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zdfgls.F90 @ 2497

Last change on this file since 2497 was 2497, checked in by gm, 13 years ago
v3.3beta: #780 zdfgls error in bottom friction formulation
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1	MODULE zdfgls
2	!!======================================================================
3	!! * MODULE zdfgls *
4	!! Ocean physics: vertical mixing coefficient computed from the gls
5	!! turbulent closure parameterization
6	!!======================================================================
7	!! History : 3.0 ! 2009-09 (G. Reffray) Original code
8	!! 3.3 ! 2010-10 (C. Bricaud) Add in the reference
9	!!----------------------------------------------------------------------
10	#if defined key_zdfgls \|\| defined key_esopa
11	!!----------------------------------------------------------------------
12	!! 'key_zdfgls' Generic Length Scale vertical physics
13	!!----------------------------------------------------------------------
14	!! zdf_gls : update momentum and tracer Kz from a gls scheme
15	!! zdf_gls_init : initialization, namelist read, and parameters control
16	!! gls_rst : read/write gls restart in ocean restart file
17	!!----------------------------------------------------------------------
18	USE oce ! ocean dynamics and active tracers
19	USE dom_oce ! ocean space and time domain
20	USE domvvl ! ocean space and time domain : variable volume layer
21	USE zdf_oce ! ocean vertical physics
22	USE sbc_oce ! surface boundary condition: ocean
23	USE phycst ! physical constants
24	USE zdfmxl ! mixed layer
25	USE restart ! only for lrst_oce
26	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
27	USE prtctl ! Print control
28	USE in_out_manager ! I/O manager
29	USE iom ! I/O manager library
30
31	IMPLICIT NONE
32	PRIVATE
33
34	PUBLIC zdf_gls ! routine called in step module
35	PUBLIC zdf_gls_init ! routine called in opa module
36	PUBLIC gls_rst ! routine called in step module
37
38	LOGICAL , PUBLIC, PARAMETER :: lk_zdfgls = .TRUE. !: TKE vertical mixing flag
39	REAL(wp), PUBLIC, DIMENSION(jpi,jpj,jpk) :: en !: now turbulent kinetic energy
40	REAL(wp), PUBLIC, DIMENSION(jpi,jpj,jpk) :: mxln !: now mixing length
41	REAL(wp), PUBLIC, DIMENSION(jpi,jpj,jpk) :: zwall !: wall function
42	REAL(wp), PUBLIC, DIMENSION(jpi,jpj) :: ustars2 !: Squared surface velocity scale at T-points
43	REAL(wp), PUBLIC, DIMENSION(jpi,jpj) :: ustarb2 !: Squared bottom velocity scale at T-points
44
45	! !!! Namelist namzdf_gls
46	LOGICAL :: ln_crban = .FALSE. ! =T use Craig and Banner scheme
47	LOGICAL :: ln_length_lim = .FALSE. ! use limit on the dissipation rate under stable stratification (Galperin et al. 1988)
48	LOGICAL :: ln_sigpsi = .FALSE. ! Activate Burchard (2003) modification for k-eps closure & wave breaking mixing
49	INTEGER :: nn_tkebc_surf = 0 ! TKE surface boundary condition (=0/1)
50	INTEGER :: nn_tkebc_bot = 0 ! TKE bottom boundary condition (=0/1)
51	INTEGER :: nn_psibc_surf = 0 ! PSI surface boundary condition (=0/1)
52	INTEGER :: nn_psibc_bot = 0 ! PSI bottom boundary condition (=0/1)
53	INTEGER :: nn_stab_func = 0 ! stability functions G88, KC or Canuto (=0/1/2)
54	INTEGER :: nn_clos = 0 ! closure 0/1/2/3 MY82/k-eps/k-w/gen
55	REAL(wp) :: rn_clim_galp = 0.53_wp ! Holt 2008 value for k-eps: 0.267
56	REAL(wp) :: rn_epsmin = 1.e-12_wp ! minimum value of dissipation (m2/s3)
57	REAL(wp) :: rn_emin = 1.e-6_wp ! minimum value of TKE (m2/s2)
58	REAL(wp) :: rn_charn = 2.e+5_wp ! Charnock constant for surface breaking waves mixing : 1400. (standard) or 2.e5 (Stacey value)
59	REAL(wp) :: rn_crban = 100._wp ! Craig and Banner constant for surface breaking waves mixing
60
61	REAL(wp) :: hsro = 0.003_wp ! Minimum surface roughness
62	REAL(wp) :: hbro = 0.003_wp ! Bottom roughness (m)
63	REAL(wp) :: rcm_sf = 0.73_wp ! Shear free turbulence parameters
64	REAL(wp) :: ra_sf = -2.0_wp ! Must be negative -2 < ra_sf < -1
65	REAL(wp) :: rl_sf = 0.2_wp ! 0 <rl_sf<vkarmn
66	REAL(wp) :: rghmin = -0.28_wp
67	REAL(wp) :: rgh0 = 0.0329_wp
68	REAL(wp) :: rghcri = 0.03_wp
69	REAL(wp) :: ra1 = 0.92_wp
70	REAL(wp) :: ra2 = 0.74_wp
71	REAL(wp) :: rb1 = 16.60_wp
72	REAL(wp) :: rb2 = 10.10_wp
73	REAL(wp) :: re2 = 1.33_wp
74	REAL(wp) :: rl1 = 0.107_wp
75	REAL(wp) :: rl2 = 0.0032_wp
76	REAL(wp) :: rl3 = 0.0864_wp
77	REAL(wp) :: rl4 = 0.12_wp
78	REAL(wp) :: rl5 = 11.9_wp
79	REAL(wp) :: rl6 = 0.4_wp
80	REAL(wp) :: rl7 = 0.0_wp
81	REAL(wp) :: rl8 = 0.48_wp
82	REAL(wp) :: rm1 = 0.127_wp
83	REAL(wp) :: rm2 = 0.00336_wp
84	REAL(wp) :: rm3 = 0.0906_wp
85	REAL(wp) :: rm4 = 0.101_wp
86	REAL(wp) :: rm5 = 11.2_wp
87	REAL(wp) :: rm6 = 0.4_wp
88	REAL(wp) :: rm7 = 0.0_wp
89	REAL(wp) :: rm8 = 0.318_wp
90
91	REAL(wp) :: rc02, rc02r, rc03, rc04 ! coefficients deduced from above parameters
92	REAL(wp) :: rc03_sqrt2_galp ! - - - -
93	REAL(wp) :: rsbc_tke1, rsbc_tke2, rsbc_tke3, rfact_tke ! - - - -
94	REAL(wp) :: rsbc_psi1, rsbc_psi2, rsbc_psi3, rfact_psi ! - - - -
95	REAL(wp) :: rsbc_mb , rsbc_std , rsbc_zs ! - - - -
96	REAL(wp) :: rc0, rc2, rc3, rf6, rcff, rc_diff ! - - - -
97	REAL(wp) :: rs0, rs1, rs2, rs4, rs5, rs6 ! - - - -
98	REAL(wp) :: rd0, rd1, rd2, rd3, rd4, rd5 ! - - - -
99	REAL(wp) :: rsc_tke, rsc_psi, rpsi1, rpsi2, rpsi3, rsc_psi0 ! - - - -
100	REAL(wp) :: rpsi3m, rpsi3p, rpp, rmm, rnn ! - - - -
101
102	!! * Substitutions
103	# include "domzgr_substitute.h90"
104	# include "vectopt_loop_substitute.h90"
105	!!----------------------------------------------------------------------
106	!! NEMO/OPA 3.3 , NEMO Consortium (2010)
107	!! $Id $
108	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
109	!!----------------------------------------------------------------------
110	CONTAINS
111
112	SUBROUTINE zdf_gls( kt )
113	!!----------------------------------------------------------------------
114	!! * ROUTINE zdf_gls *
115	!!
116	!! ** Purpose : Compute the vertical eddy viscosity and diffusivity
117	!! coefficients using the GLS turbulent closure scheme.
118	!!----------------------------------------------------------------------
119	USE oce, z_elem_a => ua ! use ua as workspace
120	USE oce, z_elem_b => va ! use va as workspace
121	USE oce, z_elem_c => ta ! use ta as workspace
122	USE oce, psi => sa ! use sa as workspace
123	!
124	INTEGER, INTENT(in) :: kt ! ocean time step
125	INTEGER :: ji, jj, jk, ibot, ibotm1, dir ! dummy loop arguments
126	REAL(wp) :: zesh2, zsigpsi, zcoef, zex1, zex2 ! local scalars
127	REAL(wp) :: ztx2, zty2, zup, zdown, zcof ! - -
128	REAL(wp) :: zratio, zrn2, zflxb, sh ! - -
129	REAL(wp) :: prod, buoy, diss, zdiss, sm ! - -
130	REAL(wp) :: gh, gm, shr, dif, zsqen, zav ! - -
131	REAL(wp), DIMENSION(jpi,jpj) :: zdep !
132	REAL(wp), DIMENSION(jpi,jpj) :: zflxs ! Turbulence fluxed induced by internal waves
133	REAL(wp), DIMENSION(jpi,jpj) :: zhsro ! Surface roughness (surface waves)
134	REAL(wp), DIMENSION(jpi,jpj,jpk) :: eb ! tke at time before
135	REAL(wp), DIMENSION(jpi,jpj,jpk) :: mxlb ! mixing length at time before
136	REAL(wp), DIMENSION(jpi,jpj,jpk) :: shear ! vertical shear
137	REAL(wp), DIMENSION(jpi,jpj,jpk) :: eps ! dissipation rate
138	REAL(wp), DIMENSION(jpi,jpj,jpk) :: zwall_psi ! Wall function use in the wb case (ln_sigpsi.AND.ln_crban=T)
139	!!--------------------------------------------------------------------
140
141	! Preliminary computing
142
143	ustars2 = 0._wp ; ustarb2 = 0._wp ; psi = 0._wp ; zwall_psi = 0._wp
144
145	! Compute surface and bottom friction at T-points
146	!CDIR NOVERRCHK
147	DO jj = 2, jpjm1
148	!CDIR NOVERRCHK
149	DO ji = fs_2, fs_jpim1 ! vector opt.
150	!
151	! surface friction
152	ustars2(ji,jj) = rau0r * taum(ji,jj) * tmask(ji,jj,1)
153	!
154	! bottom friction (explicit before friction)
155	! Note that we chose here not to bound the friction as in dynbfr)
156	ztx2 = ( bfrua(ji,jj) * ub(ji,jj,mbku(ji,jj)) + bfrua(ji-1,jj) * ub(ji-1,jj,mbku(ji-1,jj)) ) &
157	& * ( 1._wp - 0.5_wp * umask(ji,jj,1) * umask(ji-1,jj,1) )
158	zty2 = ( bfrva(ji,jj) * vb(ji,jj,mbkv(ji,jj)) + bfrva(ji,jj-1) * vb(ji,jj-1,mbkv(ji,jj-1)) ) &
159	& * ( 1._wp - 0.5_wp * vmask(ji,jj,1) * vmask(ji,jj-1,1) )
160	ustarb2(ji,jj) = SQRT( ztx2 * ztx2 + zty2 * zty2 ) * tmask(ji,jj,1)
161	END DO
162	END DO
163
164	! In case of breaking surface waves mixing,
165	! Compute surface roughness length according to Charnock formula:
166	IF( ln_crban ) THEN ; zhsro(:,:) = MAX(rsbc_zs * ustars2(:,:), hsro)
167	ELSE ; zhsro(:,:) = hsro
168	ENDIF
169
170	! Compute shear and dissipation rate
171	DO jk = 2, jpkm1
172	DO jj = 2, jpjm1
173	DO ji = fs_2, fs_jpim1 ! vector opt.
174	avmu(ji,jj,jk) = avmu(ji,jj,jk) * ( un(ji,jj,jk-1) - un(ji,jj,jk) ) &
175	& * ( ub(ji,jj,jk-1) - ub(ji,jj,jk) ) &
176	& / ( fse3uw_n(ji,jj,jk) &
177	& * fse3uw_b(ji,jj,jk) )
178	avmv(ji,jj,jk) = avmv(ji,jj,jk) * ( vn(ji,jj,jk-1) - vn(ji,jj,jk) ) &
179	& * ( vb(ji,jj,jk-1) - vb(ji,jj,jk) ) &
180	& / ( fse3vw_n(ji,jj,jk) &
181	& * fse3vw_b(ji,jj,jk) )
182	eps(ji,jj,jk) = rc03 * en(ji,jj,jk) * SQRT(en(ji,jj,jk)) / mxln(ji,jj,jk)
183	END DO
184	END DO
185	END DO
186	!
187	! Lateral boundary conditions (avmu,avmv) (sign unchanged)
188	CALL lbc_lnk( avmu, 'U', 1. ) ; CALL lbc_lnk( avmv, 'V', 1. )
189
190	! Save tke at before time step
191	eb (:,:,:) = en (:,:,:)
192	mxlb(:,:,:) = mxln(:,:,:)
193
194	IF( nn_clos == 0 ) THEN ! Mellor-Yamada
195	DO jk = 2, jpkm1
196	DO jj = 2, jpjm1
197	DO ji = fs_2, fs_jpim1 ! vector opt.
198	zup = mxln(ji,jj,jk) * fsdepw(ji,jj,mbkt(ji,jj)+1)
199	zdown = vkarmn * fsdepw(ji,jj,jk) * ( -fsdepw(ji,jj,jk) + fsdepw(ji,jj,mbkt(ji,jj)+1) )
200	zcoef = ( zup / MAX( zdown, rsmall ) )
201	zwall (ji,jj,jk) = ( 1._wp + re2 * zcoefzcoef ) tmask(ji,jj,jk)
202	END DO
203	END DO
204	END DO
205	ENDIF
206
207	!!---------------------------------!!
208	!! Equation to prognostic k !!
209	!!---------------------------------!!
210	!
211	! Now Turbulent kinetic energy (output in en)
212	! -------------------------------
213	! Resolution of a tridiagonal linear system by a "methode de chasse"
214	! computation from level 2 to jpkm1 (e(1) computed after and e(jpk)=0 ).
215	! The surface boundary condition are set after
216	! The bottom boundary condition are also set after. In standard e(bottom)=0.
217	! z_elem_b : diagonal z_elem_c : upper diagonal z_elem_a : lower diagonal
218	! Warning : after this step, en : right hand side of the matrix
219
220	DO jk = 2, jpkm1
221	DO jj = 2, jpjm1
222	DO ji = fs_2, fs_jpim1 ! vector opt.
223	!
224	! shear prod. at w-point weightened by mask
225	shear(ji,jj,jk) = ( avmu(ji-1,jj,jk) + avmu(ji,jj,jk) ) / MAX( 1.e0 , umask(ji-1,jj,jk) + umask(ji,jj,jk) ) &
226	& + ( avmv(ji,jj-1,jk) + avmv(ji,jj,jk) ) / MAX( 1.e0 , vmask(ji,jj-1,jk) + vmask(ji,jj,jk) )
227	!
228	! stratif. destruction
229	buoy = - avt(ji,jj,jk) * rn2(ji,jj,jk)
230	!
231	! shear prod. - stratif. destruction
232	diss = eps(ji,jj,jk)
233	!
234	dir = 0.5_wp + SIGN( 0.5_wp, shear(ji,jj,jk) + buoy ) ! dir =1(=0) if shear(ji,jj,jk)+buoy >0(<0)
235	!
236	zesh2 = dir(shear(ji,jj,jk)+buoy)+(1._wp-dir)shear(ji,jj,jk) ! production term
237	zdiss = dir(diss/en(ji,jj,jk)) +(1._wp-dir)(diss-buoy)/en(ji,jj,jk) ! dissipation term
238	!
239	! Compute a wall function from 1. to rsc_psi*zwall/rsc_psi0
240	! Note that as long that Dirichlet boundary conditions are NOT set at the first and last levels (GOTM style)
241	! there is no need to set a boundary condition for zwall_psi at the top and bottom boundaries.
242	! Otherwise, this should be rsc_psi/rsc_psi0
243	IF( ln_sigpsi ) THEN
244	zsigpsi = MIN( 1._wp, zesh2 / eps(ji,jj,jk) ) ! 0. <= zsigpsi <= 1.
245	zwall_psi(ji,jj,jk) = rsc_psi / ( zsigpsi * rsc_psi + (1._wp-zsigpsi) * rsc_psi0 / MAX( zwall(ji,jj,jk), 1._wp ) )
246	ELSE
247	zwall_psi(ji,jj,jk) = 1._wp
248	ENDIF
249	!
250	! building the matrix
251	zcof = rfact_tke * tmask(ji,jj,jk)
252	!
253	! lower diagonal
254	z_elem_a(ji,jj,jk) = zcof * ( avm (ji,jj,jk ) + avm (ji,jj,jk-1) ) &
255	& / ( fse3t(ji,jj,jk-1) * fse3w(ji,jj,jk ) )
256	!
257	! upper diagonal
258	z_elem_c(ji,jj,jk) = zcof * ( avm (ji,jj,jk+1) + avm (ji,jj,jk ) ) &
259	& / ( fse3t(ji,jj,jk ) * fse3w(ji,jj,jk) )
260	!
261	! diagonal
262	z_elem_b(ji,jj,jk) = 1._wp - z_elem_a(ji,jj,jk) - z_elem_c(ji,jj,jk) &
263	& + rdt * zdiss * tmask(ji,jj,jk)
264	!
265	! right hand side in en
266	en(ji,jj,jk) = en(ji,jj,jk) + rdt * zesh2 * tmask(ji,jj,jk)
267	END DO
268	END DO
269	END DO
270	!
271	z_elem_b(:,:,jpk) = 1._wp
272	!
273	! Set surface condition on zwall_psi (1 at the bottom)
274	IF( ln_sigpsi ) THEN
275	zcoef = rsc_psi / rsc_psi0
276	DO jj = 2, jpjm1
277	DO ji = fs_2, fs_jpim1 ! vector opt.
278	zwall_psi(ji,jj,1) = zcoef
279	END DO
280	END DO
281	ENDIF
282
283	! Surface boundary condition on tke
284	! ---------------------------------
285	!
286	SELECT CASE ( nn_tkebc_surf )
287	!
288	CASE ( 0 ) ! Dirichlet case
289	!
290	IF (ln_crban) THEN ! Wave induced mixing case
291	! ! en(1) = q2(1) = 0.5 * (15.8 * Ccb)^(2/3) * u*^2
292	! ! balance between the production and the dissipation terms including the wave effect
293	en(:,:,1) = MAX( rsbc_tke1 * ustars2(:,:), rn_emin )
294	z_elem_a(:,:,1) = en(:,:,1)
295	z_elem_c(:,:,1) = 0._wp
296	z_elem_b(:,:,1) = 1._wp
297	!
298	! one level below
299	en(:,:,2) = MAX( rsbc_tke1 * ustars2(:,:) * ( (zhsro(:,:)+fsdepw(:,:,2))/zhsro(:,:) )**ra_sf, rn_emin )
300	z_elem_a(:,:,2) = 0._wp
301	z_elem_c(:,:,2) = 0._wp
302	z_elem_b(:,:,2) = 1._wp
303	!
304	ELSE ! No wave induced mixing case
305	! ! en(1) = u^2/C0^2 & l(1) = Kzs
306	! ! balance between the production and the dissipation terms
307	en(:,:,1) = MAX( rc02r * ustars2(:,:), rn_emin )
308	z_elem_a(:,:,1) = en(:,:,1)
309	z_elem_c(:,:,1) = 0._wp
310	z_elem_b(:,:,1) = 1._wp
311	!
312	! one level below
313	en(:,:,2) = MAX( rc02r * ustars2(:,:), rn_emin )
314	z_elem_a(:,:,2) = 0._wp
315	z_elem_c(:,:,2) = 0._wp
316	z_elem_b(:,:,2) = 1._wp
317	!
318	ENDIF
319	!
320	CASE ( 1 ) ! Neumann boundary condition on d(e)/dz
321	!
322	IF (ln_crban) THEN ! Shear free case: d(e)/dz= Fw
323	!
324	! Dirichlet conditions at k=1 (Cosmetic)
325	en(:,:,1) = MAX( rsbc_tke1 * ustars2(:,:), rn_emin )
326	z_elem_a(:,:,1) = en(:,:,1)
327	z_elem_c(:,:,1) = 0._wp
328	z_elem_b(:,:,1) = 1._wp
329	! at k=2, set de/dz=Fw
330	z_elem_b(:,:,2) = z_elem_b(:,:,2) + z_elem_a(:,:,2) ! Remove z_elem_a from z_elem_b
331	z_elem_a(:,:,2) = 0._wp
332	zflxs(:,:) = rsbc_tke3 * ustars2(:,:)*1.5_wp ( (zhsro(:,:)+fsdept(:,:,1) ) / zhsro(:,:) )*(1.5ra_sf)
333	en(:,:,2) = en(:,:,2) + zflxs(:,:) / fse3w(:,:,2)
334	!
335	ELSE ! No wave induced mixing case: d(e)/dz=0.
336	!
337	! Dirichlet conditions at k=1 (Cosmetic)
338	en(:,:,1) = MAX( rc02r * ustars2(:,:), rn_emin )
339	z_elem_a(:,:,1) = en(:,:,1)
340	z_elem_c(:,:,1) = 0._wp
341	z_elem_b(:,:,1) = 1._wp
342	! at k=2 set de/dz=0.:
343	z_elem_b(:,:,2) = z_elem_b(:,:,2) + z_elem_a(:,:,2) ! Remove z_elem_a from z_elem_b
344	z_elem_a(:,:,2) = 0._wp
345	!
346	ENDIF
347	!
348	END SELECT
349
350	! Bottom boundary condition on tke
351	! --------------------------------
352	!
353	SELECT CASE ( nn_tkebc_bot )
354	!
355	CASE ( 0 ) ! Dirichlet
356	! ! en(ibot) = u*^2 / Co2 and mxln(ibot) = rn_lmin
357	! ! Balance between the production and the dissipation terms
358	!CDIR NOVERRCHK
359	DO jj = 2, jpjm1
360	!CDIR NOVERRCHK
361	DO ji = fs_2, fs_jpim1 ! vector opt.
362	ibot = mbkt(ji,jj) + 1 ! k bottom level of w-point
363	ibotm1 = mbkt(ji,jj) ! k-1 bottom level of w-point but >=1
364	!
365	! Bottom level Dirichlet condition:
366	z_elem_a(ji,jj,ibot ) = 0._wp
367	z_elem_c(ji,jj,ibot ) = 0._wp
368	z_elem_b(ji,jj,ibot ) = 1._wp
369	en(ji,jj,ibot ) = MAX( rc02r * ustarb2(ji,jj), rn_emin )
370	!
371	! Just above last level, Dirichlet condition again
372	z_elem_a(ji,jj,ibotm1) = 0._wp
373	z_elem_c(ji,jj,ibotm1) = 0._wp
374	z_elem_b(ji,jj,ibotm1) = 1._wp
375	en(ji,jj,ibotm1) = MAX( rc02r * ustarb2(ji,jj), rn_emin )
376	END DO
377	END DO
378	!
379	CASE ( 1 ) ! Neumman boundary condition
380	!
381	!CDIR NOVERRCHK
382	DO jj = 2, jpjm1
383	!CDIR NOVERRCHK
384	DO ji = fs_2, fs_jpim1 ! vector opt.
385	ibot = mbkt(ji,jj) + 1 ! k bottom level of w-point
386	ibotm1 = mbkt(ji,jj) ! k-1 bottom level of w-point but >=1
387	!
388	! Bottom level Dirichlet condition:
389	z_elem_a(ji,jj,ibot) = 0._wp
390	z_elem_c(ji,jj,ibot) = 0._wp
391	z_elem_b(ji,jj,ibot) = 1._wp
392	en(ji,jj,ibot) = MAX( rc02r * ustarb2(ji,jj), rn_emin )
393	!
394	! Just above last level: Neumann condition
395	z_elem_b(ji,jj,ibotm1) = z_elem_b(ji,jj,ibotm1) + z_elem_c(ji,jj,ibotm1) ! Remove z_elem_c from z_elem_b
396	z_elem_c(ji,jj,ibotm1) = 0._wp
397	END DO
398	END DO
399	!
400	END SELECT
401
402	! Matrix inversion (en prescribed at surface and the bottom)
403	! ----------------------------------------------------------
404	!
405	DO jk = 2, jpkm1 ! First recurrence : Dk = Dk - Lk * Uk-1 / Dk-1
406	DO jj = 2, jpjm1
407	DO ji = fs_2, fs_jpim1 ! vector opt.
408	z_elem_b(ji,jj,jk) = z_elem_b(ji,jj,jk) - z_elem_a(ji,jj,jk) * z_elem_c(ji,jj,jk-1) / z_elem_b(ji,jj,jk-1)
409	END DO
410	END DO
411	END DO
412	DO jk = 2, jpk ! Second recurrence : Lk = RHSk - Lk / Dk-1 * Lk-1
413	DO jj = 2, jpjm1
414	DO ji = fs_2, fs_jpim1 ! vector opt.
415	z_elem_a(ji,jj,jk) = en(ji,jj,jk) - z_elem_a(ji,jj,jk) / z_elem_b(ji,jj,jk-1) * z_elem_a(ji,jj,jk-1)
416	END DO
417	END DO
418	END DO
419	DO jk = jpk-1, 2, -1 ! thrid recurrence : Ek = ( Lk - Uk * Ek+1 ) / Dk
420	DO jj = 2, jpjm1
421	DO ji = fs_2, fs_jpim1 ! vector opt.
422	en(ji,jj,jk) = ( z_elem_a(ji,jj,jk) - z_elem_c(ji,jj,jk) * en(ji,jj,jk+1) ) / z_elem_b(ji,jj,jk)
423	END DO
424	END DO
425	END DO
426	! ! set the minimum value of tke
427	en(:,:,:) = MAX( en(:,:,:), rn_emin )
428
429	!!----------------------------------------!!
430	!! Solve prognostic equation for psi !!
431	!!----------------------------------------!!
432
433	! Set psi to previous time step value
434	!
435	SELECT CASE ( nn_clos )
436	!
437	CASE( 0 ) ! k-kl (Mellor-Yamada)
438	DO jk = 2, jpkm1
439	DO jj = 2, jpjm1
440	DO ji = fs_2, fs_jpim1 ! vector opt.
441	psi(ji,jj,jk) = en(ji,jj,jk) * mxln(ji,jj,jk)
442	END DO
443	END DO
444	END DO
445	!
446	CASE( 1 ) ! k-eps
447	DO jk = 2, jpkm1
448	DO jj = 2, jpjm1
449	DO ji = fs_2, fs_jpim1 ! vector opt.
450	psi(ji,jj,jk) = eps(ji,jj,jk)
451	END DO
452	END DO
453	END DO
454	!
455	CASE( 2 ) ! k-w
456	DO jk = 2, jpkm1
457	DO jj = 2, jpjm1
458	DO ji = fs_2, fs_jpim1 ! vector opt.
459	psi(ji,jj,jk) = SQRT( en(ji,jj,jk) ) / ( rc0 * mxln(ji,jj,jk) )
460	END DO
461	END DO
462	END DO
463	!
464	CASE( 3 ) ! generic
465	DO jk = 2, jpkm1
466	DO jj = 2, jpjm1
467	DO ji = fs_2, fs_jpim1 ! vector opt.
468	psi(ji,jj,jk) = rc02 * en(ji,jj,jk) * mxln(ji,jj,jk)**rnn
469	END DO
470	END DO
471	END DO
472	!
473	END SELECT
474	!
475	! Now gls (output in psi)
476	! -------------------------------
477	! Resolution of a tridiagonal linear system by a "methode de chasse"
478	! computation from level 2 to jpkm1 (e(1) already computed and e(jpk)=0 ).
479	! z_elem_b : diagonal z_elem_c : upper diagonal z_elem_a : lower diagonal
480	! Warning : after this step, en : right hand side of the matrix
481
482	DO jk = 2, jpkm1
483	DO jj = 2, jpjm1
484	DO ji = fs_2, fs_jpim1 ! vector opt.
485	!
486	! psi / k
487	zratio = psi(ji,jj,jk) / eb(ji,jj,jk)
488	!
489	! psi3+ : stable : B=-KhN²<0 => N²>0 if rn2>0 dir = 1 (stable) otherwise dir = 0 (unstable)
490	dir = 0.5_wp + SIGN( 0.5_wp, rn2(ji,jj,jk) )
491	!
492	rpsi3 = dir * rpsi3m + ( 1._wp - dir ) * rpsi3p
493	!
494	! shear prod. - stratif. destruction
495	prod = rpsi1 * zratio * shear(ji,jj,jk)
496	!
497	! stratif. destruction
498	buoy = rpsi3 * zratio * (- avt(ji,jj,jk) * rn2(ji,jj,jk) )
499	!
500	! shear prod. - stratif. destruction
501	diss = rpsi2 * zratio * zwall(ji,jj,jk) * eps(ji,jj,jk)
502	!
503	dir = 0.5_wp + SIGN( 0.5_wp, prod + buoy ) ! dir =1(=0) if shear(ji,jj,jk)+buoy >0(<0)
504	!
505	zesh2 = dir * ( prod + buoy ) + (1._wp - dir ) * prod ! production term
506	zdiss = dir * ( diss / psi(ji,jj,jk) ) + (1._wp - dir ) * (diss-buoy) / psi(ji,jj,jk) ! dissipation term
507	!
508	! building the matrix
509	zcof = rfact_psi * zwall_psi(ji,jj,jk) * tmask(ji,jj,jk)
510	! lower diagonal
511	z_elem_a(ji,jj,jk) = zcof * ( avm (ji,jj,jk ) + avm (ji,jj,jk-1) ) &
512	& / ( fse3t(ji,jj,jk-1) * fse3w(ji,jj,jk ) )
513	! upper diagonal
514	z_elem_c(ji,jj,jk) = zcof * ( avm (ji,jj,jk+1) + avm (ji,jj,jk ) ) &
515	& / ( fse3t(ji,jj,jk ) * fse3w(ji,jj,jk) )
516	! diagonal
517	z_elem_b(ji,jj,jk) = 1._wp - z_elem_a(ji,jj,jk) - z_elem_c(ji,jj,jk) &
518	& + rdt * zdiss * tmask(ji,jj,jk)
519	!
520	! right hand side in psi
521	psi(ji,jj,jk) = psi(ji,jj,jk) + rdt * zesh2 * tmask(ji,jj,jk)
522	END DO
523	END DO
524	END DO
525	!
526	z_elem_b(:,:,jpk) = 1._wp
527
528	! Surface boundary condition on psi
529	! ---------------------------------
530	!
531	SELECT CASE ( nn_psibc_surf )
532	!
533	CASE ( 0 ) ! Dirichlet boundary conditions
534	!
535	IF( ln_crban ) THEN ! Wave induced mixing case
536	! ! en(1) = q2(1) = 0.5 * (15.8 * Ccb)^(2/3) * u*^2
537	! ! balance between the production and the dissipation terms including the wave effect
538	zdep(:,:) = rl_sf * zhsro(:,:)
539	psi (:,:,1) = rc0*rpp en(:,:,1)*rmm zdep(:,:)*rnn tmask(:,:,1)
540	z_elem_a(:,:,1) = psi(:,:,1)
541	z_elem_c(:,:,1) = 0._wp
542	z_elem_b(:,:,1) = 1._wp
543	!
544	! one level below
545	zex1 = (rmm*ra_sf+rnn)
546	zex2 = (rmm*ra_sf)
547	zdep(:,:) = ( (zhsro(:,:) + fsdepw(:,:,2))zex1 ) / zhsro(:,:)zex2
548	psi (:,:,2) = rsbc_psi1 * ustars2(:,:)*rmm zdep(:,:) * tmask(:,:,1)
549	z_elem_a(:,:,2) = 0._wp
550	z_elem_c(:,:,2) = 0._wp
551	z_elem_b(:,:,2) = 1._wp
552	!
553	ELSE ! No wave induced mixing case
554	! ! en(1) = u^2/C0^2 & l(1) = Kzs
555	! ! balance between the production and the dissipation terms
556	!
557	zdep(:,:) = vkarmn * zhsro(:,:)
558	psi (:,:,1) = rc0*rpp en(:,:,1)*rmm zdep(:,:)*rnn tmask(:,:,1)
559	z_elem_a(:,:,1) = psi(:,:,1)
560	z_elem_c(:,:,1) = 0._wp
561	z_elem_b(:,:,1) = 1._wp
562	!
563	! one level below
564	zdep(:,:) = vkarmn * ( zhsro(:,:) + fsdepw(:,:,2) )
565	psi (:,:,2) = rc0*rpp en(:,:,1)*rmm zdep(:,:)*rnn tmask(:,:,1)
566	z_elem_a(:,:,2) = 0._wp
567	z_elem_c(:,:,2) = 0._wp
568	z_elem_b(:,:,2) = 1.
569	!
570	ENDIF
571	!
572	CASE ( 1 ) ! Neumann boundary condition on d(psi)/dz
573	!
574	IF( ln_crban ) THEN ! Wave induced mixing case
575	!
576	zdep(:,:) = rl_sf * zhsro(:,:)
577	psi (:,:,1) = rc0*rpp en(:,:,1)*rmm zdep(:,:)*rnn tmask(:,:,1)
578	z_elem_a(:,:,1) = psi(:,:,1)
579	z_elem_c(:,:,1) = 0._wp
580	z_elem_b(:,:,1) = 1._wp
581	!
582	! Neumann condition at k=2
583	z_elem_b(:,:,2) = z_elem_b(:,:,2) + z_elem_a(:,:,2) ! Remove z_elem_a from z_elem_b
584	z_elem_a(:,:,2) = 0._wp
585	!
586	! Set psi vertical flux at the surface:
587	zdep(:,:) = (zhsro(:,:) + fsdept(:,:,1))*(rmmra_sf+rnn-1._wp) / zhsro(:,:)*(rmmra_sf)
588	zflxs(:,:) = rsbc_psi3 * ( zwall_psi(:,:,1)avm(:,:,1) + zwall_psi(:,:,2)avm(:,:,2) ) &
589	& * en(:,:,1)*rmm zdep
590	psi(:,:,2) = psi(:,:,2) + zflxs(:,:) / fse3w(:,:,2)
591	!
592	ELSE ! No wave induced mixing
593	!
594	zdep(:,:) = vkarmn * zhsro(:,:)
595	psi (:,:,1) = rc0*rpp en(:,:,1)*rmm zdep(:,:)*rnn tmask(:,:,1)
596	z_elem_a(:,:,1) = psi(:,:,1)
597	z_elem_c(:,:,1) = 0._wp
598	z_elem_b(:,:,1) = 1._wp
599	!
600	! Neumann condition at k=2
601	z_elem_b(:,:,2) = z_elem_b(:,:,2) + z_elem_a(:,:,2) ! Remove z_elem_a from z_elem_b
602	z_elem_a(ji,jj,2) = 0._wp
603	!
604	! Set psi vertical flux at the surface:
605	zdep(:,:) = zhsro(:,:) + fsdept(:,:,1)
606	zflxs(:,:) = rsbc_psi2 * ( avm(:,:,1) + avm(:,:,2) ) * en(:,:,1)*rmm zdep**(rnn-1._wp)
607	psi(:,:,2) = psi(:,:,2) + zflxs(:,:) / fse3w(:,:,2)
608	!
609	ENDIF
610	!
611	END SELECT
612
613	! Bottom boundary condition on psi
614	! --------------------------------
615	!
616	SELECT CASE ( nn_psibc_bot )
617	!
618	CASE ( 0 ) ! Dirichlet
619	! ! en(ibot) = u^2 / Co2 and mxln(ibot) = vkarmn hbro
620	! ! Balance between the production and the dissipation terms
621	!CDIR NOVERRCHK
622	DO jj = 2, jpjm1
623	!CDIR NOVERRCHK
624	DO ji = fs_2, fs_jpim1 ! vector opt.
625	ibot = mbkt(ji,jj) + 1 ! k bottom level of w-point
626	ibotm1 = mbkt(ji,jj) ! k-1 bottom level of w-point but >=1
627	zdep(ji,jj) = vkarmn * hbro
628	psi (ji,jj,ibot) = rc0*rpp en(ji,jj,ibot)*rmm zdep(ji,jj)**rnn
629	z_elem_a(ji,jj,ibot) = 0._wp
630	z_elem_c(ji,jj,ibot) = 0._wp
631	z_elem_b(ji,jj,ibot) = 1._wp
632	!
633	! Just above last level, Dirichlet condition again (GOTM like)
634	zdep(ji,jj) = vkarmn * ( hbro + fse3t(ji,jj,ibotm1) )
635	psi (ji,jj,ibotm1) = rc0*rpp en(ji,jj,ibot )*rmm zdep(ji,jj)**rnn
636	z_elem_a(ji,jj,ibotm1) = 0._wp
637	z_elem_c(ji,jj,ibotm1) = 0._wp
638	z_elem_b(ji,jj,ibotm1) = 1._wp
639	END DO
640	END DO
641	!
642	CASE ( 1 ) ! Neumman boundary condition
643	!
644	!CDIR NOVERRCHK
645	DO jj = 2, jpjm1
646	!CDIR NOVERRCHK
647	DO ji = fs_2, fs_jpim1 ! vector opt.
648	ibot = mbkt(ji,jj) + 1 ! k bottom level of w-point
649	ibotm1 = mbkt(ji,jj) ! k-1 bottom level of w-point but >=1
650	!
651	! Bottom level Dirichlet condition:
652	zdep(ji,jj) = vkarmn * hbro
653	psi (ji,jj,ibot) = rc0*rpp en(ji,jj,ibot)*rmm zdep(ji,jj)**rnn
654	!
655	z_elem_a(ji,jj,ibot) = 0._wp
656	z_elem_c(ji,jj,ibot) = 0._wp
657	z_elem_b(ji,jj,ibot) = 1._wp
658	!
659	! Just above last level: Neumann condition with flux injection
660	z_elem_b(ji,jj,ibotm1) = z_elem_b(ji,jj,ibotm1) + z_elem_c(ji,jj,ibotm1) ! Remove z_elem_c from z_elem_b
661	z_elem_c(ji,jj,ibotm1) = 0.
662	!
663	! Set psi vertical flux at the bottom:
664	zdep(ji,jj) = hbro + 0.5_wp*fse3t(ji,jj,ibotm1)
665	zflxb = rsbc_psi2 * ( avm(ji,jj,ibot) + avm(ji,jj,ibotm1) ) &
666	& * (0.5_wp(en(ji,jj,ibot)+en(ji,jj,ibotm1)))rmm zdep(ji,jj)**(rnn-1._wp)
667	psi(ji,jj,ibotm1) = psi(ji,jj,ibotm1) + zflxb / fse3w(ji,jj,ibotm1)
668	END DO
669	END DO
670	!
671	END SELECT
672
673	! Matrix inversion
674	! ----------------
675	!
676	DO jk = 2, jpkm1 ! First recurrence : Dk = Dk - Lk * Uk-1 / Dk-1
677	DO jj = 2, jpjm1
678	DO ji = fs_2, fs_jpim1 ! vector opt.
679	z_elem_b(ji,jj,jk) = z_elem_b(ji,jj,jk) - z_elem_a(ji,jj,jk) * z_elem_c(ji,jj,jk-1) / z_elem_b(ji,jj,jk-1)
680	END DO
681	END DO
682	END DO
683	DO jk = 2, jpk ! Second recurrence : Lk = RHSk - Lk / Dk-1 * Lk-1
684	DO jj = 2, jpjm1
685	DO ji = fs_2, fs_jpim1 ! vector opt.
686	z_elem_a(ji,jj,jk) = psi(ji,jj,jk) - z_elem_a(ji,jj,jk) / z_elem_b(ji,jj,jk-1) * z_elem_a(ji,jj,jk-1)
687	END DO
688	END DO
689	END DO
690	DO jk = jpk-1, 2, -1 ! Third recurrence : Ek = ( Lk - Uk * Ek+1 ) / Dk
691	DO jj = 2, jpjm1
692	DO ji = fs_2, fs_jpim1 ! vector opt.
693	psi(ji,jj,jk) = ( z_elem_a(ji,jj,jk) - z_elem_c(ji,jj,jk) * psi(ji,jj,jk+1) ) / z_elem_b(ji,jj,jk)
694	END DO
695	END DO
696	END DO
697
698	! Set dissipation
699	!----------------
700
701	SELECT CASE ( nn_clos )
702	!
703	CASE( 0 ) ! k-kl (Mellor-Yamada)
704	DO jk = 1, jpkm1
705	DO jj = 2, jpjm1
706	DO ji = fs_2, fs_jpim1 ! vector opt.
707	eps(ji,jj,jk) = rc03 * en(ji,jj,jk) * en(ji,jj,jk) * SQRT( en(ji,jj,jk) ) / psi(ji,jj,jk)
708	END DO
709	END DO
710	END DO
711	!
712	CASE( 1 ) ! k-eps
713	DO jk = 1, jpkm1
714	DO jj = 2, jpjm1
715	DO ji = fs_2, fs_jpim1 ! vector opt.
716	eps(ji,jj,jk) = psi(ji,jj,jk)
717	END DO
718	END DO
719	END DO
720	!
721	CASE( 2 ) ! k-w
722	DO jk = 1, jpkm1
723	DO jj = 2, jpjm1
724	DO ji = fs_2, fs_jpim1 ! vector opt.
725	eps(ji,jj,jk) = rc04 * en(ji,jj,jk) * psi(ji,jj,jk)
726	END DO
727	END DO
728	END DO
729	!
730	CASE( 3 ) ! generic
731	zcoef = rc0**( 3._wp + rpp/rnn )
732	zex1 = ( 1.5_wp + rmm/rnn )
733	zex2 = -1._wp / rnn
734	DO jk = 1, jpkm1
735	DO jj = 2, jpjm1
736	DO ji = fs_2, fs_jpim1 ! vector opt.
737	eps(ji,jj,jk) = zcoef * en(ji,jj,jk)*zex1 psi(ji,jj,jk)**zex2
738	END DO
739	END DO
740	END DO
741	!
742	END SELECT
743
744	! Limit dissipation rate under stable stratification
745	! --------------------------------------------------
746	DO jk = 1, jpkm1 ! Note that this set boundary conditions on mxln at the same time
747	DO jj = 2, jpjm1
748	DO ji = fs_2, fs_jpim1 ! vector opt.
749	! limitation
750	eps(ji,jj,jk) = MAX( eps(ji,jj,jk), rn_epsmin )
751	mxln(ji,jj,jk) = rc03 * en(ji,jj,jk) * SQRT( en(ji,jj,jk) ) / eps(ji,jj,jk)
752	! Galperin criterium (NOTE : Not required if the proper value of C3 in stable cases is calculated)
753	zrn2 = MAX( rn2(ji,jj,jk), rsmall )
754	mxln(ji,jj,jk) = MIN( rn_clim_galp * SQRT( 2._wp * en(ji,jj,jk) / zrn2 ), mxln(ji,jj,jk) )
755	END DO
756	END DO
757	END DO
758
759	!
760	! Stability function and vertical viscosity and diffusivity
761	! ---------------------------------------------------------
762	!
763	SELECT CASE ( nn_stab_func )
764	!
765	CASE ( 0 , 1 ) ! Galperin or Kantha-Clayson stability functions
766	DO jk = 2, jpkm1
767	DO jj = 2, jpjm1
768	DO ji = fs_2, fs_jpim1 ! vector opt.
769	! zcof = l²/q²
770	zcof = mxlb(ji,jj,jk) * mxlb(ji,jj,jk) / ( 2._wp*eb(ji,jj,jk) )
771	! Gh = -N²l²/q²
772	gh = - rn2(ji,jj,jk) * zcof
773	gh = MIN( gh, rgh0 )
774	gh = MAX( gh, rghmin )
775	! Stability functions from Kantha and Clayson (if C2=C3=0 => Galperin)
776	sh = ra2( 1._wp-6._wpra1/rb1 ) / ( 1.-3.ra2gh(6.ra1+rb2*( 1._wp-rc3 ) ) )
777	sm = ( rb1*(-1._wp/3._wp) + ( 18._wpra1ra1 + 9._wpra1ra2(1._wp-rc2) )shgh ) / (1._wp-9._wpra1ra2*gh)
778	!
779	! Store stability function in avmu and avmv
780	avmu(ji,jj,jk) = rc_diff * sh * tmask(ji,jj,jk)
781	avmv(ji,jj,jk) = rc_diff * sm * tmask(ji,jj,jk)
782	END DO
783	END DO
784	END DO
785	!
786	CASE ( 2, 3 ) ! Canuto stability functions
787	DO jk = 2, jpkm1
788	DO jj = 2, jpjm1
789	DO ji = fs_2, fs_jpim1 ! vector opt.
790	! zcof = l²/q²
791	zcof = mxlb(ji,jj,jk)mxlb(ji,jj,jk) / ( 2._wp eb(ji,jj,jk) )
792	! Gh = -N²l²/q²
793	gh = - rn2(ji,jj,jk) * zcof
794	gh = MIN( gh, rgh0 )
795	gh = MAX( gh, rghmin )
796	gh = gh * rf6
797	! Gm = M²l²/q² Shear number
798	shr = shear(ji,jj,jk) / MAX( avm(ji,jj,jk), rsmall )
799	gm = MAX( shr * zcof , 1.e-10 )
800	gm = gm * rf6
801	gm = MIN ( (rd0 - rd1gh + rd3ghgh) / (rd2-rd4gh) , gm )
802	! Stability functions from Canuto
803	rcff = rd0 - rd1gh +rd2gm + rd3ghgh - rd4ghgm + rd5gmgm
804	sm = (rs0 - rs1gh + rs2gm) / rcff
805	sh = (rs4 - rs5gh + rs6gm) / rcff
806	!
807	! Store stability function in avmu and avmv
808	avmu(ji,jj,jk) = rc_diff * sh * tmask(ji,jj,jk)
809	avmv(ji,jj,jk) = rc_diff * sm * tmask(ji,jj,jk)
810	END DO
811	END DO
812	END DO
813	!
814	END SELECT
815
816	! Boundary conditions on stability functions for momentum (Neumann):
817	! Lines below are useless if GOTM style Dirichlet conditions are used
818	zcoef = rcm_sf / SQRT( 2._wp )
819	DO jj = 2, jpjm1
820	DO ji = fs_2, fs_jpim1 ! vector opt.
821	avmv(ji,jj,1) = zcoef
822	END DO
823	END DO
824	zcoef = rc0 / SQRT( 2._wp )
825	DO jj = 2, jpjm1
826	DO ji = fs_2, fs_jpim1 ! vector opt.
827	avmv(ji,jj,mbkt(ji,jj)+1) = zcoef
828	END DO
829	END DO
830
831	! Compute diffusivities/viscosities
832	! The computation below could be restrained to jk=2 to jpkm1 if GOTM style Dirichlet conditions are used
833	DO jk = 1, jpk
834	DO jj = 2, jpjm1
835	DO ji = fs_2, fs_jpim1 ! vector opt.
836	zsqen = SQRT( 2._wp * en(ji,jj,jk) ) * mxln(ji,jj,jk)
837	zav = zsqen * avmu(ji,jj,jk)
838	avt(ji,jj,jk) = MAX( zav, avtb(jk) )*tmask(ji,jj,jk) ! apply mask for zdfmxl routine
839	zav = zsqen * avmv(ji,jj,jk)
840	avm(ji,jj,jk) = MAX( zav, avmb(jk) ) ! Note that avm is not masked at the surface and the bottom
841	END DO
842	END DO
843	END DO
844	!
845	! Lateral boundary conditions (sign unchanged)
846	avt(:,:,1) = 0._wp
847	CALL lbc_lnk( avm, 'W', 1. ) ; CALL lbc_lnk( avt, 'W', 1. )
848
849	DO jk = 2, jpkm1 !* vertical eddy viscosity at u- and v-points
850	DO jj = 2, jpjm1
851	DO ji = fs_2, fs_jpim1 ! vector opt.
852	avmu(ji,jj,jk) = 0.5 * ( avm(ji,jj,jk) + avm(ji+1,jj ,jk) ) * umask(ji,jj,jk)
853	avmv(ji,jj,jk) = 0.5 * ( avm(ji,jj,jk) + avm(ji ,jj+1,jk) ) * vmask(ji,jj,jk)
854	END DO
855	END DO
856	END DO
857	avmu(:,:,1) = 0._wp ; avmv(:,:,1) = 0._wp ! set surface to zero
858	CALL lbc_lnk( avmu, 'U', 1. ) ; CALL lbc_lnk( avmv, 'V', 1. ) ! Lateral boundary conditions
859
860	IF(ln_ctl) THEN
861	CALL prt_ctl( tab3d_1=en , clinfo1=' gls - e: ', tab3d_2=avt, clinfo2=' t: ', ovlap=1, kdim=jpk)
862	CALL prt_ctl( tab3d_1=avmu, clinfo1=' gls - u: ', mask1=umask, &
863	& tab3d_2=avmv, clinfo2= ' v: ', mask2=vmask, ovlap=1, kdim=jpk )
864	ENDIF
865	!
866	END SUBROUTINE zdf_gls
867
868
869	SUBROUTINE zdf_gls_init
870	!!----------------------------------------------------------------------
871	!! * ROUTINE zdf_gls_init *
872	!!
873	!! ** Purpose : Initialization of the vertical eddy diffivity and
874	!! viscosity when using a gls turbulent closure scheme
875	!!
876	!! ** Method : Read the namzdf_gls namelist and check the parameters
877	!! called at the first timestep (nit000)
878	!!
879	!! ** input : Namlist namzdf_gls
880	!!
881	!! ** Action : Increase by 1 the nstop flag is setting problem encounter
882	!!
883	!!----------------------------------------------------------------------
884	USE dynzdf_exp
885	USE trazdf_exp
886	!
887	INTEGER :: jk ! dummy loop indices
888	REAL(wp):: zcr ! local scalar
889	!!
890	NAMELIST/namzdf_gls/rn_emin, rn_epsmin, ln_length_lim, &
891	& rn_clim_galp, ln_crban, ln_sigpsi, &
892	& rn_crban, rn_charn, &
893	& nn_tkebc_surf, nn_tkebc_bot, &
894	& nn_psibc_surf, nn_psibc_bot, &
895	& nn_stab_func, nn_clos
896	!!----------------------------------------------------------
897
898	REWIND ( numnam ) !* Read Namelist namzdf_gls
899	READ ( numnam, namzdf_gls )
900
901	IF(lwp) THEN !* Control print
902	WRITE(numout,*)
903	WRITE(numout,*) 'zdf_gls_init : gls turbulent closure scheme'
904	WRITE(numout,*) '~~~~~~~~~~~~'
905	WRITE(numout,*) ' Namelist namzdf_gls : set gls mixing parameters'
906	WRITE(numout,*) ' minimum value of en rn_emin = ', rn_emin
907	WRITE(numout,*) ' minimum value of eps rn_epsmin = ', rn_epsmin
908	WRITE(numout,*) ' Limit dissipation rate under stable stratif. ln_length_lim = ', ln_length_lim
909	WRITE(numout,*) ' Galperin limit (Standard: 0.53, Holt: 0.26) rn_clim_galp = ', rn_clim_galp
910	WRITE(numout,*) ' TKE Surface boundary condition nn_tkebc_surf = ', nn_tkebc_surf
911	WRITE(numout,*) ' TKE Bottom boundary condition nn_tkebc_bot = ', nn_tkebc_bot
912	WRITE(numout,*) ' PSI Surface boundary condition nn_psibc_surf = ', nn_psibc_surf
913	WRITE(numout,*) ' PSI Bottom boundary condition nn_psibc_bot = ', nn_psibc_bot
914	WRITE(numout,*) ' Craig and Banner scheme ln_crban = ', ln_crban
915	WRITE(numout,*) ' Modify psi Schmidt number (wb case) ln_sigpsi = ', ln_sigpsi
916	WRITE(numout,*) ' Craig and Banner coefficient rn_crban = ', rn_crban
917	WRITE(numout,*) ' Charnock coefficient rn_charn = ', rn_charn
918	WRITE(numout,*) ' Stability functions nn_stab_func = ', nn_stab_func
919	WRITE(numout,*) ' Type of closure nn_clos = ', nn_clos
920	WRITE(numout,*) ' Hard coded parameters'
921	WRITE(numout,*) ' Surface roughness (m) hsro = ', hsro
922	WRITE(numout,*) ' Bottom roughness (m) hbro = ', hbro
923	ENDIF
924
925	! !* Check of some namelist values
926	IF( nn_tkebc_surf < 0 .OR. nn_tkebc_surf > 1 ) CALL ctl_stop( 'bad flag: nn_tkebc_surf is 0 or 1' )
927	IF( nn_psibc_surf < 0 .OR. nn_psibc_surf > 1 ) CALL ctl_stop( 'bad flag: nn_psibc_surf is 0 or 1' )
928	IF( nn_tkebc_bot < 0 .OR. nn_tkebc_bot > 1 ) CALL ctl_stop( 'bad flag: nn_tkebc_bot is 0 or 1' )
929	IF( nn_psibc_bot < 0 .OR. nn_psibc_bot > 1 ) CALL ctl_stop( 'bad flag: nn_psibc_bot is 0 or 1' )
930	IF( nn_stab_func < 0 .OR. nn_stab_func > 3 ) CALL ctl_stop( 'bad flag: nn_stab_func is 0, 1, 2 and 3' )
931	IF( nn_clos < 0 .OR. nn_clos > 3 ) CALL ctl_stop( 'bad flag: nn_clos is 0, 1, 2 or 3' )
932
933	! Initialisation of the parameters for the choosen closure
934	! --------------------------------------------------------
935	!
936	SELECT CASE ( nn_clos )
937	!
938	CASE( 0 ) ! k-kl (Mellor-Yamada)
939	!
940	IF(lwp) WRITE(numout,*) 'The choosen closure is k-kl closed to the classical Mellor-Yamada'
941	rpp = 0._wp
942	rmm = 1._wp
943	rnn = 1._wp
944	rsc_tke = 1.96_wp
945	rsc_psi = 1.96_wp
946	rpsi1 = 0.9_wp
947	rpsi3p = 1._wp
948	rpsi2 = 0.5_wp
949	!
950	SELECT CASE ( nn_stab_func )
951	CASE( 0, 1 ) ; rpsi3m = 2.53_wp ! G88 or KC stability functions
952	CASE( 2 ) ; rpsi3m = 2.38_wp ! Canuto A stability functions
953	CASE( 3 ) ; rpsi3m = 2.38 ! Canuto B stability functions (caution : constant not identified)
954	END SELECT
955	!
956	CASE( 1 ) ! k-eps
957	!
958	IF(lwp) WRITE(numout,*) 'The choosen closure is k-eps'
959	rpp = 3._wp
960	rmm = 1.5_wp
961	rnn = -1._wp
962	rsc_tke = 1._wp
963	rsc_psi = 1.3_wp ! Schmidt number for psi
964	rpsi1 = 1.44_wp
965	rpsi3p = 1._wp
966	rpsi2 = 1.92_wp
967	!
968	SELECT CASE ( nn_stab_func )
969	CASE( 0, 1 ) ; rpsi3m = -0.52_wp ! G88 or KC stability functions
970	CASE( 2 ) ; rpsi3m = -0.629_wp ! Canuto A stability functions
971	CASE( 3 ) ; rpsi3m = -0.566 ! Canuto B stability functions
972	END SELECT
973	!
974	CASE( 2 ) ! k-omega
975	!
976	IF(lwp) WRITE(numout,*) 'The choosen closure is k-omega'
977	rpp = -1._wp
978	rmm = 0.5_wp
979	rnn = -1._wp
980	rsc_tke = 2._wp
981	rsc_psi = 2._wp
982	rpsi1 = 0.555_wp
983	rpsi3p = 1._wp
984	rpsi2 = 0.833_wp
985	!
986	SELECT CASE ( nn_stab_func )
987	CASE( 0, 1 ) ; rpsi3m = -0.58_wp ! G88 or KC stability functions
988	CASE( 2 ) ; rpsi3m = -0.64_wp ! Canuto A stability functions
989	CASE( 3 ) ; rpsi3m = -0.64_wp ! Canuto B stability functions caution : constant not identified)
990	END SELECT
991	!
992	CASE( 3 ) ! generic
993	!
994	IF(lwp) WRITE(numout,*) 'The choosen closure is generic'
995	rpp = 2._wp
996	rmm = 1._wp
997	rnn = -0.67_wp
998	rsc_tke = 0.8_wp
999	rsc_psi = 1.07_wp
1000	rpsi1 = 1._wp
1001	rpsi3p = 1._wp
1002	rpsi2 = 1.22_wp
1003	!
1004	SELECT CASE ( nn_stab_func )
1005	CASE( 0, 1 ) ; rpsi3m = 0.1_wp ! G88 or KC stability functions
1006	CASE( 2 ) ; rpsi3m = 0.05_wp ! Canuto A stability functions
1007	CASE( 3 ) ; rpsi3m = 0.05_wp ! Canuto B stability functions caution : constant not identified)
1008	END SELECT
1009	!
1010	END SELECT
1011
1012	! Initialisation of the parameters of the stability functions
1013	! -----------------------------------------------------------
1014	!
1015	SELECT CASE ( nn_stab_func )
1016	!
1017	CASE ( 0 ) ! Galperin stability functions
1018	!
1019	IF(lwp) WRITE(numout,*) 'Stability functions from Galperin'
1020	rc2 = 0._wp
1021	rc3 = 0._wp
1022	rc_diff = 1._wp
1023	rc0 = 0.5544_wp
1024	rcm_sf = 0.9884_wp
1025	rghmin = -0.28_wp
1026	rgh0 = 0.0233_wp
1027	rghcri = 0.02_wp
1028	!
1029	CASE ( 1 ) ! Kantha-Clayson stability functions
1030	!
1031	IF(lwp) WRITE(numout,*) 'Stability functions from Kantha-Clayson'
1032	rc2 = 0.7_wp
1033	rc3 = 0.2_wp
1034	rc_diff = 1._wp
1035	rc0 = 0.5544_wp
1036	rcm_sf = 0.9884_wp
1037	rghmin = -0.28_wp
1038	rgh0 = 0.0233_wp
1039	rghcri = 0.02_wp
1040	!
1041	CASE ( 2 ) ! Canuto A stability functions
1042	!
1043	IF(lwp) WRITE(numout,*) 'Stability functions from Canuto A'
1044	rs0 = 1.5_wp * rl1 * rl5*rl5
1045	rs1 = -rl4(rl6+rl7) + 2._wprl4rl5(rl1-(1._wp/3._wp)rl2-rl3) + 1.5_wprl1rl5rl8
1046	rs2 = -(3._wp/8._wp) * rl1(rl6rl6-rl7*rl7)
1047	rs4 = 2._wp * rl5
1048	rs5 = 2._wp * rl4
1049	rs6 = (2._wp/3._wp) * rl5 * ( 3._wprl3rl3 - rl2rl2 ) - 0.5_wp rl5rl1 (3._wp*rl3-rl2) &
1050	& + 0.75_wp * rl1 * ( rl6 - rl7 )
1051	rd0 = 3._wp * rl5*rl5
1052	rd1 = rl5 * ( 7._wprl4 + 3._wprl8 )
1053	rd2 = rl5rl5 ( 3._wprl3rl3 - rl2rl2 ) - 0.75_wp(rl6rl6 - rl7rl7 )
1054	rd3 = rl4 * ( 4._wprl4 + 3._wprl8)
1055	rd4 = rl4 * ( rl2 * rl6 - 3._wprl3rl7 - rl5(rl2rl2 - rl3rl3 ) ) + rl5rl8 * ( 3._wprl3rl3 - rl2*rl2 )
1056	rd5 = 0.25_wp * ( rl2rl2 - 3._wp rl3rl3 ) ( rl6rl6 - rl7rl7 )
1057	rc0 = 0.5268_wp
1058	rf6 = 8._wp / (rc0**6._wp)
1059	rc_diff = SQRT(2._wp) / (rc0**3._wp)
1060	rcm_sf = 0.7310_wp
1061	rghmin = -0.28_wp
1062	rgh0 = 0.0329_wp
1063	rghcri = 0.03_wp
1064	!
1065	CASE ( 3 ) ! Canuto B stability functions
1066	!
1067	IF(lwp) WRITE(numout,*) 'Stability functions from Canuto B'
1068	rs0 = 1.5_wp * rm1 * rm5*rm5
1069	rs1 = -rm4 * (rm6+rm7) + 2._wp * rm4rm5(rm1-(1._wp/3._wp)rm2-rm3) + 1.5_wp rm1rm5rm8
1070	rs2 = -(3._wp/8._wp) * rm1 * (rm6rm6-rm7rm7 )
1071	rs4 = 2._wp * rm5
1072	rs5 = 2._wp * rm4
1073	rs6 = (2._wp/3._wp) * rm5 * (3._wprm3rm3-rm2rm2) - 0.5_wp rm5rm1(3._wprm3-rm2) + 0.75_wp rm1*(rm6-rm7)
1074	rd0 = 3._wp * rm5*rm5
1075	rd1 = rm5 * (7._wprm4 + 3._wprm8)
1076	rd2 = rm5rm5 (3._wprm3rm3 - rm2rm2) - 0.75_wp (rm6rm6 - rm7rm7)
1077	rd3 = rm4 * ( 4._wprm4 + 3._wprm8 )
1078	rd4 = rm4 * ( rm2rm6 -3._wprm3rm7 - rm5(rm2rm2 - rm3rm3) ) + rm5 * rm8 * ( 3._wprm3rm3 - rm2*rm2 )
1079	rd5 = 0.25_wp * ( rm2rm2 - 3._wprm3rm3 ) ( rm6rm6 - rm7rm7 )
1080	rc0 = 0.5268_wp !! rc0 = 0.5540_wp (Warner ...) to verify !
1081	rf6 = 8._wp / ( rc0**6._wp )
1082	rc_diff = SQRT(2._wp)/(rc0**3.)
1083	rcm_sf = 0.7470_wp
1084	rghmin = -0.28_wp
1085	rgh0 = 0.0444_wp
1086	rghcri = 0.0414_wp
1087	!
1088	END SELECT
1089
1090	! Set Schmidt number for psi diffusion in the wave breaking case
1091	! See equation 13 of Carniel et al, Ocean modelling, 30, 225-239, 2009
1092	! or equation (17) of Burchard, JPO, 31, 3133-3145, 2001
1093	IF( ln_sigpsi .AND. ln_crban ) THEN
1094	zcr = SQRT( 1.5_wprsc_tke ) rcm_sf / vkarmn
1095	rsc_psi0 = vkarmnvkarmn / ( rpsi2 rcm_sf*rcm_sf ) &
1096	& * ( rnnrnn - 4._wp/3._wp zcrrnnrmm - 1._wp/3._wp * zcr*rnn &
1097	& + 2._wp/9._wp * rmm * zcrzcr + 4._wp/9._wp zcrzcr rmm*rmm )
1098	ELSE
1099	rsc_psi0 = rsc_psi
1100	ENDIF
1101
1102	! Shear free turbulence parameters:
1103	!
1104	ra_sf = -4._wp * rnn * SQRT( rsc_tke ) / ( (1._wp+4._wprmm) SQRT( rsc_tke ) &
1105	& - SQRT(rsc_tke + 24._wprsc_psi0rpsi2 ) )
1106	rl_sf = rc0 * SQRT( rc0 / rcm_sf ) &
1107	& * SQRT( ( (1._wp + 4._wprmm + 8._wprmmrmm) rsc_tke &
1108	& + 12._wp * rsc_psi0 * rpsi2 &
1109	& - (1._wp + 4._wprmm) SQRT( rsc_tke(rsc_tke+ 24._wprsc_psi0*rpsi2) ) ) &
1110	& / ( 12._wprnnrnn ) )
1111
1112	!
1113	IF(lwp) THEN ! Control print
1114	WRITE(numout,*)
1115	WRITE(numout,*) 'Limit values'
1116	WRITE(numout,*) '~~~~~~~~~~~~'
1117	WRITE(numout,*) 'Parameter m = ',rmm
1118	WRITE(numout,*) 'Parameter n = ',rnn
1119	WRITE(numout,*) 'Parameter p = ',rpp
1120	WRITE(numout,*) 'rpsi1 = ',rpsi1
1121	WRITE(numout,*) 'rpsi2 = ',rpsi2
1122	WRITE(numout,*) 'rpsi3m = ',rpsi3m
1123	WRITE(numout,*) 'rpsi3p = ',rpsi3p
1124	WRITE(numout,*) 'rsc_tke = ',rsc_tke
1125	WRITE(numout,*) 'rsc_psi = ',rsc_psi
1126	WRITE(numout,*) 'rsc_psi0 = ',rsc_psi0
1127	WRITE(numout,*) 'rc0 = ',rc0
1128	WRITE(numout,*)
1129	WRITE(numout,*) 'Shear free turbulence parameters:'
1130	WRITE(numout,*) 'rcm_sf = ',rcm_sf
1131	WRITE(numout,*) 'ra_sf = ',ra_sf
1132	WRITE(numout,*) 'rl_sf = ',rl_sf
1133	WRITE(numout,*)
1134	ENDIF
1135
1136	! Constants initialization
1137	rc02 = rc0 * rc0 ; rc02r = 1. / rc02
1138	rc03 = rc02 * rc0
1139	rc04 = rc03 * rc0
1140	rc03_sqrt2_galp = rc03 / SQRT(2._wp) / rn_clim_galp
1141	rsbc_mb = 0.5_wp * (15.8_wprn_crban)*(2._wp/3._wp) ! Surf. bound. cond. from Mellor and Blumberg
1142	rsbc_std = 3.75_wp ! Surf. bound. cond. standard (prod=diss)
1143	rsbc_tke1 = (-rsc_tkern_crban/(rcm_sfra_sfrl_sf))*(2._wp/3._wp) ! k_eps = 53. Dirichlet + Wave breaking
1144	rsbc_tke2 = 0.5_wp / rau0
1145	rsbc_tke3 = rdt * rn_crban ! Neumann + Wave breaking
1146	rsbc_zs = rn_charn / grav ! Charnock formula
1147	rsbc_psi1 = rc0*rpp rsbc_tke1*rmm rl_sf**rnn ! Dirichlet + Wave breaking
1148	rsbc_psi2 = -0.5_wp * rdt * rc0*rpp rnn * vkarmn**rnn / rsc_psi ! Neumann + NO Wave breaking
1149	rsbc_psi3 = -0.5_wp * rdt * rc0*rpp rl_sf*rnn / rsc_psi (rnn + rmm*ra_sf) ! Neumann + Wave breaking
1150	rfact_tke = -0.5_wp / rsc_tke * rdt ! Cst used for the Diffusion term of tke
1151	rfact_psi = -0.5_wp / rsc_psi * rdt ! Cst used for the Diffusion term of tke
1152
1153	! !* Wall proximity function
1154	zwall (:,:,:) = 1._wp * tmask(:,:,:)
1155
1156	! !* set vertical eddy coef. to the background value
1157	DO jk = 1, jpk
1158	avt (:,:,jk) = avtb(jk) * tmask(:,:,jk)
1159	avm (:,:,jk) = avmb(jk) * tmask(:,:,jk)
1160	avmu(:,:,jk) = avmb(jk) * umask(:,:,jk)
1161	avmv(:,:,jk) = avmb(jk) * vmask(:,:,jk)
1162	END DO
1163	! !* read or initialize all required files
1164	CALL gls_rst( nit000, 'READ' )
1165	!
1166	END SUBROUTINE zdf_gls_init
1167
1168
1169	SUBROUTINE gls_rst( kt, cdrw )
1170	!!---------------------------------------------------------------------
1171	!! * ROUTINE ts_rst *
1172	!!
1173	!! ** Purpose : Read or write TKE file (en) in restart file
1174	!!
1175	!! ** Method : use of IOM library
1176	!! if the restart does not contain TKE, en is either
1177	!! set to rn_emin or recomputed (nn_igls/=0)
1178	!!----------------------------------------------------------------------
1179	INTEGER , INTENT(in) :: kt ! ocean time-step
1180	CHARACTER(len=*), INTENT(in) :: cdrw ! "READ"/"WRITE" flag
1181	!
1182	INTEGER :: jit, jk ! dummy loop indices
1183	INTEGER :: id1, id2, id3, id4, id5, id6, id7, id8
1184	INTEGER :: ji, jj, ikbu, ikbv
1185	REAL(wp):: cbx, cby
1186	!!----------------------------------------------------------------------
1187	!
1188	IF( TRIM(cdrw) == 'READ' ) THEN ! Read/initialise
1189	! ! ---------------
1190	IF( ln_rstart ) THEN !* Read the restart file
1191	id1 = iom_varid( numror, 'en' , ldstop = .FALSE. )
1192	id2 = iom_varid( numror, 'avt' , ldstop = .FALSE. )
1193	id3 = iom_varid( numror, 'avm' , ldstop = .FALSE. )
1194	id4 = iom_varid( numror, 'avmu' , ldstop = .FALSE. )
1195	id5 = iom_varid( numror, 'avmv' , ldstop = .FALSE. )
1196	id6 = iom_varid( numror, 'mxln' , ldstop = .FALSE. )
1197	!
1198	IF( MIN( id1, id2, id3, id4, id5, id6, id7, id8 ) > 0 ) THEN ! all required arrays exist
1199	CALL iom_get( numror, jpdom_autoglo, 'en' , en )
1200	CALL iom_get( numror, jpdom_autoglo, 'avt' , avt )
1201	CALL iom_get( numror, jpdom_autoglo, 'avm' , avm )
1202	CALL iom_get( numror, jpdom_autoglo, 'avmu' , avmu )
1203	CALL iom_get( numror, jpdom_autoglo, 'avmv' , avmv )
1204	CALL iom_get( numror, jpdom_autoglo, 'mxln' , mxln )
1205	ELSE
1206	IF(lwp) WRITE(numout,*) ' ===>>>> : previous run without gls scheme, en and mxln computed by iterative loop'
1207	en (:,:,:) = rn_emin
1208	mxln(:,:,:) = 0.001
1209	DO jit = nit000 + 1, nit000 + 10 ; CALL zdf_gls( jit ) ; END DO
1210	ENDIF
1211	ELSE !* Start from rest
1212	IF(lwp) WRITE(numout,*) ' ===>>>> : Initialisation of en and mxln by background values'
1213	en (:,:,:) = rn_emin
1214	mxln(:,:,:) = 0.001
1215	ENDIF
1216	!
1217	ELSEIF( TRIM(cdrw) == 'WRITE' ) THEN ! Create restart file
1218	! ! -------------------
1219	IF(lwp) WRITE(numout,*) '---- gls-rst ----'
1220	CALL iom_rstput( kt, nitrst, numrow, 'en' , en )
1221	CALL iom_rstput( kt, nitrst, numrow, 'avt' , avt )
1222	CALL iom_rstput( kt, nitrst, numrow, 'avm' , avm )
1223	CALL iom_rstput( kt, nitrst, numrow, 'avmu' , avmu )
1224	CALL iom_rstput( kt, nitrst, numrow, 'avmv' , avmv )
1225	CALL iom_rstput( kt, nitrst, numrow, 'mxln' , mxln )
1226	!
1227	ENDIF
1228	!
1229	END SUBROUTINE gls_rst
1230
1231	#else
1232	!!----------------------------------------------------------------------
1233	!! Dummy module : NO TKE scheme
1234	!!----------------------------------------------------------------------
1235	LOGICAL, PUBLIC, PARAMETER :: lk_zdfgls = .FALSE. !: TKE flag
1236	CONTAINS
1237	SUBROUTINE zdf_gls_init ! Empty routine
1238	WRITE(,) 'zdf_gls_init: You should not have seen this print! error?'
1239	END SUBROUTINE zdf_gls_init
1240	SUBROUTINE zdf_gls( kt ) ! Empty routine
1241	WRITE(,) 'zdf_gls: You should not have seen this print! error?', kt
1242	END SUBROUTINE zdf_gls
1243	SUBROUTINE gls_rst( kt, cdrw ) ! Empty routine
1244	INTEGER , INTENT(in) :: kt ! ocean time-step
1245	CHARACTER(len=*), INTENT(in) :: cdrw ! "READ"/"WRITE" flag
1246	WRITE(,) 'gls_rst: You should not have seen this print! error?', kt, cdrw
1247	END SUBROUTINE gls_rst
1248	#endif
1249
1250	!!======================================================================
1251	END MODULE zdfgls
1252

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