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icedyn_rhg_evp.F90 in NEMO/branches/2020/dev_r13383_HPC-02_Daley_Tiling/src/ICE – NEMO

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source: NEMO/branches/2020/dev_r13383_HPC-02_Daley_Tiling/src/ICE/icedyn_rhg_evp.F90 @ 13553

Last change on this file since 13553 was 13553, checked in by hadcv, 4 years ago
Merge in trunk up to [13550]
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1	MODULE icedyn_rhg_evp
2	!!======================================================================
3	!! * MODULE icedyn_rhg_evp *
4	!! Sea-Ice dynamics : rheology Elasto-Viscous-Plastic
5	!!======================================================================
6	!! History : - ! 2007-03 (M.A. Morales Maqueda, S. Bouillon) Original code
7	!! 3.0 ! 2008-03 (M. Vancoppenolle) adaptation to new model
8	!! - ! 2008-11 (M. Vancoppenolle, S. Bouillon, Y. Aksenov) add surface tilt in ice rheolohy
9	!! 3.3 ! 2009-05 (G.Garric) addition of the evp case
10	!! 3.4 ! 2011-01 (A. Porter) dynamical allocation
11	!! 3.5 ! 2012-08 (R. Benshila) AGRIF
12	!! 3.6 ! 2016-06 (C. Rousset) Rewriting + landfast ice + mEVP (Bouillon 2013)
13	!! 3.7 ! 2017 (C. Rousset) add aEVP (Kimmritz 2016-2017)
14	!! 4.0 ! 2018 (many people) SI3 [aka Sea Ice cube]
15	!!----------------------------------------------------------------------
16	#if defined key_si3
17	!!----------------------------------------------------------------------
18	!! 'key_si3' SI3 sea-ice model
19	!!----------------------------------------------------------------------
20	!! ice_dyn_rhg_evp : computes ice velocities from EVP rheology
21	!! rhg_evp_rst : read/write EVP fields in ice restart
22	!!----------------------------------------------------------------------
23	USE phycst ! Physical constant
24	USE dom_oce ! Ocean domain
25	USE sbc_oce , ONLY : ln_ice_embd, nn_fsbc, ssh_m
26	USE sbc_ice , ONLY : utau_ice, vtau_ice, snwice_mass, snwice_mass_b
27	USE ice ! sea-ice: ice variables
28	USE icevar ! ice_var_sshdyn
29	USE icedyn_rdgrft ! sea-ice: ice strength
30	USE bdy_oce , ONLY : ln_bdy
31	USE bdyice
32	#if defined key_agrif
33	USE agrif_ice_interp
34	#endif
35	!
36	USE in_out_manager ! I/O manager
37	USE iom ! I/O manager library
38	USE lib_mpp ! MPP library
39	USE lib_fortran ! fortran utilities (glob_sum + no signed zero)
40	USE lbclnk ! lateral boundary conditions (or mpp links)
41	USE prtctl ! Print control
42
43	USE netcdf ! NetCDF library for convergence test
44	IMPLICIT NONE
45	PRIVATE
46
47	PUBLIC ice_dyn_rhg_evp ! called by icedyn_rhg.F90
48	PUBLIC rhg_evp_rst ! called by icedyn_rhg.F90
49
50	!! * Substitutions
51	# include "do_loop_substitute.h90"
52	# include "domzgr_substitute.h90"
53
54	!! for convergence tests
55	INTEGER :: ncvgid ! netcdf file id
56	INTEGER :: nvarid ! netcdf variable id
57	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zmsk00, zmsk15
58	!!----------------------------------------------------------------------
59	!! NEMO/ICE 4.0 , NEMO Consortium (2018)
60	!! $Id$
61	!! Software governed by the CeCILL license (see ./LICENSE)
62	!!----------------------------------------------------------------------
63	CONTAINS
64
65	SUBROUTINE ice_dyn_rhg_evp( kt, Kmm, pstress1_i, pstress2_i, pstress12_i, pshear_i, pdivu_i, pdelta_i )
66	!!-------------------------------------------------------------------
67	!! * SUBROUTINE ice_dyn_rhg_evp *
68	!! EVP-C-grid
69	!!
70	!! ** purpose : determines sea ice drift from wind stress, ice-ocean
71	!! stress and sea-surface slope. Ice-ice interaction is described by
72	!! a non-linear elasto-viscous-plastic (EVP) law including shear
73	!! strength and a bulk rheology (Hunke and Dukowicz, 2002).
74	!!
75	!! The points in the C-grid look like this, dear reader
76	!!
77	!! (ji,jj)
78	!! \|
79	!! \|
80	!! (ji-1,jj) \| (ji,jj)
81	!! ---------
82	!! \| \|
83	!! \| (ji,jj) \|------(ji,jj)
84	!! \| \|
85	!! ---------
86	!! (ji-1,jj-1) (ji,jj-1)
87	!!
88	!! ** Inputs : - wind forcing (stress), oceanic currents
89	!! ice total volume (vt_i) per unit area
90	!! snow total volume (vt_s) per unit area
91	!!
92	!! ** Action : - compute u_ice, v_ice : the components of the
93	!! sea-ice velocity vector
94	!! - compute delta_i, shear_i, divu_i, which are inputs
95	!! of the ice thickness distribution
96	!!
97	!! ** Steps : 0) compute mask at F point
98	!! 1) Compute ice snow mass, ice strength
99	!! 2) Compute wind, oceanic stresses, mass terms and
100	!! coriolis terms of the momentum equation
101	!! 3) Solve the momentum equation (iterative procedure)
102	!! 4) Recompute delta, shear and divergence
103	!! (which are inputs of the ITD) & store stress
104	!! for the next time step
105	!! 5) Diagnostics including charge ellipse
106	!!
107	!! ** Notes : There is the possibility to use aEVP from the nice work of Kimmritz et al. (2016 & 2017)
108	!! by setting up ln_aEVP=T (i.e. changing alpha and beta parameters).
109	!! This is an upgraded version of mEVP from Bouillon et al. 2013
110	!! (i.e. more stable and better convergence)
111	!!
112	!! References : Hunke and Dukowicz, JPO97
113	!! Bouillon et al., Ocean Modelling 2009
114	!! Bouillon et al., Ocean Modelling 2013
115	!! Kimmritz et al., Ocean Modelling 2016 & 2017
116	!!-------------------------------------------------------------------
117	INTEGER , INTENT(in ) :: kt ! time step
118	INTEGER , INTENT(in ) :: Kmm ! ocean time level index
119	REAL(wp), DIMENSION(:,:), INTENT(inout) :: pstress1_i, pstress2_i, pstress12_i !
120	REAL(wp), DIMENSION(:,:), INTENT( out) :: pshear_i , pdivu_i , pdelta_i !
121	!!
122	INTEGER :: ji, jj ! dummy loop indices
123	INTEGER :: jter ! local integers
124	!
125	REAL(wp) :: zrhoco ! rho0 * rn_cio
126	REAL(wp) :: zdtevp, z1_dtevp ! time step for subcycling
127	REAL(wp) :: ecc2, z1_ecc2 ! square of yield ellipse eccenticity
128	REAL(wp) :: zalph1, z1_alph1, zalph2, z1_alph2 ! alpha coef from Bouillon 2009 or Kimmritz 2017
129	REAl(wp) :: zbetau, zbetav
130	REAL(wp) :: zm1, zm2, zm3, zmassU, zmassV, zvU, zvV ! ice/snow mass and volume
131	REAL(wp) :: zp_delf, zds2, zdt, zdt2, zdiv, zdiv2 ! temporary scalars
132	REAL(wp) :: zTauO, zTauB, zRHS, zvel ! temporary scalars
133	REAL(wp) :: zkt ! isotropic tensile strength for landfast ice
134	REAL(wp) :: zvCr ! critical ice volume above which ice is landfast
135	!
136	REAL(wp) :: zintb, zintn ! dummy argument
137	REAL(wp) :: zfac_x, zfac_y
138	REAL(wp) :: zshear, zdum1, zdum2
139	!
140	REAL(wp), DIMENSION(jpi,jpj) :: zdelta, zp_delt ! delta and P/delta at T points
141	REAL(wp), DIMENSION(jpi,jpj) :: zbeta ! beta coef from Kimmritz 2017
142	!
143	REAL(wp), DIMENSION(jpi,jpj) :: zdt_m ! (dt / ice-snow_mass) on T points
144	REAL(wp), DIMENSION(jpi,jpj) :: zaU , zaV ! ice fraction on U/V points
145	REAL(wp), DIMENSION(jpi,jpj) :: zmU_t, zmV_t ! (ice-snow_mass / dt) on U/V points
146	REAL(wp), DIMENSION(jpi,jpj) :: zmf ! coriolis parameter at T points
147	REAL(wp), DIMENSION(jpi,jpj) :: v_oceU, u_oceV, v_iceU, u_iceV ! ocean/ice u/v component on V/U points
148	!
149	REAL(wp), DIMENSION(jpi,jpj) :: zds ! shear
150	REAL(wp), DIMENSION(jpi,jpj) :: zs1, zs2, zs12 ! stress tensor components
151	REAL(wp), DIMENSION(jpi,jpj) :: zsshdyn ! array used for the calculation of ice surface slope:
152	! ! ocean surface (ssh_m) if ice is not embedded
153	! ! ice bottom surface if ice is embedded
154	REAL(wp), DIMENSION(jpi,jpj) :: zfU , zfV ! internal stresses
155	REAL(wp), DIMENSION(jpi,jpj) :: zspgU, zspgV ! surface pressure gradient at U/V points
156	REAL(wp), DIMENSION(jpi,jpj) :: zCorU, zCorV ! Coriolis stress array
157	REAL(wp), DIMENSION(jpi,jpj) :: ztaux_ai, ztauy_ai ! ice-atm. stress at U-V points
158	REAL(wp), DIMENSION(jpi,jpj) :: ztaux_oi, ztauy_oi ! ice-ocean stress at U-V points
159	REAL(wp), DIMENSION(jpi,jpj) :: ztaux_bi, ztauy_bi ! ice-OceanBottom stress at U-V points (landfast)
160	REAL(wp), DIMENSION(jpi,jpj) :: ztaux_base, ztauy_base ! ice-bottom stress at U-V points (landfast)
161	!
162	REAL(wp), DIMENSION(jpi,jpj) :: zmsk01x, zmsk01y ! dummy arrays
163	REAL(wp), DIMENSION(jpi,jpj) :: zmsk00x, zmsk00y ! mask for ice presence
164	REAL(wp), DIMENSION(jpi,jpj) :: zfmask ! mask at F points for the ice
165
166	REAL(wp), PARAMETER :: zepsi = 1.0e-20_wp ! tolerance parameter
167	REAL(wp), PARAMETER :: zmmin = 1._wp ! ice mass (kg/m2) below which ice velocity becomes very small
168	REAL(wp), PARAMETER :: zamin = 0.001_wp ! ice concentration below which ice velocity becomes very small
169	!! --- check convergence
170	REAL(wp), DIMENSION(jpi,jpj) :: zu_ice, zv_ice
171	!! --- diags
172	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zsig1, zsig2, zsig3
173	!! --- SIMIP diags
174	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zdiag_xmtrp_ice ! X-component of ice mass transport (kg/s)
175	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zdiag_ymtrp_ice ! Y-component of ice mass transport (kg/s)
176	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zdiag_xmtrp_snw ! X-component of snow mass transport (kg/s)
177	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zdiag_ymtrp_snw ! Y-component of snow mass transport (kg/s)
178	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zdiag_xatrp ! X-component of area transport (m2/s)
179	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zdiag_yatrp ! Y-component of area transport (m2/s)
180	!!-------------------------------------------------------------------
181
182	IF( kt == nit000 .AND. lwp ) WRITE(numout,*) '-- ice_dyn_rhg_evp: EVP sea-ice rheology'
183	!
184	! for diagnostics and convergence tests
185	ALLOCATE( zmsk00(jpi,jpj), zmsk15(jpi,jpj) )
186	DO_2D( 1, 1, 1, 1 )
187	zmsk00(ji,jj) = MAX( 0._wp , SIGN( 1._wp , at_i(ji,jj) - epsi06 ) ) ! 1 if ice , 0 if no ice
188	zmsk15(ji,jj) = MAX( 0._wp , SIGN( 1._wp , at_i(ji,jj) - 0.15_wp ) ) ! 1 if 15% ice, 0 if less
189	END_2D
190	!
191	!!gm for Clem: OPTIMIZATION: I think zfmask can be computed one for all at the initialization....
192	!------------------------------------------------------------------------------!
193	! 0) mask at F points for the ice
194	!------------------------------------------------------------------------------!
195	! ocean/land mask
196	DO_2D( 1, 0, 1, 0 )
197	zfmask(ji,jj) = tmask(ji,jj,1) * tmask(ji+1,jj,1) * tmask(ji,jj+1,1) * tmask(ji+1,jj+1,1)
198	END_2D
199	CALL lbc_lnk( 'icedyn_rhg_evp', zfmask, 'F', 1._wp )
200
201	! Lateral boundary conditions on velocity (modify zfmask)
202	DO_2D( 0, 0, 0, 0 )
203	IF( zfmask(ji,jj) == 0._wp ) THEN
204	zfmask(ji,jj) = rn_ishlat * MIN( 1._wp , MAX( umask(ji,jj,1), umask(ji,jj+1,1), &
205	& vmask(ji,jj,1), vmask(ji+1,jj,1) ) )
206	ENDIF
207	END_2D
208	DO jj = 2, jpjm1
209	IF( zfmask(1,jj) == 0._wp ) THEN
210	zfmask(1 ,jj) = rn_ishlat * MIN( 1._wp , MAX( vmask(2,jj,1), umask(1,jj+1,1), umask(1,jj,1) ) )
211	ENDIF
212	IF( zfmask(jpi,jj) == 0._wp ) THEN
213	zfmask(jpi,jj) = rn_ishlat * MIN( 1._wp , MAX( umask(jpi,jj+1,1), vmask(jpim1,jj,1), umask(jpi,jj-1,1) ) )
214	ENDIF
215	END DO
216	DO ji = 2, jpim1
217	IF( zfmask(ji,1) == 0._wp ) THEN
218	zfmask(ji, 1 ) = rn_ishlat * MIN( 1._wp , MAX( vmask(ji+1,1,1), umask(ji,2,1), vmask(ji,1,1) ) )
219	ENDIF
220	IF( zfmask(ji,jpj) == 0._wp ) THEN
221	zfmask(ji,jpj) = rn_ishlat * MIN( 1._wp , MAX( vmask(ji+1,jpj,1), vmask(ji-1,jpj,1), umask(ji,jpjm1,1) ) )
222	ENDIF
223	END DO
224	CALL lbc_lnk( 'icedyn_rhg_evp', zfmask, 'F', 1._wp )
225
226	!------------------------------------------------------------------------------!
227	! 1) define some variables and initialize arrays
228	!------------------------------------------------------------------------------!
229	zrhoco = rho0 * rn_cio
230
231	! ecc2: square of yield ellipse eccenticrity
232	ecc2 = rn_ecc * rn_ecc
233	z1_ecc2 = 1._wp / ecc2
234
235	! alpha parameters (Bouillon 2009)
236	IF( .NOT. ln_aEVP ) THEN
237	zdtevp = rDt_ice / REAL( nn_nevp )
238	zalph1 = 2._wp * rn_relast * REAL( nn_nevp )
239	zalph2 = zalph1 * z1_ecc2
240
241	z1_alph1 = 1._wp / ( zalph1 + 1._wp )
242	z1_alph2 = 1._wp / ( zalph2 + 1._wp )
243	ELSE
244	zdtevp = rdt_ice
245	! zalpha parameters set later on adaptatively
246	ENDIF
247	z1_dtevp = 1._wp / zdtevp
248
249	! Initialise stress tensor
250	zs1 (:,:) = pstress1_i (:,:)
251	zs2 (:,:) = pstress2_i (:,:)
252	zs12(:,:) = pstress12_i(:,:)
253
254	! Ice strength
255	CALL ice_strength
256
257	! landfast param from Lemieux(2016): add isotropic tensile strength (following Konig Beatty and Holland, 2010)
258	IF( ln_landfast_L16 ) THEN ; zkt = rn_lf_tensile
259	ELSE ; zkt = 0._wp
260	ENDIF
261	!
262	!------------------------------------------------------------------------------!
263	! 2) Wind / ocean stress, mass terms, coriolis terms
264	!------------------------------------------------------------------------------!
265	! sea surface height
266	! embedded sea ice: compute representative ice top surface
267	! non-embedded sea ice: use ocean surface for slope calculation
268	zsshdyn(:,:) = ice_var_sshdyn( ssh_m, snwice_mass, snwice_mass_b)
269
270	DO_2D( 0, 0, 0, 0 )
271
272	! ice fraction at U-V points
273	zaU(ji,jj) = 0.5_wp * ( at_i(ji,jj) * e1e2t(ji,jj) + at_i(ji+1,jj) * e1e2t(ji+1,jj) ) * r1_e1e2u(ji,jj) * umask(ji,jj,1)
274	zaV(ji,jj) = 0.5_wp * ( at_i(ji,jj) * e1e2t(ji,jj) + at_i(ji,jj+1) * e1e2t(ji,jj+1) ) * r1_e1e2v(ji,jj) * vmask(ji,jj,1)
275
276	! Ice/snow mass at U-V points
277	zm1 = ( rhos * vt_s(ji ,jj ) + rhoi * vt_i(ji ,jj ) )
278	zm2 = ( rhos * vt_s(ji+1,jj ) + rhoi * vt_i(ji+1,jj ) )
279	zm3 = ( rhos * vt_s(ji ,jj+1) + rhoi * vt_i(ji ,jj+1) )
280	zmassU = 0.5_wp * ( zm1 * e1e2t(ji,jj) + zm2 * e1e2t(ji+1,jj) ) * r1_e1e2u(ji,jj) * umask(ji,jj,1)
281	zmassV = 0.5_wp * ( zm1 * e1e2t(ji,jj) + zm3 * e1e2t(ji,jj+1) ) * r1_e1e2v(ji,jj) * vmask(ji,jj,1)
282
283	! Ocean currents at U-V points
284	v_oceU(ji,jj) = 0.25_wp * ( v_oce(ji,jj) + v_oce(ji,jj-1) + v_oce(ji+1,jj) + v_oce(ji+1,jj-1) ) * umask(ji,jj,1)
285	u_oceV(ji,jj) = 0.25_wp * ( u_oce(ji,jj) + u_oce(ji-1,jj) + u_oce(ji,jj+1) + u_oce(ji-1,jj+1) ) * vmask(ji,jj,1)
286
287	! Coriolis at T points (m*f)
288	zmf(ji,jj) = zm1 * ff_t(ji,jj)
289
290	! dt/m at T points (for alpha and beta coefficients)
291	zdt_m(ji,jj) = zdtevp / MAX( zm1, zmmin )
292
293	! m/dt
294	zmU_t(ji,jj) = zmassU * z1_dtevp
295	zmV_t(ji,jj) = zmassV * z1_dtevp
296
297	! Drag ice-atm.
298	ztaux_ai(ji,jj) = zaU(ji,jj) * utau_ice(ji,jj)
299	ztauy_ai(ji,jj) = zaV(ji,jj) * vtau_ice(ji,jj)
300
301	! Surface pressure gradient (- mgGRAD(ssh)) at U-V points
302	zspgU(ji,jj) = - zmassU * grav * ( zsshdyn(ji+1,jj) - zsshdyn(ji,jj) ) * r1_e1u(ji,jj)
303	zspgV(ji,jj) = - zmassV * grav * ( zsshdyn(ji,jj+1) - zsshdyn(ji,jj) ) * r1_e2v(ji,jj)
304
305	! masks
306	zmsk00x(ji,jj) = 1._wp - MAX( 0._wp, SIGN( 1._wp, -zmassU ) ) ! 0 if no ice
307	zmsk00y(ji,jj) = 1._wp - MAX( 0._wp, SIGN( 1._wp, -zmassV ) ) ! 0 if no ice
308
309	! switches
310	IF( zmassU <= zmmin .AND. zaU(ji,jj) <= zamin ) THEN ; zmsk01x(ji,jj) = 0._wp
311	ELSE ; zmsk01x(ji,jj) = 1._wp ; ENDIF
312	IF( zmassV <= zmmin .AND. zaV(ji,jj) <= zamin ) THEN ; zmsk01y(ji,jj) = 0._wp
313	ELSE ; zmsk01y(ji,jj) = 1._wp ; ENDIF
314
315	END_2D
316	CALL lbc_lnk_multi( 'icedyn_rhg_evp', zmf, 'T', 1.0_wp, zdt_m, 'T', 1.0_wp )
317	!
318	! !== Landfast ice parameterization ==!
319	!
320	IF( ln_landfast_L16 ) THEN !-- Lemieux 2016
321	DO_2D( 0, 0, 0, 0 )
322	! ice thickness at U-V points
323	zvU = 0.5_wp * ( vt_i(ji,jj) * e1e2t(ji,jj) + vt_i(ji+1,jj) * e1e2t(ji+1,jj) ) * r1_e1e2u(ji,jj) * umask(ji,jj,1)
324	zvV = 0.5_wp * ( vt_i(ji,jj) * e1e2t(ji,jj) + vt_i(ji,jj+1) * e1e2t(ji,jj+1) ) * r1_e1e2v(ji,jj) * vmask(ji,jj,1)
325	! ice-bottom stress at U points
326	zvCr = zaU(ji,jj) * rn_lf_depfra * hu(ji,jj,Kmm)
327	ztaux_base(ji,jj) = - rn_lf_bfr * MAX( 0._wp, zvU - zvCr ) * EXP( -rn_crhg * ( 1._wp - zaU(ji,jj) ) )
328	! ice-bottom stress at V points
329	zvCr = zaV(ji,jj) * rn_lf_depfra * hv(ji,jj,Kmm)
330	ztauy_base(ji,jj) = - rn_lf_bfr * MAX( 0._wp, zvV - zvCr ) * EXP( -rn_crhg * ( 1._wp - zaV(ji,jj) ) )
331	! ice_bottom stress at T points
332	zvCr = at_i(ji,jj) * rn_lf_depfra * ht(ji,jj)
333	tau_icebfr(ji,jj) = - rn_lf_bfr * MAX( 0._wp, vt_i(ji,jj) - zvCr ) * EXP( -rn_crhg * ( 1._wp - at_i(ji,jj) ) )
334	END_2D
335	CALL lbc_lnk( 'icedyn_rhg_evp', tau_icebfr(:,:), 'T', 1.0_wp )
336	!
337	ELSE !-- no landfast
338	DO_2D( 0, 0, 0, 0 )
339	ztaux_base(ji,jj) = 0._wp
340	ztauy_base(ji,jj) = 0._wp
341	END_2D
342	ENDIF
343
344	!------------------------------------------------------------------------------!
345	! 3) Solution of the momentum equation, iterative procedure
346	!------------------------------------------------------------------------------!
347	!
348	! ! ==================== !
349	DO jter = 1 , nn_nevp ! loop over jter !
350	! ! ==================== !
351	l_full_nf_update = jter == nn_nevp ! false: disable full North fold update (performances) for iter = 1 to nn_nevp-1
352	!
353	! convergence test
354	IF( nn_rhg_chkcvg == 1 .OR. nn_rhg_chkcvg == 2 ) THEN
355	DO_2D( nn_hls, nn_hls, nn_hls, nn_hls )
356	zu_ice(ji,jj) = u_ice(ji,jj) * umask(ji,jj,1) ! velocity at previous time step
357	zv_ice(ji,jj) = v_ice(ji,jj) * vmask(ji,jj,1)
358	END_2D
359	ENDIF
360
361	! --- divergence, tension & shear (Appendix B of Hunke & Dukowicz, 2002) --- !
362	DO_2D( 1, 0, 1, 0 )
363
364	! shear at F points
365	zds(ji,jj) = ( ( u_ice(ji,jj+1) * r1_e1u(ji,jj+1) - u_ice(ji,jj) * r1_e1u(ji,jj) ) * e1f(ji,jj) * e1f(ji,jj) &
366	& + ( v_ice(ji+1,jj) * r1_e2v(ji+1,jj) - v_ice(ji,jj) * r1_e2v(ji,jj) ) * e2f(ji,jj) * e2f(ji,jj) &
367	& ) * r1_e1e2f(ji,jj) * zfmask(ji,jj)
368
369	END_2D
370
371	DO_2D( 0, 0, 0, 0 )
372
373	! shear**2 at T points (doc eq. A16)
374	zds2 = ( zds(ji,jj ) * zds(ji,jj ) * e1e2f(ji,jj ) + zds(ji-1,jj ) * zds(ji-1,jj ) * e1e2f(ji-1,jj ) &
375	& + zds(ji,jj-1) * zds(ji,jj-1) * e1e2f(ji,jj-1) + zds(ji-1,jj-1) * zds(ji-1,jj-1) * e1e2f(ji-1,jj-1) &
376	& ) * 0.25_wp * r1_e1e2t(ji,jj)
377
378	! divergence at T points
379	zdiv = ( e2u(ji,jj) * u_ice(ji,jj) - e2u(ji-1,jj) * u_ice(ji-1,jj) &
380	& + e1v(ji,jj) * v_ice(ji,jj) - e1v(ji,jj-1) * v_ice(ji,jj-1) &
381	& ) * r1_e1e2t(ji,jj)
382	zdiv2 = zdiv * zdiv
383
384	! tension at T points
385	zdt = ( ( u_ice(ji,jj) * r1_e2u(ji,jj) - u_ice(ji-1,jj) * r1_e2u(ji-1,jj) ) * e2t(ji,jj) * e2t(ji,jj) &
386	& - ( v_ice(ji,jj) * r1_e1v(ji,jj) - v_ice(ji,jj-1) * r1_e1v(ji,jj-1) ) * e1t(ji,jj) * e1t(ji,jj) &
387	& ) * r1_e1e2t(ji,jj)
388	zdt2 = zdt * zdt
389
390	! delta at T points
391	zdelta(ji,jj) = SQRT( zdiv2 + ( zdt2 + zds2 ) * z1_ecc2 )
392
393	END_2D
394	CALL lbc_lnk( 'icedyn_rhg_evp', zdelta, 'T', 1.0_wp )
395
396	! P/delta at T points
397	DO_2D( 1, 1, 1, 1 )
398	zp_delt(ji,jj) = strength(ji,jj) / ( zdelta(ji,jj) + rn_creepl )
399	END_2D
400
401	DO_2D( 0, 1, 0, 1 ) ! loop ends at jpi,jpj so that no lbc_lnk are needed for zs1 and zs2
402
403	! divergence at T points (duplication to avoid communications)
404	zdiv = ( e2u(ji,jj) * u_ice(ji,jj) - e2u(ji-1,jj) * u_ice(ji-1,jj) &
405	& + e1v(ji,jj) * v_ice(ji,jj) - e1v(ji,jj-1) * v_ice(ji,jj-1) &
406	& ) * r1_e1e2t(ji,jj)
407
408	! tension at T points (duplication to avoid communications)
409	zdt = ( ( u_ice(ji,jj) * r1_e2u(ji,jj) - u_ice(ji-1,jj) * r1_e2u(ji-1,jj) ) * e2t(ji,jj) * e2t(ji,jj) &
410	& - ( v_ice(ji,jj) * r1_e1v(ji,jj) - v_ice(ji,jj-1) * r1_e1v(ji,jj-1) ) * e1t(ji,jj) * e1t(ji,jj) &
411	& ) * r1_e1e2t(ji,jj)
412
413	! alpha for aEVP
414	! gamma = 0.5P/(delta+creepl) (cpi)2/Area dt/m
415	! alpha = beta = sqrt(4*gamma)
416	IF( ln_aEVP ) THEN
417	zalph1 = MAX( 50._wp, rpi * SQRT( 0.5_wp * zp_delt(ji,jj) * r1_e1e2t(ji,jj) * zdt_m(ji,jj) ) )
418	z1_alph1 = 1._wp / ( zalph1 + 1._wp )
419	zalph2 = zalph1
420	z1_alph2 = z1_alph1
421	! explicit:
422	! z1_alph1 = 1._wp / zalph1
423	! z1_alph2 = 1._wp / zalph1
424	! zalph1 = zalph1 - 1._wp
425	! zalph2 = zalph1
426	ENDIF
427
428	! stress at T points (zkt/=0 if landfast)
429	zs1(ji,jj) = ( zs1(ji,jj)zalph1 + zp_delt(ji,jj) ( zdiv(1._wp + zkt) - zdelta(ji,jj)(1._wp - zkt) ) ) * z1_alph1
430	zs2(ji,jj) = ( zs2(ji,jj)zalph2 + zp_delt(ji,jj) ( zdt * z1_ecc2 * (1._wp + zkt) ) ) * z1_alph2
431
432	END_2D
433
434	! Save beta at T-points for further computations
435	IF( ln_aEVP ) THEN
436	DO_2D( 1, 1, 1, 1 )
437	zbeta(ji,jj) = MAX( 50._wp, rpi * SQRT( 0.5_wp * zp_delt(ji,jj) * r1_e1e2t(ji,jj) * zdt_m(ji,jj) ) )
438	END_2D
439	ENDIF
440
441	DO_2D( 1, 0, 1, 0 )
442
443	! alpha for aEVP
444	IF( ln_aEVP ) THEN
445	zalph2 = MAX( zbeta(ji,jj), zbeta(ji+1,jj), zbeta(ji,jj+1), zbeta(ji+1,jj+1) )
446	z1_alph2 = 1._wp / ( zalph2 + 1._wp )
447	! explicit:
448	! z1_alph2 = 1._wp / zalph2
449	! zalph2 = zalph2 - 1._wp
450	ENDIF
451
452	! P/delta at F points
453	zp_delf = 0.25_wp * ( zp_delt(ji,jj) + zp_delt(ji+1,jj) + zp_delt(ji,jj+1) + zp_delt(ji+1,jj+1) )
454
455	! stress at F points (zkt/=0 if landfast)
456	zs12(ji,jj)= ( zs12(ji,jj) * zalph2 + zp_delf * ( zds(ji,jj) * z1_ecc2 * (1._wp + zkt) ) * 0.5_wp ) * z1_alph2
457
458	END_2D
459
460	! --- Ice internal stresses (Appendix C of Hunke and Dukowicz, 2002) --- !
461	DO_2D( 0, 0, 0, 0 )
462	! !--- U points
463	zfU(ji,jj) = 0.5_wp * ( ( zs1(ji+1,jj) - zs1(ji,jj) ) * e2u(ji,jj) &
464	& + ( zs2(ji+1,jj) * e2t(ji+1,jj) * e2t(ji+1,jj) - zs2(ji,jj) * e2t(ji,jj) * e2t(ji,jj) &
465	& ) * r1_e2u(ji,jj) &
466	& + ( zs12(ji,jj) * e1f(ji,jj) * e1f(ji,jj) - zs12(ji,jj-1) * e1f(ji,jj-1) * e1f(ji,jj-1) &
467	& ) * 2._wp * r1_e1u(ji,jj) &
468	& ) * r1_e1e2u(ji,jj)
469	!
470	! !--- V points
471	zfV(ji,jj) = 0.5_wp * ( ( zs1(ji,jj+1) - zs1(ji,jj) ) * e1v(ji,jj) &
472	& - ( zs2(ji,jj+1) * e1t(ji,jj+1) * e1t(ji,jj+1) - zs2(ji,jj) * e1t(ji,jj) * e1t(ji,jj) &
473	& ) * r1_e1v(ji,jj) &
474	& + ( zs12(ji,jj) * e2f(ji,jj) * e2f(ji,jj) - zs12(ji-1,jj) * e2f(ji-1,jj) * e2f(ji-1,jj) &
475	& ) * 2._wp * r1_e2v(ji,jj) &
476	& ) * r1_e1e2v(ji,jj)
477	!
478	! !--- ice currents at U-V point
479	v_iceU(ji,jj) = 0.25_wp * ( v_ice(ji,jj) + v_ice(ji,jj-1) + v_ice(ji+1,jj) + v_ice(ji+1,jj-1) ) * umask(ji,jj,1)
480	u_iceV(ji,jj) = 0.25_wp * ( u_ice(ji,jj) + u_ice(ji-1,jj) + u_ice(ji,jj+1) + u_ice(ji-1,jj+1) ) * vmask(ji,jj,1)
481	!
482	END_2D
483	!
484	! --- Computation of ice velocity --- !
485	! Bouillon et al. 2013 (eq 47-48) => unstable unless alpha, beta vary as in Kimmritz 2016 & 2017
486	! Bouillon et al. 2009 (eq 34-35) => stable
487	IF( MOD(jter,2) == 0 ) THEN ! even iterations
488	!
489	DO_2D( 0, 0, 0, 0 )
490	! !--- tau_io/(v_oce - v_ice)
491	zTauO = zaV(ji,jj) * zrhoco * SQRT( ( v_ice (ji,jj) - v_oce (ji,jj) ) * ( v_ice (ji,jj) - v_oce (ji,jj) ) &
492	& + ( u_iceV(ji,jj) - u_oceV(ji,jj) ) * ( u_iceV(ji,jj) - u_oceV(ji,jj) ) )
493	! !--- Ocean-to-Ice stress
494	ztauy_oi(ji,jj) = zTauO * ( v_oce(ji,jj) - v_ice(ji,jj) )
495	!
496	! !--- tau_bottom/v_ice
497	zvel = 5.e-05_wp + SQRT( v_ice(ji,jj) * v_ice(ji,jj) + u_iceV(ji,jj) * u_iceV(ji,jj) )
498	zTauB = ztauy_base(ji,jj) / zvel
499	! !--- OceanBottom-to-Ice stress
500	ztauy_bi(ji,jj) = zTauB * v_ice(ji,jj)
501	!
502	! !--- Coriolis at V-points (energy conserving formulation)
503	zCorV(ji,jj) = - 0.25_wp * r1_e2v(ji,jj) * &
504	& ( zmf(ji,jj ) * ( e2u(ji,jj ) * u_ice(ji,jj ) + e2u(ji-1,jj ) * u_ice(ji-1,jj ) ) &
505	& + zmf(ji,jj+1) * ( e2u(ji,jj+1) * u_ice(ji,jj+1) + e2u(ji-1,jj+1) * u_ice(ji-1,jj+1) ) )
506	!
507	! !--- Sum of external forces (explicit solution) = F + tau_ia + Coriolis + spg + tau_io
508	zRHS = zfV(ji,jj) + ztauy_ai(ji,jj) + zCorV(ji,jj) + zspgV(ji,jj) + ztauy_oi(ji,jj)
509	!
510	! !--- landfast switch => 0 = static friction : TauB > RHS & sign(TauB) /= sign(RHS)
511	! 1 = sliding friction : TauB < RHS
512	rswitch = 1._wp - MIN( 1._wp, ABS( SIGN( 1._wp, zRHS + ztauy_base(ji,jj) ) - SIGN( 1._wp, zRHS ) ) )
513	!
514	IF( ln_aEVP ) THEN !--- ice velocity using aEVP (Kimmritz et al 2016 & 2017)
515	zbetav = MAX( zbeta(ji,jj), zbeta(ji,jj+1) )
516	v_ice(ji,jj) = ( ( rswitch * ( zmV_t(ji,jj) * ( zbetav * v_ice(ji,jj) + v_ice_b(ji,jj) ) & ! previous velocity
517	& + zRHS + zTauO * v_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
518	& ) / MAX( zepsi, zmV_t(ji,jj) * ( zbetav + 1._wp ) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
519	& + ( 1._wp - rswitch ) * ( v_ice_b(ji,jj) &
520	& + v_ice (ji,jj) * MAX( 0._wp, zbetav - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
521	& ) / ( zbetav + 1._wp ) &
522	& ) * zmsk01y(ji,jj) + v_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01y(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
523	& ) * zmsk00y(ji,jj)
524	ELSE !--- ice velocity using EVP implicit formulation (cf Madec doc & Bouillon 2009)
525	v_ice(ji,jj) = ( ( rswitch * ( zmV_t(ji,jj) * v_ice(ji,jj) & ! previous velocity
526	& + zRHS + zTauO * v_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
527	& ) / MAX( zepsi, zmV_t(ji,jj) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
528	& + ( 1._wp - rswitch ) * v_ice(ji,jj) * MAX( 0._wp, 1._wp - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
529	& ) * zmsk01y(ji,jj) + v_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01y(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
530	& ) * zmsk00y(ji,jj)
531	ENDIF
532	END_2D
533	CALL lbc_lnk( 'icedyn_rhg_evp', v_ice, 'V', -1.0_wp )
534	!
535	#if defined key_agrif
536	!! CALL agrif_interp_ice( 'V', jter, nn_nevp )
537	CALL agrif_interp_ice( 'V' )
538	#endif
539	IF( ln_bdy ) CALL bdy_ice_dyn( 'V' )
540	!
541	DO_2D( 0, 0, 0, 0 )
542	! !--- tau_io/(u_oce - u_ice)
543	zTauO = zaU(ji,jj) * zrhoco * SQRT( ( u_ice (ji,jj) - u_oce (ji,jj) ) * ( u_ice (ji,jj) - u_oce (ji,jj) ) &
544	& + ( v_iceU(ji,jj) - v_oceU(ji,jj) ) * ( v_iceU(ji,jj) - v_oceU(ji,jj) ) )
545	! !--- Ocean-to-Ice stress
546	ztaux_oi(ji,jj) = zTauO * ( u_oce(ji,jj) - u_ice(ji,jj) )
547	!
548	! !--- tau_bottom/u_ice
549	zvel = 5.e-05_wp + SQRT( v_iceU(ji,jj) * v_iceU(ji,jj) + u_ice(ji,jj) * u_ice(ji,jj) )
550	zTauB = ztaux_base(ji,jj) / zvel
551	! !--- OceanBottom-to-Ice stress
552	ztaux_bi(ji,jj) = zTauB * u_ice(ji,jj)
553	!
554	! !--- Coriolis at U-points (energy conserving formulation)
555	zCorU(ji,jj) = 0.25_wp * r1_e1u(ji,jj) * &
556	& ( zmf(ji ,jj) * ( e1v(ji ,jj) * v_ice(ji ,jj) + e1v(ji ,jj-1) * v_ice(ji ,jj-1) ) &
557	& + zmf(ji+1,jj) * ( e1v(ji+1,jj) * v_ice(ji+1,jj) + e1v(ji+1,jj-1) * v_ice(ji+1,jj-1) ) )
558	!
559	! !--- Sum of external forces (explicit solution) = F + tau_ia + Coriolis + spg + tau_io
560	zRHS = zfU(ji,jj) + ztaux_ai(ji,jj) + zCorU(ji,jj) + zspgU(ji,jj) + ztaux_oi(ji,jj)
561	!
562	! !--- landfast switch => 0 = static friction : TauB > RHS & sign(TauB) /= sign(RHS)
563	! 1 = sliding friction : TauB < RHS
564	rswitch = 1._wp - MIN( 1._wp, ABS( SIGN( 1._wp, zRHS + ztaux_base(ji,jj) ) - SIGN( 1._wp, zRHS ) ) )
565	!
566	IF( ln_aEVP ) THEN !--- ice velocity using aEVP (Kimmritz et al 2016 & 2017)
567	zbetau = MAX( zbeta(ji,jj), zbeta(ji+1,jj) )
568	u_ice(ji,jj) = ( ( rswitch * ( zmU_t(ji,jj) * ( zbetau * u_ice(ji,jj) + u_ice_b(ji,jj) ) & ! previous velocity
569	& + zRHS + zTauO * u_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
570	& ) / MAX( zepsi, zmU_t(ji,jj) * ( zbetau + 1._wp ) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
571	& + ( 1._wp - rswitch ) * ( u_ice_b(ji,jj) &
572	& + u_ice (ji,jj) * MAX( 0._wp, zbetau - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
573	& ) / ( zbetau + 1._wp ) &
574	& ) * zmsk01x(ji,jj) + u_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01x(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
575	& ) * zmsk00x(ji,jj)
576	ELSE !--- ice velocity using EVP implicit formulation (cf Madec doc & Bouillon 2009)
577	u_ice(ji,jj) = ( ( rswitch * ( zmU_t(ji,jj) * u_ice(ji,jj) & ! previous velocity
578	& + zRHS + zTauO * u_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
579	& ) / MAX( zepsi, zmU_t(ji,jj) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
580	& + ( 1._wp - rswitch ) * u_ice(ji,jj) * MAX( 0._wp, 1._wp - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
581	& ) * zmsk01x(ji,jj) + u_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01x(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
582	& ) * zmsk00x(ji,jj)
583	ENDIF
584	END_2D
585	CALL lbc_lnk( 'icedyn_rhg_evp', u_ice, 'U', -1.0_wp )
586	!
587	#if defined key_agrif
588	!! CALL agrif_interp_ice( 'U', jter, nn_nevp )
589	CALL agrif_interp_ice( 'U' )
590	#endif
591	IF( ln_bdy ) CALL bdy_ice_dyn( 'U' )
592	!
593	ELSE ! odd iterations
594	!
595	DO_2D( 0, 0, 0, 0 )
596	! !--- tau_io/(u_oce - u_ice)
597	zTauO = zaU(ji,jj) * zrhoco * SQRT( ( u_ice (ji,jj) - u_oce (ji,jj) ) * ( u_ice (ji,jj) - u_oce (ji,jj) ) &
598	& + ( v_iceU(ji,jj) - v_oceU(ji,jj) ) * ( v_iceU(ji,jj) - v_oceU(ji,jj) ) )
599	! !--- Ocean-to-Ice stress
600	ztaux_oi(ji,jj) = zTauO * ( u_oce(ji,jj) - u_ice(ji,jj) )
601	!
602	! !--- tau_bottom/u_ice
603	zvel = 5.e-05_wp + SQRT( v_iceU(ji,jj) * v_iceU(ji,jj) + u_ice(ji,jj) * u_ice(ji,jj) )
604	zTauB = ztaux_base(ji,jj) / zvel
605	! !--- OceanBottom-to-Ice stress
606	ztaux_bi(ji,jj) = zTauB * u_ice(ji,jj)
607	!
608	! !--- Coriolis at U-points (energy conserving formulation)
609	zCorU(ji,jj) = 0.25_wp * r1_e1u(ji,jj) * &
610	& ( zmf(ji ,jj) * ( e1v(ji ,jj) * v_ice(ji ,jj) + e1v(ji ,jj-1) * v_ice(ji ,jj-1) ) &
611	& + zmf(ji+1,jj) * ( e1v(ji+1,jj) * v_ice(ji+1,jj) + e1v(ji+1,jj-1) * v_ice(ji+1,jj-1) ) )
612	!
613	! !--- Sum of external forces (explicit solution) = F + tau_ia + Coriolis + spg + tau_io
614	zRHS = zfU(ji,jj) + ztaux_ai(ji,jj) + zCorU(ji,jj) + zspgU(ji,jj) + ztaux_oi(ji,jj)
615	!
616	! !--- landfast switch => 0 = static friction : TauB > RHS & sign(TauB) /= sign(RHS)
617	! 1 = sliding friction : TauB < RHS
618	rswitch = 1._wp - MIN( 1._wp, ABS( SIGN( 1._wp, zRHS + ztaux_base(ji,jj) ) - SIGN( 1._wp, zRHS ) ) )
619	!
620	IF( ln_aEVP ) THEN !--- ice velocity using aEVP (Kimmritz et al 2016 & 2017)
621	zbetau = MAX( zbeta(ji,jj), zbeta(ji+1,jj) )
622	u_ice(ji,jj) = ( ( rswitch * ( zmU_t(ji,jj) * ( zbetau * u_ice(ji,jj) + u_ice_b(ji,jj) ) & ! previous velocity
623	& + zRHS + zTauO * u_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
624	& ) / MAX( zepsi, zmU_t(ji,jj) * ( zbetau + 1._wp ) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
625	& + ( 1._wp - rswitch ) * ( u_ice_b(ji,jj) &
626	& + u_ice (ji,jj) * MAX( 0._wp, zbetau - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
627	& ) / ( zbetau + 1._wp ) &
628	& ) * zmsk01x(ji,jj) + u_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01x(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
629	& ) * zmsk00x(ji,jj)
630	ELSE !--- ice velocity using EVP implicit formulation (cf Madec doc & Bouillon 2009)
631	u_ice(ji,jj) = ( ( rswitch * ( zmU_t(ji,jj) * u_ice(ji,jj) & ! previous velocity
632	& + zRHS + zTauO * u_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
633	& ) / MAX( zepsi, zmU_t(ji,jj) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
634	& + ( 1._wp - rswitch ) * u_ice(ji,jj) * MAX( 0._wp, 1._wp - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
635	& ) * zmsk01x(ji,jj) + u_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01x(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
636	& ) * zmsk00x(ji,jj)
637	ENDIF
638	END_2D
639	CALL lbc_lnk( 'icedyn_rhg_evp', u_ice, 'U', -1.0_wp )
640	!
641	#if defined key_agrif
642	!! CALL agrif_interp_ice( 'U', jter, nn_nevp )
643	CALL agrif_interp_ice( 'U' )
644	#endif
645	IF( ln_bdy ) CALL bdy_ice_dyn( 'U' )
646	!
647	DO_2D( 0, 0, 0, 0 )
648	! !--- tau_io/(v_oce - v_ice)
649	zTauO = zaV(ji,jj) * zrhoco * SQRT( ( v_ice (ji,jj) - v_oce (ji,jj) ) * ( v_ice (ji,jj) - v_oce (ji,jj) ) &
650	& + ( u_iceV(ji,jj) - u_oceV(ji,jj) ) * ( u_iceV(ji,jj) - u_oceV(ji,jj) ) )
651	! !--- Ocean-to-Ice stress
652	ztauy_oi(ji,jj) = zTauO * ( v_oce(ji,jj) - v_ice(ji,jj) )
653	!
654	! !--- tau_bottom/v_ice
655	zvel = 5.e-05_wp + SQRT( v_ice(ji,jj) * v_ice(ji,jj) + u_iceV(ji,jj) * u_iceV(ji,jj) )
656	zTauB = ztauy_base(ji,jj) / zvel
657	! !--- OceanBottom-to-Ice stress
658	ztauy_bi(ji,jj) = zTauB * v_ice(ji,jj)
659	!
660	! !--- Coriolis at v-points (energy conserving formulation)
661	zCorV(ji,jj) = - 0.25_wp * r1_e2v(ji,jj) * &
662	& ( zmf(ji,jj ) * ( e2u(ji,jj ) * u_ice(ji,jj ) + e2u(ji-1,jj ) * u_ice(ji-1,jj ) ) &
663	& + zmf(ji,jj+1) * ( e2u(ji,jj+1) * u_ice(ji,jj+1) + e2u(ji-1,jj+1) * u_ice(ji-1,jj+1) ) )
664	!
665	! !--- Sum of external forces (explicit solution) = F + tau_ia + Coriolis + spg + tau_io
666	zRHS = zfV(ji,jj) + ztauy_ai(ji,jj) + zCorV(ji,jj) + zspgV(ji,jj) + ztauy_oi(ji,jj)
667	!
668	! !--- landfast switch => 0 = static friction : TauB > RHS & sign(TauB) /= sign(RHS)
669	! 1 = sliding friction : TauB < RHS
670	rswitch = 1._wp - MIN( 1._wp, ABS( SIGN( 1._wp, zRHS + ztauy_base(ji,jj) ) - SIGN( 1._wp, zRHS ) ) )
671	!
672	IF( ln_aEVP ) THEN !--- ice velocity using aEVP (Kimmritz et al 2016 & 2017)
673	zbetav = MAX( zbeta(ji,jj), zbeta(ji,jj+1) )
674	v_ice(ji,jj) = ( ( rswitch * ( zmV_t(ji,jj) * ( zbetav * v_ice(ji,jj) + v_ice_b(ji,jj) ) & ! previous velocity
675	& + zRHS + zTauO * v_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
676	& ) / MAX( zepsi, zmV_t(ji,jj) * ( zbetav + 1._wp ) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
677	& + ( 1._wp - rswitch ) * ( v_ice_b(ji,jj) &
678	& + v_ice (ji,jj) * MAX( 0._wp, zbetav - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
679	& ) / ( zbetav + 1._wp ) &
680	& ) * zmsk01y(ji,jj) + v_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01y(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
681	& ) * zmsk00y(ji,jj)
682	ELSE !--- ice velocity using EVP implicit formulation (cf Madec doc & Bouillon 2009)
683	v_ice(ji,jj) = ( ( rswitch * ( zmV_t(ji,jj) * v_ice(ji,jj) & ! previous velocity
684	& + zRHS + zTauO * v_ice(ji,jj) & ! F + tau_ia + Coriolis + spg + tau_io(only ocean part)
685	& ) / MAX( zepsi, zmV_t(ji,jj) + zTauO - zTauB ) & ! m/dt + tau_io(only ice part) + landfast
686	& + ( 1._wp - rswitch ) * v_ice(ji,jj) * MAX( 0._wp, 1._wp - zdtevp * rn_lf_relax ) & ! static friction => slow decrease to v=0
687	& ) * zmsk01y(ji,jj) + v_oce(ji,jj) * 0.01_wp * ( 1._wp - zmsk01y(ji,jj) ) & ! v_ice = v_oce/100 if mass < zmmin & conc < zamin
688	& ) * zmsk00y(ji,jj)
689	ENDIF
690	END_2D
691	CALL lbc_lnk( 'icedyn_rhg_evp', v_ice, 'V', -1.0_wp )
692	!
693	#if defined key_agrif
694	!! CALL agrif_interp_ice( 'V', jter, nn_nevp )
695	CALL agrif_interp_ice( 'V' )
696	#endif
697	IF( ln_bdy ) CALL bdy_ice_dyn( 'V' )
698	!
699	ENDIF
700
701	! convergence test
702	IF( nn_rhg_chkcvg == 2 ) CALL rhg_cvg( kt, jter, nn_nevp, u_ice, v_ice, zu_ice, zv_ice )
703	!
704	! ! ==================== !
705	END DO ! end loop over jter !
706	! ! ==================== !
707	IF( ln_aEVP ) CALL iom_put( 'beta_evp' , zbeta )
708	!
709	!------------------------------------------------------------------------------!
710	! 4) Recompute delta, shear and div (inputs for mechanical redistribution)
711	!------------------------------------------------------------------------------!
712	DO_2D( 1, 0, 1, 0 )
713
714	! shear at F points
715	zds(ji,jj) = ( ( u_ice(ji,jj+1) * r1_e1u(ji,jj+1) - u_ice(ji,jj) * r1_e1u(ji,jj) ) * e1f(ji,jj) * e1f(ji,jj) &
716	& + ( v_ice(ji+1,jj) * r1_e2v(ji+1,jj) - v_ice(ji,jj) * r1_e2v(ji,jj) ) * e2f(ji,jj) * e2f(ji,jj) &
717	& ) * r1_e1e2f(ji,jj) * zfmask(ji,jj)
718
719	END_2D
720
721	DO_2D( 0, 0, 0, 0 ) ! no vector loop
722
723	! tension**2 at T points
724	zdt = ( ( u_ice(ji,jj) * r1_e2u(ji,jj) - u_ice(ji-1,jj) * r1_e2u(ji-1,jj) ) * e2t(ji,jj) * e2t(ji,jj) &
725	& - ( v_ice(ji,jj) * r1_e1v(ji,jj) - v_ice(ji,jj-1) * r1_e1v(ji,jj-1) ) * e1t(ji,jj) * e1t(ji,jj) &
726	& ) * r1_e1e2t(ji,jj)
727	zdt2 = zdt * zdt
728
729	! shear**2 at T points (doc eq. A16)
730	zds2 = ( zds(ji,jj ) * zds(ji,jj ) * e1e2f(ji,jj ) + zds(ji-1,jj ) * zds(ji-1,jj ) * e1e2f(ji-1,jj ) &
731	& + zds(ji,jj-1) * zds(ji,jj-1) * e1e2f(ji,jj-1) + zds(ji-1,jj-1) * zds(ji-1,jj-1) * e1e2f(ji-1,jj-1) &
732	& ) * 0.25_wp * r1_e1e2t(ji,jj)
733
734	! shear at T points
735	pshear_i(ji,jj) = SQRT( zdt2 + zds2 )
736
737	! divergence at T points
738	pdivu_i(ji,jj) = ( e2u(ji,jj) * u_ice(ji,jj) - e2u(ji-1,jj) * u_ice(ji-1,jj) &
739	& + e1v(ji,jj) * v_ice(ji,jj) - e1v(ji,jj-1) * v_ice(ji,jj-1) &
740	& ) * r1_e1e2t(ji,jj)
741
742	! delta at T points
743	zdelta(ji,jj) = SQRT( pdivu_i(ji,jj) * pdivu_i(ji,jj) + ( zdt2 + zds2 ) * z1_ecc2 )
744	rswitch = 1._wp - MAX( 0._wp, SIGN( 1._wp, -zdelta(ji,jj) ) ) ! 0 if delta=0
745	pdelta_i(ji,jj) = zdelta(ji,jj) + rn_creepl * rswitch
746
747	END_2D
748	CALL lbc_lnk_multi( 'icedyn_rhg_evp', pshear_i, 'T', 1.0_wp, pdivu_i, 'T', 1.0_wp, pdelta_i, 'T', 1.0_wp )
749
750	! --- Store the stress tensor for the next time step --- !
751	CALL lbc_lnk_multi( 'icedyn_rhg_evp', zs1, 'T', 1.0_wp, zs2, 'T', 1.0_wp, zs12, 'F', 1.0_wp )
752	pstress1_i (:,:) = zs1 (:,:)
753	pstress2_i (:,:) = zs2 (:,:)
754	pstress12_i(:,:) = zs12(:,:)
755	!
756
757	!------------------------------------------------------------------------------!
758	! 5) diagnostics
759	!------------------------------------------------------------------------------!
760	! --- ice-ocean, ice-atm. & ice-oceanbottom(landfast) stresses --- !
761	IF( iom_use('utau_oi') .OR. iom_use('vtau_oi') .OR. iom_use('utau_ai') .OR. iom_use('vtau_ai') .OR. &
762	& iom_use('utau_bi') .OR. iom_use('vtau_bi') ) THEN
763	!
764	CALL lbc_lnk_multi( 'icedyn_rhg_evp', ztaux_oi, 'U', -1.0_wp, ztauy_oi, 'V', -1.0_wp, ztaux_ai, 'U', -1.0_wp, ztauy_ai, 'V', -1.0_wp, &
765	& ztaux_bi, 'U', -1.0_wp, ztauy_bi, 'V', -1.0_wp )
766	!
767	CALL iom_put( 'utau_oi' , ztaux_oi * zmsk00 )
768	CALL iom_put( 'vtau_oi' , ztauy_oi * zmsk00 )
769	CALL iom_put( 'utau_ai' , ztaux_ai * zmsk00 )
770	CALL iom_put( 'vtau_ai' , ztauy_ai * zmsk00 )
771	CALL iom_put( 'utau_bi' , ztaux_bi * zmsk00 )
772	CALL iom_put( 'vtau_bi' , ztauy_bi * zmsk00 )
773	ENDIF
774
775	! --- divergence, shear and strength --- !
776	IF( iom_use('icediv') ) CALL iom_put( 'icediv' , pdivu_i * zmsk00 ) ! divergence
777	IF( iom_use('iceshe') ) CALL iom_put( 'iceshe' , pshear_i * zmsk00 ) ! shear
778	IF( iom_use('icestr') ) CALL iom_put( 'icestr' , strength * zmsk00 ) ! strength
779
780	! --- stress tensor --- !
781	IF( iom_use('isig1') .OR. iom_use('isig2') .OR. iom_use('isig3') .OR. iom_use('normstr') .OR. iom_use('sheastr') ) THEN
782	!
783	ALLOCATE( zsig1(jpi,jpj) , zsig2(jpi,jpj) , zsig3(jpi,jpj) )
784	!
785	DO_2D( 0, 0, 0, 0 )
786	zdum1 = ( zmsk00(ji-1,jj) * pstress12_i(ji-1,jj) + zmsk00(ji ,jj-1) * pstress12_i(ji ,jj-1) + & ! stress12_i at T-point
787	& zmsk00(ji ,jj) * pstress12_i(ji ,jj) + zmsk00(ji-1,jj-1) * pstress12_i(ji-1,jj-1) ) &
788	& / MAX( 1._wp, zmsk00(ji-1,jj) + zmsk00(ji,jj-1) + zmsk00(ji,jj) + zmsk00(ji-1,jj-1) )
789
790	zshear = SQRT( pstress2_i(ji,jj) * pstress2_i(ji,jj) + 4._wp * zdum1 * zdum1 ) ! shear stress
791
792	zdum2 = zmsk00(ji,jj) / MAX( 1._wp, strength(ji,jj) )
793
794	!! zsig1(ji,jj) = 0.5_wp * zdum2 * ( pstress1_i(ji,jj) + zshear ) ! principal stress (y-direction, see Hunke & Dukowicz 2002)
795	!! zsig2(ji,jj) = 0.5_wp * zdum2 * ( pstress1_i(ji,jj) - zshear ) ! principal stress (x-direction, see Hunke & Dukowicz 2002)
796	!! zsig3(ji,jj) = zdum2*2 ( ( pstress1_i(ji,jj) + strength(ji,jj) )*2 + ( rn_ecc zshear )**2 ) ! quadratic relation linking compressive stress to shear stress
797	!! ! (scheme converges if this value is ~1, see Bouillon et al 2009 (eq. 11))
798	zsig1(ji,jj) = 0.5_wp * zdum2 * ( pstress1_i(ji,jj) ) ! compressive stress, see Bouillon et al. 2015
799	zsig2(ji,jj) = 0.5_wp * zdum2 * ( zshear ) ! shear stress
800	zsig3(ji,jj) = zdum2*2 ( ( pstress1_i(ji,jj) + strength(ji,jj) )*2 + ( rn_ecc zshear )**2 )
801	END_2D
802	CALL lbc_lnk_multi( 'icedyn_rhg_evp', zsig1, 'T', 1.0_wp, zsig2, 'T', 1.0_wp, zsig3, 'T', 1.0_wp )
803	!
804	CALL iom_put( 'isig1' , zsig1 )
805	CALL iom_put( 'isig2' , zsig2 )
806	CALL iom_put( 'isig3' , zsig3 )
807	!
808	! Stress tensor invariants (normal and shear stress N/m)
809	IF( iom_use('normstr') ) CALL iom_put( 'normstr' , ( zs1(:,:) + zs2(:,:) ) * zmsk00(:,:) ) ! Normal stress
810	IF( iom_use('sheastr') ) CALL iom_put( 'sheastr' , SQRT( ( zs1(:,:) - zs2(:,:) )*2 + 4zs12(:,:)*2 ) zmsk00(:,:) ) ! Shear stress
811
812	DEALLOCATE( zsig1 , zsig2 , zsig3 )
813	ENDIF
814
815	! --- SIMIP --- !
816	IF( iom_use('dssh_dx') .OR. iom_use('dssh_dy') .OR. &
817	& iom_use('corstrx') .OR. iom_use('corstry') .OR. iom_use('intstrx') .OR. iom_use('intstry') ) THEN
818	!
819	CALL lbc_lnk_multi( 'icedyn_rhg_evp', zspgU, 'U', -1.0_wp, zspgV, 'V', -1.0_wp, &
820	& zCorU, 'U', -1.0_wp, zCorV, 'V', -1.0_wp, zfU, 'U', -1.0_wp, zfV, 'V', -1.0_wp )
821
822	CALL iom_put( 'dssh_dx' , zspgU * zmsk00 ) ! Sea-surface tilt term in force balance (x)
823	CALL iom_put( 'dssh_dy' , zspgV * zmsk00 ) ! Sea-surface tilt term in force balance (y)
824	CALL iom_put( 'corstrx' , zCorU * zmsk00 ) ! Coriolis force term in force balance (x)
825	CALL iom_put( 'corstry' , zCorV * zmsk00 ) ! Coriolis force term in force balance (y)
826	CALL iom_put( 'intstrx' , zfU * zmsk00 ) ! Internal force term in force balance (x)
827	CALL iom_put( 'intstry' , zfV * zmsk00 ) ! Internal force term in force balance (y)
828	ENDIF
829
830	IF( iom_use('xmtrpice') .OR. iom_use('ymtrpice') .OR. &
831	& iom_use('xmtrpsnw') .OR. iom_use('ymtrpsnw') .OR. iom_use('xatrp') .OR. iom_use('yatrp') ) THEN
832	!
833	ALLOCATE( zdiag_xmtrp_ice(jpi,jpj) , zdiag_ymtrp_ice(jpi,jpj) , &
834	& zdiag_xmtrp_snw(jpi,jpj) , zdiag_ymtrp_snw(jpi,jpj) , zdiag_xatrp(jpi,jpj) , zdiag_yatrp(jpi,jpj) )
835	!
836	DO_2D( 0, 0, 0, 0 )
837	! 2D ice mass, snow mass, area transport arrays (X, Y)
838	zfac_x = 0.5 * u_ice(ji,jj) * e2u(ji,jj) * zmsk00(ji,jj)
839	zfac_y = 0.5 * v_ice(ji,jj) * e1v(ji,jj) * zmsk00(ji,jj)
840
841	zdiag_xmtrp_ice(ji,jj) = rhoi * zfac_x * ( vt_i(ji+1,jj) + vt_i(ji,jj) ) ! ice mass transport, X-component
842	zdiag_ymtrp_ice(ji,jj) = rhoi * zfac_y * ( vt_i(ji,jj+1) + vt_i(ji,jj) ) ! '' Y- ''
843
844	zdiag_xmtrp_snw(ji,jj) = rhos * zfac_x * ( vt_s(ji+1,jj) + vt_s(ji,jj) ) ! snow mass transport, X-component
845	zdiag_ymtrp_snw(ji,jj) = rhos * zfac_y * ( vt_s(ji,jj+1) + vt_s(ji,jj) ) ! '' Y- ''
846
847	zdiag_xatrp(ji,jj) = zfac_x * ( at_i(ji+1,jj) + at_i(ji,jj) ) ! area transport, X-component
848	zdiag_yatrp(ji,jj) = zfac_y * ( at_i(ji,jj+1) + at_i(ji,jj) ) ! '' Y- ''
849
850	END_2D
851
852	CALL lbc_lnk_multi( 'icedyn_rhg_evp', zdiag_xmtrp_ice, 'U', -1.0_wp, zdiag_ymtrp_ice, 'V', -1.0_wp, &
853	& zdiag_xmtrp_snw, 'U', -1.0_wp, zdiag_ymtrp_snw, 'V', -1.0_wp, &
854	& zdiag_xatrp , 'U', -1.0_wp, zdiag_yatrp , 'V', -1.0_wp )
855
856	CALL iom_put( 'xmtrpice' , zdiag_xmtrp_ice ) ! X-component of sea-ice mass transport (kg/s)
857	CALL iom_put( 'ymtrpice' , zdiag_ymtrp_ice ) ! Y-component of sea-ice mass transport
858	CALL iom_put( 'xmtrpsnw' , zdiag_xmtrp_snw ) ! X-component of snow mass transport (kg/s)
859	CALL iom_put( 'ymtrpsnw' , zdiag_ymtrp_snw ) ! Y-component of snow mass transport
860	CALL iom_put( 'xatrp' , zdiag_xatrp ) ! X-component of ice area transport
861	CALL iom_put( 'yatrp' , zdiag_yatrp ) ! Y-component of ice area transport
862
863	DEALLOCATE( zdiag_xmtrp_ice , zdiag_ymtrp_ice , &
864	& zdiag_xmtrp_snw , zdiag_ymtrp_snw , zdiag_xatrp , zdiag_yatrp )
865
866	ENDIF
867	!
868	! --- convergence tests --- !
869	IF( nn_rhg_chkcvg == 1 .OR. nn_rhg_chkcvg == 2 ) THEN
870	IF( iom_use('uice_cvg') ) THEN
871	IF( ln_aEVP ) THEN ! output: beta * ( u(t=nn_nevp) - u(t=nn_nevp-1) )
872	CALL iom_put( 'uice_cvg', MAX( ABS( u_ice(:,:) - zu_ice(:,:) ) * zbeta(:,:) * umask(:,:,1) , &
873	& ABS( v_ice(:,:) - zv_ice(:,:) ) * zbeta(:,:) * vmask(:,:,1) ) * zmsk15(:,:) )
874	ELSE ! output: nn_nevp * ( u(t=nn_nevp) - u(t=nn_nevp-1) )
875	CALL iom_put( 'uice_cvg', REAL( nn_nevp ) * MAX( ABS( u_ice(:,:) - zu_ice(:,:) ) * umask(:,:,1) , &
876	& ABS( v_ice(:,:) - zv_ice(:,:) ) * vmask(:,:,1) ) * zmsk15(:,:) )
877	ENDIF
878	ENDIF
879	ENDIF
880	!
881	DEALLOCATE( zmsk00, zmsk15 )
882	!
883	END SUBROUTINE ice_dyn_rhg_evp
884
885
886	SUBROUTINE rhg_cvg( kt, kiter, kitermax, pu, pv, pub, pvb )
887	!!----------------------------------------------------------------------
888	!! * ROUTINE rhg_cvg *
889	!!
890	!! ** Purpose : check convergence of oce rheology
891	!!
892	!! ** Method : create a file ice_cvg.nc containing the convergence of ice velocity
893	!! during the sub timestepping of rheology so as:
894	!! uice_cvg = MAX( u(t+1) - u(t) , v(t+1) - v(t) )
895	!! This routine is called every sub-iteration, so it is cpu expensive
896	!!
897	!! ** Note : for the first sub-iteration, uice_cvg is set to 0 (too large otherwise)
898	!!----------------------------------------------------------------------
899	INTEGER , INTENT(in) :: kt, kiter, kitermax ! ocean time-step index
900	REAL(wp), DIMENSION(:,:), INTENT(in) :: pu, pv, pub, pvb ! now and before velocities
901	!!
902	INTEGER :: it, idtime, istatus
903	INTEGER :: ji, jj ! dummy loop indices
904	REAL(wp) :: zresm ! local real
905	CHARACTER(len=20) :: clname
906	REAL(wp), DIMENSION(jpi,jpj) :: zres ! check convergence
907	!!----------------------------------------------------------------------
908
909	! create file
910	IF( kt == nit000 .AND. kiter == 1 ) THEN
911	!
912	IF( lwp ) THEN
913	WRITE(numout,*)
914	WRITE(numout,*) 'rhg_cvg : ice rheology convergence control'
915	WRITE(numout,*) '~~~~~~~'
916	ENDIF
917	!
918	IF( lwm ) THEN
919	clname = 'ice_cvg.nc'
920	IF( .NOT. Agrif_Root() ) clname = TRIM(Agrif_CFixed())//"_"//TRIM(clname)
921	istatus = NF90_CREATE( TRIM(clname), NF90_CLOBBER, ncvgid )
922	istatus = NF90_DEF_DIM( ncvgid, 'time' , NF90_UNLIMITED, idtime )
923	istatus = NF90_DEF_VAR( ncvgid, 'uice_cvg', NF90_DOUBLE , (/ idtime /), nvarid )
924	istatus = NF90_ENDDEF(ncvgid)
925	ENDIF
926	!
927	ENDIF
928
929	! time
930	it = ( kt - 1 ) * kitermax + kiter
931
932	! convergence
933	IF( kiter == 1 ) THEN ! remove the first iteration for calculations of convergence (always very large)
934	zresm = 0._wp
935	ELSE
936	DO_2D( 1, 1, 1, 1 )
937	zres(ji,jj) = MAX( ABS( pu(ji,jj) - pub(ji,jj) ) * umask(ji,jj,1), &
938	& ABS( pv(ji,jj) - pvb(ji,jj) ) * vmask(ji,jj,1) ) * zmsk15(ji,jj)
939	END_2D
940	zresm = MAXVAL( zres )
941	CALL mpp_max( 'icedyn_rhg_evp', zresm ) ! max over the global domain
942	ENDIF
943
944	IF( lwm ) THEN
945	! write variables
946	istatus = NF90_PUT_VAR( ncvgid, nvarid, (/zresm/), (/it/), (/1/) )
947	! close file
948	IF( kt == nitend ) istatus = NF90_CLOSE(ncvgid)
949	ENDIF
950
951	END SUBROUTINE rhg_cvg
952
953
954	SUBROUTINE rhg_evp_rst( cdrw, kt )
955	!!---------------------------------------------------------------------
956	!! * ROUTINE rhg_evp_rst *
957	!!
958	!! ** Purpose : Read or write RHG file in restart file
959	!!
960	!! ** Method : use of IOM library
961	!!----------------------------------------------------------------------
962	CHARACTER(len=*) , INTENT(in) :: cdrw ! "READ"/"WRITE" flag
963	INTEGER, OPTIONAL, INTENT(in) :: kt ! ice time-step
964	!
965	INTEGER :: iter ! local integer
966	INTEGER :: id1, id2, id3 ! local integers
967	!!----------------------------------------------------------------------
968	!
969	IF( TRIM(cdrw) == 'READ' ) THEN ! Read/initialize
970	! ! ---------------
971	IF( ln_rstart ) THEN !* Read the restart file
972	!
973	id1 = iom_varid( numrir, 'stress1_i' , ldstop = .FALSE. )
974	id2 = iom_varid( numrir, 'stress2_i' , ldstop = .FALSE. )
975	id3 = iom_varid( numrir, 'stress12_i', ldstop = .FALSE. )
976	!
977	IF( MIN( id1, id2, id3 ) > 0 ) THEN ! fields exist
978	CALL iom_get( numrir, jpdom_auto, 'stress1_i' , stress1_i , cd_type = 'T' )
979	CALL iom_get( numrir, jpdom_auto, 'stress2_i' , stress2_i , cd_type = 'T' )
980	CALL iom_get( numrir, jpdom_auto, 'stress12_i', stress12_i, cd_type = 'F' )
981	ELSE ! start rheology from rest
982	IF(lwp) WRITE(numout,*)
983	IF(lwp) WRITE(numout,*) ' ==>>> previous run without rheology, set stresses to 0'
984	stress1_i (:,:) = 0._wp
985	stress2_i (:,:) = 0._wp
986	stress12_i(:,:) = 0._wp
987	ENDIF
988	ELSE !* Start from rest
989	IF(lwp) WRITE(numout,*)
990	IF(lwp) WRITE(numout,*) ' ==>>> start from rest: set stresses to 0'
991	stress1_i (:,:) = 0._wp
992	stress2_i (:,:) = 0._wp
993	stress12_i(:,:) = 0._wp
994	ENDIF
995	!
996	ELSEIF( TRIM(cdrw) == 'WRITE' ) THEN ! Create restart file
997	! ! -------------------
998	IF(lwp) WRITE(numout,*) '---- rhg-rst ----'
999	iter = kt + nn_fsbc - 1 ! ice restarts are written at kt == nitrst - nn_fsbc + 1
1000	!
1001	CALL iom_rstput( iter, nitrst, numriw, 'stress1_i' , stress1_i )
1002	CALL iom_rstput( iter, nitrst, numriw, 'stress2_i' , stress2_i )
1003	CALL iom_rstput( iter, nitrst, numriw, 'stress12_i', stress12_i )
1004	!
1005	ENDIF
1006	!
1007	END SUBROUTINE rhg_evp_rst
1008
1009
1010	#else
1011	!!----------------------------------------------------------------------
1012	!! Default option Empty module NO SI3 sea-ice model
1013	!!----------------------------------------------------------------------
1014	#endif
1015
1016	!!==============================================================================
1017	END MODULE icedyn_rhg_evp

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