature is above freezing
	528	! this should normally not happen, but sometimes, heat diffusion leads to this
[4161]	529
[4688]	530	dh_i_bott (ji) = dh_i_bott(ji) + zdeltah(ji,jk)
[825]	531
[5202]	532	zfmdt = - zdeltah(ji,jk) * rhoic ! Mass flux x time step > 0
[825]	533
[4688]	534	! Contribution to heat flux to the ocean [W.m-2], <0 (ice enthalpy zEi is "sent" to the ocean)
[4872]	535	hfx_res_1d(ji) = hfx_res_1d(ji) + zfmdt * a_i_1d(ji) * zEi * r1_rdtice
[825]	536
[4872]	537	! Contribution to salt flux (clem: using sm_i_1d and not s_i_1d(jk) is ok)
[5167]	538	sfx_res_1d(ji) = sfx_res_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * sm_i_1d(ji) * r1_rdtice
[4688]	539
	540	! Contribution to mass flux
[4872]	541	wfx_res_1d(ji) = wfx_res_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice
[825]	542
[4688]	543	! update heat content (J.m-2) and layer thickness
[4872]	544	qh_i_old(ji,jk) = qh_i_old(ji,jk) + zdeltah(ji,jk) * q_i_1d(ji,jk)
[4688]	545	h_i_old (ji,jk) = h_i_old (ji,jk) + zdeltah(ji,jk)
[825]	546
[4688]	547	ELSE !!! Basal melting
[825]	548
[5202]	549	zEi = - q_i_1d(ji,jk) * r1_rhoic ! Specific enthalpy of melting ice (J/kg, <0)
	550	zEw = rcp * ( ztmelts - rt0 ) ! Specific enthalpy of meltwater (J/kg, <0)
	551	zdE = zEi - zEw ! Specific enthalpy difference (J/kg, <0)
[825]	552
[5202]	553	zfmdt = - zq_bo(ji) / zdE ! Mass flux x time step (kg/m2, >0)
[825]	554
[5202]	555	zdeltah(ji,jk) = - zfmdt * r1_rhoic ! Gross thickness change
[4688]	556
[5202]	557	zdeltah(ji,jk) = MIN( 0._wp , MAX( zdeltah(ji,jk), - zh_i(ji,jk) ) ) ! bound thickness change
[4688]	558
[5202]	559	zq_bo(ji) = MAX( 0._wp , zq_bo(ji) - zdeltah(ji,jk) * rhoic * zdE ) ! update available heat. MAX is necessary for roundup errors
[4688]	560
[5202]	561	dh_i_bott(ji) = dh_i_bott(ji) + zdeltah(ji,jk) ! Update basal melt
[4688]	562
[5202]	563	zfmdt = - zdeltah(ji,jk) * rhoic ! Mass flux x time step > 0
[4688]	564
[5202]	565	zQm = zfmdt * zEw ! Heat exchanged with ocean
[4688]	566
	567	! Contribution to heat flux to the ocean [W.m-2], <0
[5202]	568	hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice
[4688]	569
[4872]	570	! Contribution to salt flux (clem: using sm_i_1d and not s_i_1d(jk) is ok)
[5202]	571	sfx_bom_1d(ji) = sfx_bom_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * sm_i_1d(ji) * r1_rdtice
[4688]	572
	573	! Total heat flux used in this process [W.m-2], >0
[5202]	574	hfx_bom_1d(ji) = hfx_bom_1d(ji) - zfmdt * a_i_1d(ji) * zdE * r1_rdtice
[4688]	575
	576	! Contribution to mass flux
[5202]	577	wfx_bom_1d(ji) = wfx_bom_1d(ji) - rhoic * a_i_1d(ji) * zdeltah(ji,jk) * r1_rdtice
[4688]	578
	579	! update heat content (J.m-2) and layer thickness
[4872]	580	qh_i_old(ji,jk) = qh_i_old(ji,jk) + zdeltah(ji,jk) * q_i_1d(ji,jk)
[4688]	581	h_i_old (ji,jk) = h_i_old (ji,jk) + zdeltah(ji,jk)
	582	ENDIF
	583
	584	ENDIF
[5123]	585	END DO
	586	END DO
[4688]	587
[825]	588	!-------------------------------------------
[4688]	589	! Update temperature, energy
[825]	590	!-------------------------------------------
	591	DO ji = kideb, kiut
[4872]	592	ht_i_1d(ji) = MAX( 0._wp , ht_i_1d(ji) + dh_i_bott(ji) )
[4688]	593	END DO
[825]	594
[4688]	595	!-------------------------------------------
	596	! 5. What to do with remaining energy
	597	!-------------------------------------------
	598	! If heat still available for melting and snow remains, then melt more snow
	599	!-------------------------------------------
	600	zdeltah(:,:) = 0._wp ! important
	601	DO ji = kideb, kiut
	602	zq_rema(ji) = zq_su(ji) + zq_bo(ji)
[5128]	603	rswitch = 1._wp - MAX( 0._wp, SIGN( 1._wp, - ht_s_1d(ji) ) ) ! =1 if snow
[5134]	604	rswitch = rswitch * MAX( 0._wp, SIGN( 1._wp, q_s_1d(ji,1) - epsi20 ) )
	605	zdeltah (ji,1) = - rswitch * zq_rema(ji) / MAX( q_s_1d(ji,1), epsi20 )
[5128]	606	zdeltah (ji,1) = MIN( 0._wp , MAX( zdeltah(ji,1) , - ht_s_1d(ji) ) ) ! bound melting
	607	dh_s_tot (ji) = dh_s_tot(ji) + zdeltah(ji,1)
	608	ht_s_1d (ji) = ht_s_1d(ji) + zdeltah(ji,1)
	609
[5134]	610	zq_rema(ji) = zq_rema(ji) + zdeltah(ji,1) * q_s_1d(ji,1) ! update available heat (J.m-2)
[5128]	611	! heat used to melt snow
[5134]	612	hfx_snw_1d(ji) = hfx_snw_1d(ji) - zdeltah(ji,1) * a_i_1d(ji) * q_s_1d(ji,1) * r1_rdtice ! W.m-2 (>0)
[5128]	613	! Contribution to mass flux
	614	wfx_snw_1d(ji) = wfx_snw_1d(ji) - rhosn * a_i_1d(ji) * zdeltah(ji,1) * r1_rdtice
	615	!
[4688]	616	ii = MOD( npb(ji) - 1, jpi ) + 1 ; ij = ( npb(ji) - 1 ) / jpi + 1
	617	! Remaining heat flux (W.m-2) is sent to the ocean heat budget
[5123]	618	hfx_out(ii,ij) = hfx_out(ii,ij) + ( zq_rema(ji) * a_i_1d(ji) ) * r1_rdtice
[825]	619
[5128]	620	IF( ln_icectl .AND. zq_rema(ji) < 0. .AND. lwp ) WRITE(numout,*) 'ALERTE zq_rema <0 = ', zq_rema(ji)
[4688]	621	END DO
	622
[921]	623	!
	624	!------------------------------------------------------------------------------\|
	625	! 6) Snow-Ice formation \|
	626	!------------------------------------------------------------------------------\|
[1572]	627	! When snow load excesses Archimede's limit, snow-ice interface goes down under sea-level,
	628	! flooding of seawater transforms snow into ice dh_snowice is positive for the ice
[825]	629	DO ji = kideb, kiut
[1572]	630	!
[4872]	631	dh_snowice(ji) = MAX( 0._wp , ( rhosn * ht_s_1d(ji) + (rhoic-rau0) * ht_i_1d(ji) ) / ( rhosn+rau0-rhoic ) )
[825]	632
[5167]	633	ht_i_1d(ji) = ht_i_1d(ji) + dh_snowice(ji)
	634	ht_s_1d(ji) = ht_s_1d(ji) - dh_snowice(ji)
[825]	635
[4688]	636	! Salinity of snow ice
	637	ii = MOD( npb(ji) - 1, jpi ) + 1 ; ij = ( npb(ji) - 1 ) / jpi + 1
[5123]	638	zs_snic = zswitch_sal * sss_m(ii,ij) * ( rhoic - rhosn ) * r1_rhoic + ( 1. - zswitch_sal ) * sm_i_1d(ji)
[825]	639
	640	! entrapment during snow ice formation
[5134]	641	! new salinity difference stored (to be used in limthd_sal.F90)
[5123]	642	IF ( nn_icesal == 2 ) THEN
[5134]	643	rswitch = MAX( 0._wp , SIGN( 1._wp , ht_i_1d(ji) - epsi20 ) )
[4161]	644	! salinity dif due to snow-ice formation
[5134]	645	dsm_i_si_1d(ji) = ( zs_snic - sm_i_1d(ji) ) * dh_snowice(ji) / MAX( ht_i_1d(ji), epsi20 ) * rswitch
[4161]	646	! salinity dif due to bottom growth
[4688]	647	IF ( zf_tt(ji) < 0._wp ) THEN
[5134]	648	dsm_i_se_1d(ji) = ( s_i_new(ji) - sm_i_1d(ji) ) * dh_i_bott(ji) / MAX( ht_i_1d(ji), epsi20 ) * rswitch
[4161]	649	ENDIF
	650	ENDIF
[825]	651
[4688]	652	! Contribution to energy flux to the ocean [J/m2], >0 (if sst<0)
	653	ii = MOD( npb(ji) - 1, jpi ) + 1 ; ij = ( npb(ji) - 1 ) / jpi + 1
	654	zfmdt = ( rhosn - rhoic ) * MAX( dh_snowice(ji), 0._wp ) ! <0
	655	zsstK = sst_m(ii,ij) + rt0
	656	zEw = rcp * ( zsstK - rt0 )
	657	zQm = zfmdt * zEw
	658
	659	! Contribution to heat flux
[4872]	660	hfx_thd_1d(ji) = hfx_thd_1d(ji) + zfmdt * a_i_1d(ji) * zEw * r1_rdtice
[825]	661
[4688]	662	! Contribution to salt flux
[4872]	663	sfx_sni_1d(ji) = sfx_sni_1d(ji) + sss_m(ii,ij) * a_i_1d(ji) * zfmdt * r1_rdtice
[4688]	664
	665	! Contribution to mass flux
	666	! All snow is thrown in the ocean, and seawater is taken to replace the volume
[4872]	667	wfx_sni_1d(ji) = wfx_sni_1d(ji) - a_i_1d(ji) * dh_snowice(ji) * rhoic * r1_rdtice
	668	wfx_snw_1d(ji) = wfx_snw_1d(ji) + a_i_1d(ji) * dh_snowice(ji) * rhosn * r1_rdtice
[4688]	669
	670	! update heat content (J.m-2) and layer thickness
[4872]	671	qh_i_old(ji,0) = qh_i_old(ji,0) + dh_snowice(ji) * q_s_1d(ji,1) + zfmdt * zEw
[4688]	672	h_i_old (ji,0) = h_i_old (ji,0) + dh_snowice(ji)
	673
[5134]	674	END DO
[825]	675
[2715]	676	!
[4688]	677	!-------------------------------------------
	678	! Update temperature, energy
	679	!-------------------------------------------
	680	DO ji = kideb, kiut
[4990]	681	rswitch = 1.0 - MAX( 0._wp , SIGN( 1._wp , - ht_i_1d(ji) ) )
[5123]	682	t_su_1d(ji) = rswitch * t_su_1d(ji) + ( 1.0 - rswitch ) * rt0
[5134]	683	END DO
[4688]	684
	685	DO jk = 1, nlay_s
	686	DO ji = kideb,kiut
	687	! mask enthalpy
[5134]	688	rswitch = 1._wp - MAX( 0._wp , SIGN( 1._wp, - ht_s_1d(ji) ) )
	689	q_s_1d(ji,jk) = rswitch * q_s_1d(ji,jk)
[4872]	690	! recalculate t_s_1d from q_s_1d
[5134]	691	t_s_1d(ji,jk) = rt0 + rswitch * ( - q_s_1d(ji,jk) / ( rhosn * cpic ) + lfus / cpic )
[4688]	692	END DO
	693	END DO
[5134]	694
	695	! --- ensure that a_i = 0 where ht_i = 0 ---
	696	WHERE( ht_i_1d == 0._wp ) a_i_1d = 0._wp
[5123]	697
[6399]	698	CALL wrk_dealloc( jpij, zqprec, zq_su, zq_bo, zf_tt, zq_rema, zsnw, zevap_rema )
	699	CALL wrk_dealloc( jpij, zdh_s_mel, zdh_s_pre, zdh_s_sub, zqh_i )
[5202]	700	CALL wrk_dealloc( jpij, nlay_i, zdeltah, zh_i )
	701	CALL wrk_dealloc( jpij, nlay_i, icount )
[2715]	702	!
[4161]	703	!
[921]	704	END SUBROUTINE lim_thd_dh
[5407]	705
	706
	707	!!--------------------------------------------------------------------------
	708	!! INTERFACE lim_thd_snwblow
	709	!! ** Purpose : Compute distribution of precip over the ice
	710	!!--------------------------------------------------------------------------
	711	SUBROUTINE lim_thd_snwblow_2d( pin, pout )
[5487]	712	REAL(wp), DIMENSION(:,:), INTENT(in ) :: pin ! previous fraction lead ( pfrld or (1. - a_i_b) )
	713	REAL(wp), DIMENSION(:,:), INTENT(inout) :: pout
[5407]	714	pout = ( 1._wp - ( pin )**rn_betas )
	715	END SUBROUTINE lim_thd_snwblow_2d
	716
	717	SUBROUTINE lim_thd_snwblow_1d( pin, pout )
[5487]	718	REAL(wp), DIMENSION(:), INTENT(in ) :: pin
	719	REAL(wp), DIMENSION(:), INTENT(inout) :: pout
[5407]	720	pout = ( 1._wp - ( pin )**rn_betas )
	721	END SUBROUTINE lim_thd_snwblow_1d
	722
[1572]	723
[825]	724	#else
[1572]	725	!!----------------------------------------------------------------------
	726	!! Default option NO LIM3 sea-ice model
	727	!!----------------------------------------------------------------------
[825]	728	CONTAINS
	729	SUBROUTINE lim_thd_dh ! Empty routine
	730	END SUBROUTINE lim_thd_dh
	731	#endif
[1572]	732
	733	!!======================================================================
[921]	734	END MODULE limthd_dh

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