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zdfkpp.F90 in trunk/NEMO/OPA_SRC/ZDF – NEMO

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source: trunk/NEMO/OPA_SRC/ZDF/zdfkpp.F90 @ 896

Last change on this file since 896 was 896, checked in by rblod, 16 years ago
Update KPP according to step reorganization (nemo_v2) ..., see ticket #101
Property svn:eol-style set to `native` Property svn:keywords set to `Author Date Id Revision`
File size: 74.4 KB

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1	MODULE zdfkpp
2	!!======================================================================
3	!! * MODULE zdfkpp *
4	!! Ocean physics: vertical mixing coefficient compute from the KPP
5	!! turbulent closure parameterization
6	!!=====================================================================
7	!! History : 8.1 ! 00-03 (W.G. Large, J. Chanut) Original code
8	!! 8.1 ! 02-06 (J.M. Molines) for real case CLIPPER
9	!! 8.2 ! 03-10 (Chanut J.) re-writting
10	!! 9.0 ! 05-01 (C. Ethe) Free form, F90
11	!!----------------------------------------------------------------------
12	#if defined key_zdfkpp \|\| defined key_esopa
13	!!----------------------------------------------------------------------
14	!! 'key_zdfkpp' KPP scheme
15	!!----------------------------------------------------------------------
16	!!----------------------------------------------------------------------
17	!! zdf_kpp : update momentum and tracer Kz from a kpp scheme
18	!! zdf_kpp_init : initialization, namelist read, and parameters control
19	!!----------------------------------------------------------------------
20	USE oce ! ocean dynamics and active tracers
21	USE dom_oce ! ocean space and time domain
22	USE zdf_oce ! ocean vertical physics
23	USE sbc_oce ! surface boundary condition: ocean
24	USE phycst ! physical constants
25	USE eosbn2 ! equation of state
26	USE zdfddm ! double diffusion mixing
27	USE in_out_manager ! I/O manager
28	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
29	USE prtctl ! Print control
30	USE trdmod ! momentum/tracers trends
31
32	IMPLICIT NONE
33	PRIVATE
34
35	PUBLIC zdf_kpp ! routine called by step.F90
36	PUBLIC tra_kpp ! routine called by step.F90
37
38	LOGICAL, PUBLIC, PARAMETER :: lk_zdfkpp = .TRUE. !: KPP vertical mixing flag
39	REAL(wp), PUBLIC, DIMENSION(jpi,jpj,jpk) :: ghats !: non-local scalar mixing term (gamma/<ws>o)
40	REAL(wp), PUBLIC, DIMENSION(jpi,jpj) :: &
41	wt0 , & !: surface temperature flux for non local flux
42	ws0 , & !: surface salinity flux for non local flux
43	hkpp !: boundary layer depht
44
45	INTEGER :: & !!! kpp namelist (namkpp)
46	nave = 1 , & ! = 0/1 flag for horizontal average on avt, avmu, avmv
47	navb = 0 ! = 0/1 flag for constant or profile background avt
48
49	REAL(wp) :: & !!! ** Interior Mixing
50	difmiw = 1.2e-04_wp , & ! constant internal wave viscosity (m2/s)
51	difsiw = 1.2e-05_wp , & ! constant internal wave diffusivity (m2/s)
52	Riinfty = 0.8_wp , & ! local Richardson Number limit for shear instability
53	difri = 5.e-03_wp , & ! maximum shear mixing at Rig = 0 (m2/s)
54	bvsqcon = -1.e-09_wp , & ! Brunt-Vaisala squared (1/s**2) for maximum convection
55	difcon = 1._wp ! maximum mixing in interior convection (m2/s)
56	#if defined key_zdfddm
57	REAL(wp) :: & !!! ** Double diffusion Mixing
58	difssf = 1.e-03_wp , & ! maximum salt fingering mixing
59	Rrho0 = 1.9_wp , & ! limit for salt fingering mixing
60	difsdc = 1.5e-06_wp ! maximum diffusive convection mixing
61	#endif
62	LOGICAL :: &
63	ln_kpprimix = .TRUE. ! Shear instability mixing
64
65	REAL(wp) :: & !!! General constants
66	epsln = 1.0e-20_wp , & ! a small positive number
67	pthird = 1._wp/3._wp , & ! 1/3
68	pfourth = 1._wp/4._wp ! 1/4
69
70	REAL(wp) :: & !!! Boundary Layer Turbulence Parameters
71	vonk = 0.4_wp , & ! von Karman's constant
72	epsilon = 0.1_wp , & ! nondimensional extent of the surface layer
73	rconc1 = 5.0_wp , & ! standard flux profile function parmaeters
74	rconc2 = 16.0_wp , & ! " "
75	rconcm = 8.38_wp , & ! momentum flux profile fit
76	rconam = 1.26_wp , & ! " "
77	rzetam = -.20_wp , & ! " "
78	rconcs = 98.96_wp , & ! scalar flux profile fit
79	rconas = -28.86_wp , & ! " "
80	rzetas = -1.0_wp ! " "
81	REAL(wp) :: & !!! Boundary Layer Depth Diagnostic
82	Ricr = 0.3_wp , & ! critical bulk Richardson Number
83	rcekman = 0.7_wp , & ! coefficient for ekman depth
84	rcmonob = 1.0_wp , & ! coefficient for Monin-Obukhov depth
85	rconcv = 1.7_wp , & ! ratio of interior buoyancy frequency to buoyancy frequency at entrainment depth
86	hbf = 1.0_wp , & ! fraction of bound. layer depth to which absorbed solar
87	! ! rad. and contributes to surf. buo. forcing
88	Vtc ! function of rconcv,rconcs,epsilon,vonk,Ricr
89	REAL(wp) :: & !!! Nonlocal Boundary Layer Mixing
90	rcstar = 5.0_wp , & ! coefficient for convective nonlocal transport
91	rcs = 1.0e-3_wp , & ! conversion: mm/s ==> m/s
92	rcg ! non-dimensional coefficient for nonlocal transport
93
94	#if ! defined key_kppcustom
95	REAL(wp), DIMENSION(jpk,jpk) :: &
96	del ! array for reference mean values of vertical integration
97	#endif
98
99	#if defined key_kpplktb
100	INTEGER, PARAMETER :: & !!! Parameters for lookup table for turbulent velocity scales
101	nilktb = 892 , & ! number of values for zehat in KPP lookup table
102	njlktb = 482 , & ! number of values for ustar in KPP lookup table
103	nilktbm1 = nilktb - 1 , & !
104	njlktbm1 = njlktb - 1 !
105
106	REAL(wp), DIMENSION(nilktb,njlktb) :: &
107	wmlktb , & ! lookup table for the turbulent vertical velocity scale for momentum
108	wslktb ! lookup table for the turbulent vertical velocity scale for tracers
109
110	REAL(wp) :: &
111	dehatmin = -4.e-7_wp , & ! minimum limit for zhat in lookup table (m3/s3)
112	dehatmax = 0._wp , & ! maximum limit for zhat in lookup table (m3/s3)
113	ustmin = 0._wp , & ! minimum limit for ustar in lookup table (m/s)
114	ustmax = 0.04_wp , & ! maximum limit for ustar in lookup table (m/s)
115	dezehat , & ! delta zhat in lookup table
116	deustar ! delta ustar in lookup table
117	#endif
118	REAL(wp), DIMENSION(jpk) :: & !!! attenuation coef
119	ratt
120	!! already defines in module traqsr, but only if the solar radiation penetration is considered
121	REAL(wp) :: & !!! * penetrative solar radiation coefficient *
122	rabs = 0.58_wp , & ! fraction associated with xsi1
123	xsi1 = 0.35_wp , & ! first depth of extinction
124	xsi2 = 23.0_wp ! second depth of extinction
125	! ! (default values: water type Ib)
126
127	REAL(wp), DIMENSION(jpi,jpj,jpk) :: &
128	etmean , & ! coefficient used for horizontal smoothing
129	eumean , & ! at t-, u- and v-points
130	evmean
131
132	#if defined key_cfg_1d
133	REAL(wp), PUBLIC, DIMENSION(jpi,jpj,jpk) :: &
134	rig , & ! gradient Richardson number
135	rib , & ! bulk Richardson number
136	buof , & ! buoyancy forcing
137	mols ! moning-Obukhov length scale
138	REAL(wp), PUBLIC, DIMENSION(jpi,jpj) :: &
139	ekdp ! Ekman depth
140	#endif
141
142	INTEGER :: & !
143	jip = 62 , jjp = 111
144
145	!! * Substitutions
146	# include "domzgr_substitute.h90"
147	# include "vectopt_loop_substitute.h90"
148	# include "zdfddm_substitute.h90"
149	!!----------------------------------------------------------------------
150	!! OPA 9.0 , LOCEAN-IPSL (2005)
151	!! $Id$
152	!! Software governed by the CeCILL licence (modipsl/doc/NEMO_CeCILL.txt)
153	!!----------------------------------------------------------------------
154
155	CONTAINS
156
157	SUBROUTINE zdf_kpp ( kt )
158	!!----------------------------------------------------------------------
159	!! * ROUTINE zdf_kpp *
160	!!
161	!! ** Purpose : Compute the vertical eddy viscosity and diffusivity
162	!! coefficients and non local mixing using K-profile parameterization
163	!!
164	!! ** Method : The boundary layer depth hkpp is diagnosed at tracer points
165	!! from profiles of buoyancy, and shear, and the surface forcing.
166	!! Above hbl (sigma=-z/hbl <1) the mixing coefficients are computed from
167	!!
168	!! Kx = hkpp Wx(sigma) G(sigma)
169	!!
170	!! and the non local term ghat = Cs / Ws(sigma) / hkpp
171	!! Below hkpp the coefficients are the sum of mixing due to internal waves
172	!! shear instability and double diffusion.
173	!!
174	!! -1- Compute the now interior vertical mixing coefficients at all depths.
175	!! -2- Diagnose the boundary layer depth.
176	!! -3- Compute the now boundary layer vertical mixing coefficients.
177	!! -4- Compute the now vertical eddy vicosity and diffusivity.
178	!! -5- Smoothing
179	!!
180	!! N.B. The computation is done from jk=2 to jpkm1
181	!! Surface value of avt avmu avmv are set once a time to zero
182	!! in routine zdf_kpp_init.
183	!!
184	!! ** Action : update the non-local terms ghats
185	!! update avt, avmu, avmv (before vertical eddy coef.)
186	!!
187	!! References : Large W.G., Mc Williams J.C. and Doney S.C.
188	!! Reviews of Geophysics, 32, 4, November 1994
189	!! Comments in the code refer to this paper, particularly
190	!! the equation number. (LMD94, here after)
191	!!----------------------------------------------------------------------
192	#if defined key_zdfddm
193	USE oce , zviscos => ua, & ! temp. array for viscosities use ua as workspace
194	& zdiffut => ta, & ! temp. array for diffusivities use sa as workspace
195	& zdiffus => sa ! temp. array for diffusivities use sa as workspace
196	#else
197	USE oce , zviscos => ua, & ! temp. array for viscosities use ua as workspace
198	& zdiffut => ta ! temp. array for diffusivities use sa as workspace
199	#endif
200	!!
201	INTEGER, INTENT( in ) :: kt ! ocean time step
202	!!
203	INTEGER :: ji, jj, jk ! dummy loop indices
204	INTEGER :: ikbot, jkmax, jkm1, jkp2 !
205
206	REAL(wp), DIMENSION(jpi,jpj) :: & !!! Surface buoyancy forcing, friction velocity
207	zBo, zBosol, zustar !
208	!
209	REAL(wp) :: & !
210	ztx, zty, ztau, zflageos, & !
211	zstabl, zbuofdep,zucube, & !
212	zrhos, zalbet, zbeta, & !
213	zthermal, zhalin, zatt1 !
214
215	REAL(wp) :: & !!! Bulk richardson number
216	zref, zt, zs, zh, & !
217	zu, zv, zrh, & !
218	zrib, zrinum, & !
219	zdVsq, zVtsq !
220
221	REAL(wp) :: & !!! Velocity scales
222	zehat, zeta, zhrib, zsig, & !
223	zscale, zwst, zws, zwm
224
225	#if defined key_kpplktb
226	INTEGER :: & !!! Lookup table or Analytical functions
227	il, jl !
228	REAL(wp) :: & !
229	ud, zfrac, ufrac, & !
230	zwam, zwbm, zwas, zwbs !
231	#else
232	REAL(wp) :: & !
233	zwsun, zwmun, &
234	zcons, zconm, zwcons, zwconm !
235	#endif
236
237	REAL(wp) :: & !!! In situ density
238	zsr, zbw, ze, & !
239	zb, zd, zc, zaw, za, & !
240	zb1, za1, zkw, zk0, & !
241	zcomp , zrhd, zrhdr,zbvzed !
242
243	#if ! defined key_kppcustom
244	!! * local declarations
245	INTEGER :: &
246	jm ! dummy loop indices
247	REAL(wp) :: & !!! Compression terms
248	zr1, zr2, zr3, zr4, & !
249	zrhop !
250	#endif
251
252	REAL(wp) :: & !
253	zflag, ztemp, zrn2, & !
254	zdep21, zdep32, zdep43
255
256	REAL(wp) :: & !!! Interior richardson mixing
257	zdku2, zdkv2, ze3sqr, & !
258	zsh2, zri, zfri !
259
260	REAL(wp), DIMENSION(jpi,0:2) :: & !!! Moning-Obukov limitation
261	zmoek
262	REAL(wp), DIMENSION(jpi) :: &
263	zmoa, zekman
264	REAL(wp) :: &
265	zmob, zek
266
267	REAL(wp), DIMENSION(jpi,4) :: & !!! The pipe
268	zdepw, zdift, zvisc
269	REAL(wp), DIMENSION(jpi,3) :: &
270	zdept
271	REAL(wp), DIMENSION(jpi,2) :: &
272	zriblk
273	REAL(wp), DIMENSION(jpi,jpk) :: & !
274	zmask
275	REAL(wp), DIMENSION(jpi) :: & !
276	zhmax, zria, zhbl
277	REAL(wp) :: & !
278	zflagri, zflagek, & !
279	zflagmo, zflagh, zflagkb !
280	REAL(wp), DIMENSION(jpi) :: & !!! Shape function (G)
281	za2m, za3m, zkmpm, &
282	za2t, za3t, zkmpt
283	REAL(wp) :: & !
284	zdelta, zdelta2, & !
285	zdzup, zdzdn, zdzh, & !
286	zvath, zgat1, zdat1, & !
287	zkm1m, zkm1t
288	REAL(wp), DIMENSION(jpi,jpk) :: & !!! Boundary layer diffusivities/viscosities
289	zblcm, zblct
290	#if defined key_zdfddm
291	REAL(wp) :: & !!! double diffusion mixing
292	zrrau, zds, &
293	zavdds, zavddt,zinr
294	REAL(wp), DIMENSION(jpi,4) :: &
295	zdifs
296	REAL(wp), DIMENSION(jpi) :: &
297	za2s, za3s, zkmps
298	REAL(wp) :: &
299	zkm1s
300	REAL(wp), DIMENSION(jpi,jpk) :: &
301	zblcs
302	#endif
303	!!--------------------------------------------------------------------
304
305
306	! Initialization (first time-step only)
307	! --------------
308	IF( kt == nit000 ) CALL zdf_kpp_init
309
310	zviscos(:,:,:) = 0.
311	zblcm (:,: ) = 0.
312	zdiffut(:,:,:) = 0.
313	zblct (:,: ) = 0.
314	#if defined key_zdfddm
315	zdiffus(:,:,:) = 0.
316	zblcs (:,: ) = 0.
317	#endif
318	ghats(:,:,:) = 0.
319
320	zBo (:,:) = 0.
321	zBosol(:,:) = 0.
322	zustar(:,:) = 0.
323
324
325	!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
326	! I. Interior diffusivity and viscosity at w points ( T interfaces)
327	!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
328	DO jk = 2, jpkm1
329	DO jj = 2, jpjm1
330	DO ji = fs_2, fs_jpim1
331	! Mixing due to internal waves breaking
332	! -------------------------------------
333	avmu(ji,jj,jk) = difmiw
334	avt (ji,jj,jk) = difsiw
335	! Mixing due to vertical shear instability
336	! -------------------------------------
337	IF( ln_kpprimix ) THEN
338	! Compute the gradient Richardson number at interfaces (zri):
339	! LMD94, eq. 27 (is vertical smoothing needed : Rig=N^2 / (dz(u))^2 + (dz(v))^2
340	zdku2 = ( un(ji - 1,jj,jk - 1) - un(ji - 1,jj,jk) ) &
341	& * ( un(ji - 1,jj,jk - 1) - un(ji - 1,jj,jk) ) &
342	& + ( un(ji ,jj,jk - 1) - un(ji ,jj,jk) ) &
343	& * ( un(ji ,jj,jk - 1) - un(ji ,jj,jk) )
344
345	zdkv2 = ( vn(ji,jj - 1,jk - 1) - vn(ji,jj - 1,jk) ) &
346	& * ( vn(ji,jj - 1,jk - 1) - vn(ji,jj - 1,jk) ) &
347	& + ( vn(ji, jj,jk - 1) - vn(ji, jj,jk) ) &
348	& * ( vn(ji, jj,jk - 1) - vn(ji, jj,jk) )
349
350	ze3sqr = 1. / ( fse3w(ji,jj,jk) * fse3w(ji,jj,jk) )
351	! Square of vertical shear at interfaces
352	zsh2 = 0.5 * 0.5 * ( zdku2 + zdkv2 ) * ze3sqr
353	zri = MAX( rn2(ji,jj,jk), 0. ) / ( zsh2 + epsln )
354	#if defined key_cfg_1d
355	! save the gradient richardson number
356	rig(ji,jj,jk) = zri * tmask(ji,jj,jk)
357	#endif
358	! Evaluate f of Ri (zri) for shear instability store in zfri
359	! LMD94, eq. 28a,b,c, figure 3 ; Rem: p1 is 3, hard coded
360	zfri = MAX( zri , 0. )
361	zfri = MIN( zfri / Riinfty , 1.0 )
362	zfri = ( 1.0 - zfri * zfri )
363	zfri = zfri * zfri * zfri
364	! add shear contribution to mixing coef.
365	avmu(ji,jj,jk) = avmu(ji,jj,jk) + difri * zfri
366	avt (ji,jj,jk) = avt (ji,jj,jk) + difri * zfri
367	ENDIF
368	#if defined key_zdfddm
369	avs (ji,jj,jk) = avt (ji,jj,jk)
370	! Double diffusion mixing ; NOT IN ROUTINE ZDFDDM.F90
371	! ------------------------------------------------------------------
372	! only retains positive value of rrau
373	zrrau = MAX( rrau(ji,jj,jk), epsln )
374	zds = sn(ji,jj,jk-1) - sn(ji,jj,jk)
375	IF( zrrau > 1. .AND. zds > 0.) THEN
376	!
377	! Salt fingering case.
378	!---------------------
379	! Compute interior diffusivity for double diffusive mixing of
380	! salinity. Upper bound "zrrau" by "Rrho0"; (Rrho0=1.9, difcoefnuf=0.001).
381	! After that set interior diffusivity for double diffusive mixing
382	! of temperature
383	zavdds = MIN( zrrau, Rrho0 )
384	zavdds = ( zavdds - 1.0 ) / ( Rrho0 - 1.0 )
385	zavdds = 1.0 - zavdds * zavdds
386	zavdds = zavdds * zavdds * zavdds
387	zavdds = difssf * zavdds
388	zavddt = 0.7 * zavdds
389	ELSEIF( zrrau < 1. .AND. zrrau > 0. .AND. zds < 0.) THEN
390	!
391	! Diffusive convection case.
392	!---------------------------
393	! Compute interior diffusivity for double diffusive mixing of
394	! temperature (Marmorino and Caldwell, 1976);
395	! Compute interior diffusivity for double diffusive mixing of salinity
396	zinr = 1. / zrrau
397	zavddt = 0.909 * EXP( 4.6 * EXP( -0.54* ( zinr - 1. ) ) )
398	zavddt = difsdc * zavddt
399	IF( zrrau < 0.5) THEN
400	zavdds = zavddt * 0.15 * zrrau
401	ELSE
402	zavdds = zavddt * (1.85 * zrrau - 0.85 )
403	ENDIF
404	ELSE
405	zavddt = 0.
406	zavdds = 0.
407	ENDIF
408	! Add double diffusion contribution to temperature and salinity mixing coefficients.
409	avt (ji,jj,jk) = avt (ji,jj,jk) + zavddt
410	avs (ji,jj,jk) = avs (ji,jj,jk) + zavdds
411	#endif
412	END DO
413	END DO
414	END DO
415
416
417	! Radiative (zBosol) and non radiative (zBo) surface buoyancy
418	!JMM at the time zdfkpp is called, q still holds the sum q + qsr
419	!---------------------------------------------------------------------
420	DO jj = 2, jpjm1
421	DO ji = fs_2, fs_jpim1
422	IF( neos < 1) THEN
423	zt = tn(ji,jj,1)
424	zs = sn(ji,jj,1) - 35.0
425	zh = fsdept(ji,jj,1)
426	! potential volumic mass
427	zrhos = rhop(ji,jj,1)
428	zalbet = ( ( ( - 0.255019e-07 * zt + 0.298357e-05 ) * zt & ! ratio alpha/beta
429	& - 0.203814e-03 ) * zt &
430	& + 0.170907e-01 ) * zt &
431	& + 0.665157e-01 &
432	& + ( - 0.678662e-05 * zs &
433	& - 0.846960e-04 * zt + 0.378110e-02 ) * zs &
434	& + ( ( - 0.302285e-13 * zh &
435	& - 0.251520e-11 * zs &
436	& + 0.512857e-12 * zt * zt ) * zh &
437	& - 0.164759e-06 * zs &
438	& +( 0.791325e-08 * zt - 0.933746e-06 ) * zt &
439	& + 0.380374e-04 ) * zh
440
441	zbeta = ( ( -0.415613e-09 * zt + 0.555579e-07 ) * zt & ! beta
442	& - 0.301985e-05 ) * zt &
443	& + 0.785567e-03 &
444	& + ( 0.515032e-08 * zs &
445	& + 0.788212e-08 * zt - 0.356603e-06 ) * zs &
446	& +( ( 0.121551e-17 * zh &
447	& - 0.602281e-15 * zs &
448	& - 0.175379e-14 * zt + 0.176621e-12 ) * zh &
449	& + 0.408195e-10 * zs &
450	& + ( - 0.213127e-11 * zt + 0.192867e-09 ) * zt &
451	& - 0.121555e-07 ) * zh
452
453	zthermal = zbeta * zalbet / ( rcp * zrhos + epsln )
454	zhalin = zbeta * sn(ji,jj,1) * rcs
455	ELSE
456	zrhos = rhop(ji,jj,1) + rau0 * ( 1. - tmask(ji,jj,1) )
457	zthermal = ralpha / ( rcp * zrhos + epsln )
458	zhalin = rbeta * sn(ji,jj,1) * rcs
459	ENDIF
460	! Radiative surface buoyancy force
461	zBosol(ji,jj) = grav * zthermal * qsr(ji,jj)
462	! Non radiative surface buoyancy force
463	zBo (ji,jj) = grav * zthermal * qns(ji,jj) - grav * zhalin * emp(ji,jj)
464	! Surface Temperature flux for non-local term
465	wt0(ji,jj) = - ( qsr(ji,jj) + qns(ji,jj) )* ro0cpr * tmask(ji,jj,1)
466	! Surface salinity flux for non-local term
467	ws0(ji,jj) = - ( emp(ji,jj) * sn(ji,jj,1) * rcs ) * tmask(ji,jj,1)
468	ENDDO
469	ENDDO
470
471	zflageos = 0.5 + SIGN( 0.5, neos - 1. )
472	! Compute surface buoyancy forcing, Monin Obukhov and Ekman depths
473	!------------------------------------------------------------------
474	DO jj = 2, jpjm1
475	DO ji = fs_2, fs_jpim1
476	! Reference surface density = density at first T point level
477	zrhos = rhop(ji,jj,1) + zflageos * rau0 * ( 1. - tmask(ji,jj,1) )
478	! Friction velocity (zustar), at T-point : LMD94 eq. 2
479	ztx = 0.5 * ( utau(ji,jj) + utau(ji - 1, jj ) )
480	zty = 0.5 * ( vtau(ji,jj) + vtau(ji , jj - 1) )
481	ztau = SQRT( ztx * ztx + zty * zty )
482	zustar(ji,jj) = SQRT( ztau / ( zrhos + epsln ) )
483	ENDDO
484	ENDDO
485
486	!CDIR NOVERRCHK
487	! ! ===============
488	DO jj = 2, jpjm1 ! Vertical slab
489	! ! ===============
490
491	!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
492	! II Compute Boundary layer mixing coef. and diagnose the new boundary layer depth
493	!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
494
495	! Initialization
496	jkmax = 0
497	zdept (:,:) = 0.
498	zdepw (:,:) = 0.
499	zriblk(:,:) = 0.
500	zmoek (:,:) = 0.
501	zvisc (:,:) = 0.
502	zdift (:,:) = 0.
503	#if defined key_zdfddm
504	zdifs (:,:) = 0.
505	#endif
506	zmask (:,:) = 0.
507	DO ji = fs_2, fs_jpim1
508	zria(ji ) = 0.
509	! Maximum boundary layer depth
510	ikbot = mbathy(ji,jj) - 1 ! ikbot is the last T point in the water
511	zhmax(ji) = fsdept(ji,jj,ikbot) - 0.001
512	! Compute Monin obukhov length scale at the surface and Ekman depth:
513	zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * ratt(1)
514	zekman(ji) = rcekman * zustar(ji,jj) / ( ABS( ff(ji,jj) ) + epsln )
515	zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj)
516	zmoa(ji) = zucube / ( vonk * ( zbuofdep + epsln ) )
517	#if defined key_cfg_1d
518	! store the surface buoyancy forcing
519	zstabl = 0.5 + SIGN( 0.5, zbuofdep )
520	buof(ji,jj,1) = zbuofdep * tmask(ji,jj,1)
521	! store the moning-oboukov length scale at surface
522	zmob = zstabl * zmoa(ji) + ( 1.0 - zstabl ) * fsdept(ji,jj,1)
523	mols(ji,jj,1) = MIN( zmob , zhmax(ji) ) * tmask(ji,jj,1)
524	! store Ekman depth
525	zek = zstabl * zekman(ji) + ( 1.0 - zstabl ) * fsdept(ji,jj,1)
526	ekdp(ji,jj ) = MIN( zek , zhmax(ji) ) * tmask(ji,jj,1)
527	#endif
528	END DO
529	! Compute the pipe
530	! ---------------------
531	DO jk = 2, jpkm1
532	DO ji = fs_2, fs_jpim1
533	! Compute bfsfc = Bo + radiative contribution down to hbf*depht
534	zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * ratt(jk)
535	! Flag (zstabl = 1) if positive forcing
536	zstabl = 0.5 + SIGN( 0.5, zbuofdep)
537
538	! Compute bulk richardson number zrib at depht
539	!-------------------------------------------------------
540	! [Br - B(d)] * d zrinum
541	! Rib(z) = ----------------------- = -------------
542	! \|Vr - V(d)\|^2 + Vt(d)^2 zdVsq + zVtsq
543	!
544	! First compute zt,zs,zu,zv = means in the surface layer < epsilon*depht
545	! Else surface values are taken at the first T level.
546	! For stability, resolved vertical shear is computed with "before velocities".
547	zref = epsilon * fsdept(ji,jj,jk)
548	#if defined key_kppcustom
549	! zref = gdept(1)
550	zref = fsdept(ji,jj,1)
551	zt = tn(ji,jj,1)
552	zs = sn(ji,jj,1)
553	zrh = rhop(ji,jj,1)
554	zu = ( ub(ji,jj,1) + ub(ji - 1,jj ,1) ) / MAX( 1. , umask(ji,jj,1) + umask(ji - 1,jj ,1) )
555	zv = ( vb(ji,jj,1) + vb(ji ,jj - 1,1) ) / MAX( 1. , vmask(ji,jj,1) + vmask(ji ,jj - 1,1) )
556	#else
557	zt = 0.
558	zs = 0.
559	zu = 0.
560	zv = 0.
561	zrh = 0.
562	! vertically integration over the upper epsilon*gdept(jk) ; del () array is computed once in zdf_kpp_init
563	DO jm = 1, jpkm1
564	zt = zt + del(jk,jm) * tn(ji,jj,jm)
565	zs = zs + del(jk,jm) * sn(ji,jj,jm)
566	zu = zu + 0.5 * del(jk,jm) &
567	& * ( ub(ji,jj,jm) + ub(ji - 1,jj,jm) ) &
568	& / MAX( 1. , umask(ji,jj,jm) + umask(ji - 1,jj,jm) )
569	zv = zv + 0.5 * del(jk,jm) &
570	& * ( vb(ji,jj,jm) + vb(ji,jj - 1,jm) ) &
571	& / MAX( 1. , vmask(ji,jj,jm) + vmask(ji,jj - 1,jm) )
572	zrh = zrh + del(jk,jm) * rhop(ji,jj,jm)
573	END DO
574	#endif
575	zsr = SQRT( ABS( sn(ji,jj,jk) ) )
576	! depth
577	zh = fsdept(ji,jj,jk)
578	! compute compression terms on density
579	ze = ( -3.508914e-8zt-1.248266e-8 ) zt-2.595994e-6
580	zbw = ( 1.296821e-6zt-5.782165e-9 ) zt+1.045941e-4
581	zb = zbw + ze * zs
582
583	zd = -2.042967e-2
584	zc = (-7.267926e-5zt+2.598241e-3 ) zt+0.1571896
585	zaw = ( ( 5.939910e-6zt+2.512549e-3 ) zt-0.1028859 ) *zt - 4.721788
586	za = ( zdzsr + zc ) zs + zaw
587
588	zb1 = (-0.1909078zt+7.390729 ) zt-55.87545
589	za1 = ( ( 2.326469e-3zt+1.553190)zt-65.00517 ) *zt+1044.077
590	zkw = ( ( (-1.361629e-4zt-1.852732e-2 ) zt-30.41638 ) zt + 2098.925 ) zt+190925.6
591	zk0 = ( zb1zsr + za1 )zs + zkw
592	zcomp = 1.0 - zh / ( zk0 - zh * ( za - zh * zb ) )
593
594	#if defined key_kppcustom
595	! potential density of water(zrh = zt,zs at level jk):
596	zrhdr = zrh / zcomp
597	#else
598	! potential density of water(ztref,zsref at level jk):
599	! compute volumic mass pure water at atm pressure
600	IF ( neos < 1 ) THEN
601	zr1= ( ( ( ( 6.536332e-9zt-1.120083e-6 )zt+1.001685e-4)*zt &
602	& -9.095290e-3 )zt+6.793952e-2 )zt+999.842594
603	! seawater volumic mass atm pressure
604	zr2= ( ( ( 5.3875e-9zt-8.2467e-7 ) zt+7.6438e-5 ) *zt &
605	& -4.0899e-3 ) *zt+0.824493
606	zr3= ( -1.6546e-6zt+1.0227e-4 ) zt-5.72466e-3
607	zr4= 4.8314e-4
608	! potential volumic mass (reference to the surface)
609	zrhop= ( zr4zs + zr3zsr + zr2 ) *zs + zr1
610	zrhdr = zrhop / zcomp
611	ELSE
612	zrhdr = zrh / zcomp
613	ENDIF
614	#endif
615
616	! potential density of ambiant water at level jk :
617	zrhd = ( rhd(ji,jj,jk) * rau0 + rau0 )
618
619	! And now the Rib number numerator .
620	zrinum = grav * ( zrhd - zrhdr ) / rau0
621	zrinum = zrinum * ( fsdept(ji,jj,jk) - zref ) * tmask(ji,jj,jk)
622
623	! Resolved shear contribution to Rib at depth T-point (zdVsq)
624	ztx = ( ub( ji , jj ,jk) + ub(ji - 1, jj ,jk) ) &
625	& / MAX( 1. , umask( ji , jj ,jk) + umask(ji - 1, jj ,jk) )
626	zty = ( vb( ji , jj ,jk) + vb(ji ,jj - 1,jk) ) &
627	& / MAX( 1., vmask( ji , jj ,jk) + vmask(ji ,jj - 1,jk) )
628
629	zdVsq = ( zu - ztx ) * ( zu - ztx ) + ( zv - zty ) * ( zv - zty )
630
631	! Scalar turbulent velocity scale zws for hbl=gdept
632	zscale = zstabl + ( 1.0 - zstabl ) * epsilon
633	zehat = vonk * zscale * fsdept(ji,jj,jk) * zbuofdep
634	zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj)
635	zeta = zehat / ( zucube + epsln )
636
637	IF( zehat > 0. ) THEN
638	! Stable case
639	zws = vonk * zustar(ji,jj) / ( 1.0 + rconc1 * zeta )
640	ELSE
641	! Unstable case
642	#if defined key_kpplktb
643	! use lookup table
644	zd = zehat - dehatmin
645	il = INT( zd / dezehat )
646	il = MIN( il, nilktbm1 )
647	il = MAX( il, 1 )
648
649	ud = zustar(ji,jj) - ustmin
650	jl = INT( ud / deustar )
651	jl = MIN( jl, njlktbm1 )
652	jl = MAX( jl, 1 )
653
654	zfrac = zd / dezehat - FLOAT( il )
655	ufrac = ud / deustar - FLOAT( jl )
656	zwas = ( 1. - zfrac ) * wslktb(il,jl+1) + zfrac * wslktb(il+1,jl+1)
657	zwbs = ( 1. - zfrac ) * wslktb(il,jl ) + zfrac * wslktb(il+1,jl )
658	!
659	zws = ( 1. - ufrac ) * zwbs + ufrac * zwas
660	#else
661	! use analytical functions:
662	zcons = 0.5 + SIGN( 0.5 , ( rzetas - zeta ) )
663	zwcons = vonk * zustar(ji,jj) * ( ( ABS( rconas - rconcs * zeta ) )**pthird )
664	zwsun = vonk * zustar(ji,jj) * SQRT( ABS ( 1.0 - rconc2 * zeta ) )
665	!
666	zws = zcons * zwcons + ( 1.0 - zcons) * zwsun
667	#endif
668	ENDIF
669
670	! Turbulent shear contribution to Rib (zVtsq) bv frequency at levels ( ie T-point jk)
671	zrn2 = 0.5 * ( rn2(ji,jj,jk) + rn2(ji,jj,jk+1) )
672	zbvzed = SQRT( ABS( zrn2 ) )
673	zVtsq = fsdept(ji,jj,jk) * zws * zbvzed * Vtc
674
675	! Finally, the bulk Richardson number at depth fsdept(i,j,k)
676	zrib = zrinum / ( zdVsq + zVtsq + epsln )
677
678	! Find subscripts around the boundary layer depth, build the pipe
679	! ----------------------------------------------------------------
680
681	! Flag (zflagri = 1) if zrib < Ricr
682	zflagri = 0.5 + SIGN( 0.5, ( Ricr - zrib ) )
683	! Flag (zflagh = 1) if still within overall boundary layer
684	zflagh = 0.5 + SIGN( 0.5, ( fsdept(ji,jj,1) - zdept(ji,2) ) )
685
686	! Ekman layer depth
687	zek = zstabl * zekman(ji) + ( 1.0 - zstabl ) * zhmax(ji)
688	zflag = 0.5 + SIGN( 0.5, ( zek - fsdept(ji,jj,jk-1) ) )
689	zek = zflag * zek + ( 1.0 - zflag ) * zhmax(ji)
690	zflagek = 0.5 + SIGN( 0.5, ( zek - fsdept(ji,jj,jk) ) )
691	! Flag (zflagmo = 1) if still within stable Monin-Obukhov and in water
692	zmob = zucube / ( vonk * ( zbuofdep + epsln ) )
693	ztemp = zstabl * zmob + ( 1.0 - zstabl) * zhmax(ji)
694	ztemp = MIN( ztemp , zhmax(ji) )
695	zflagmo = 0.5 + SIGN( 0.5, ( ztemp - fsdept(ji,jj,jk) ) )
696
697	! No limitation by Monin Obukhov or Ekman depths:
698	! zflagek = 1.0
699	! zflagmo = 0.5 + SIGN( 0.5, ( zhmax(ji) - fsdept(ji,jj,jk) ) )
700
701	! Load pipe via zflagkb for later calculations
702	! Flag (zflagkb = 1) if zflagh = 1 and (zflagri = 0 or zflagek = 0 or zflagmo = 0)
703	zflagkb = zflagh * ( 1.0 - ( zflagri * zflagek * zflagmo ) )
704
705	zmask(ji,jk) = zflagh
706	jkp2 = MIN( jk+2 , ikbot )
707	jkm1 = MAX( jk-1 , 2 )
708	jkmax = MAX( jkmax, jk * INT( REAL( zflagh+epsln ) ) )
709
710	zdept(ji,1) = zdept(ji,1) + zflagkb * fsdept(ji,jj,jk-1)
711	zdept(ji,2) = zdept(ji,2) + zflagkb * fsdept(ji,jj,jk )
712	zdept(ji,3) = zdept(ji,3) + zflagkb * fsdept(ji,jj,jk+1)
713
714	zdepw(ji,1) = zdepw(ji,1) + zflagkb * fsdepw(ji,jj,jk-1)
715	zdepw(ji,2) = zdepw(ji,2) + zflagkb * fsdepw(ji,jj,jk )
716	zdepw(ji,3) = zdepw(ji,3) + zflagkb * fsdepw(ji,jj,jk+1)
717	zdepw(ji,4) = zdepw(ji,4) + zflagkb * fsdepw(ji,jj,jkp2)
718
719	zriblk(ji,1) = zriblk(ji,1) + zflagkb * zria(ji)
720	zriblk(ji,2) = zriblk(ji,2) + zflagkb * zrib
721
722	zmoek (ji,0) = zmoek (ji,0) + zflagkb * zek
723	zmoek (ji,1) = zmoek (ji,1) + zflagkb * zmoa(ji)
724	zmoek (ji,2) = zmoek (ji,2) + zflagkb * ztemp
725	! Save Monin Obukhov depth
726	zmoa (ji) = zmob
727
728	zvisc(ji,1) = zvisc(ji,1) + zflagkb * avmu(ji,jj,jkm1)
729	zvisc(ji,2) = zvisc(ji,2) + zflagkb * avmu(ji,jj,jk )
730	zvisc(ji,3) = zvisc(ji,3) + zflagkb * avmu(ji,jj,jk+1)
731	zvisc(ji,4) = zvisc(ji,4) + zflagkb * avmu(ji,jj,jkp2)
732
733	zdift(ji,1) = zdift(ji,1) + zflagkb * avt (ji,jj,jkm1)
734	zdift(ji,2) = zdift(ji,2) + zflagkb * avt (ji,jj,jk )
735	zdift(ji,3) = zdift(ji,3) + zflagkb * avt (ji,jj,jk+1)
736	zdift(ji,4) = zdift(ji,4) + zflagkb * avt (ji,jj,jkp2)
737
738	#if defined key_zdfddm
739	zdifs(ji,1) = zdifs(ji,1) + zflagkb * avs (ji,jj,jkm1)
740	zdifs(ji,2) = zdifs(ji,2) + zflagkb * avs (ji,jj,jk )
741	zdifs(ji,3) = zdifs(ji,3) + zflagkb * avs (ji,jj,jk+1)
742	zdifs(ji,4) = zdifs(ji,4) + zflagkb * avs (ji,jj,jkp2)
743	#endif
744	! Save the Richardson number
745	zria (ji) = zrib
746	#if defined key_cfg_1d
747	! store buoyancy length scale
748	buof(ji,jj,jk) = zbuofdep * tmask(ji,jj,jk)
749	! store Monin Obukhov
750	zmob = zstabl * zmob + ( 1.0 - zstabl) * fsdept(ji,jj,1)
751	mols(ji,jj,jk) = MIN( zmob , zhmax(ji) ) * tmask(ji,jj,jk)
752	! Bulk Richardson number
753	rib(ji,jj,jk) = zrib * tmask(ji,jj,jk)
754	#endif
755	END DO
756	END DO
757	!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
758	! III PROCESS THE PIPE
759	!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
760
761	DO ji = fs_2, fs_jpim1
762
763	! Find the boundary layer depth zhbl
764	! ----------------------------------------
765
766	! Interpolate monin Obukhov and critical Ri mumber depths
767	ztemp = zdept(ji,2) - zdept(ji,1)
768	zflag = ( Ricr - zriblk(ji,1) ) / ( zriblk(ji,2) - zriblk(ji,1) + epsln )
769	zhrib = zdept(ji,1) + zflag * ztemp
770
771	IF( zriblk(ji,2) < Ricr ) zhrib = zhmax(ji)
772
773	IF( zmoek(ji,2) < zdept(ji,2) ) THEN
774	IF ( zmoek(ji,1) < 0. ) THEN
775	zmob = zdept(ji,2) - epsln
776	ELSE
777	zmob = ztemp + zmoek(ji,1) - zmoek(ji,2)
778	zmob = ( zmoek(ji,1) * zdept(ji,2) - zmoek(ji,2) * zdept(ji,1) ) / zmob
779	zmob = MAX( zmob , zdept(ji,1) + epsln )
780	ENDIF
781	ELSE
782	zmob = zhmax(ji)
783	ENDIF
784	ztemp = MIN( zmob , zmoek(ji,0) )
785
786	! Finally, the boundary layer depth, zhbl
787	zhbl(ji) = MAX( fsdept(ji,jj,1) + epsln, MIN( zhrib , ztemp ) )
788
789	! Save hkpp for further diagnostics (optional)
790	hkpp(ji,jj) = zhbl(ji) * tmask(ji,jj,1)
791
792	! Correct mask if zhbl < fsdepw(ji,jj,2) for no viscosity/diffusivity enhancement at fsdepw(ji,jj,2)
793	! zflag = 1 if zhbl(ji) > fsdepw(ji,jj,2)
794	IF( zhbl(ji) < fsdepw(ji,jj,2) ) zmask(ji,2) = 0.
795
796
797	! Velocity scales at depth zhbl
798	! -----------------------------------
799
800	! Compute bouyancy forcing down to zhbl
801	ztemp = -hbf * zhbl(ji)
802	zatt1 = 1.0 - ( rabs * EXP( ztemp / xsi1 ) + ( 1.0 - rabs ) * EXP( ztemp / xsi2 ) )
803	zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * zatt1
804	zstabl = 0.5 + SIGN( 0.5 , zbuofdep )
805
806	zbuofdep = zbuofdep + zstabl * epsln
807
808	zscale = zstabl + ( 1.0 - zstabl ) * epsilon
809	zehat = vonk * zscale * zhbl(ji) * zbuofdep
810	zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj)
811	zeta = zehat / ( zucube + epsln )
812
813	IF( zehat > 0. ) THEN
814	! Stable case
815	zws = vonk * zustar(ji,jj) / ( 1.0 + rconc1 * zeta )
816	zwm = zws
817	ELSE
818	! Unstable case
819	#if defined key_kpplktb
820	! use lookup table
821	zd = zehat - dehatmin
822	il = INT( zd / dezehat )
823	il = MIN( il, nilktbm1 )
824	il = MAX( il, 1 )
825
826	ud = zustar(ji,jj) - ustmin
827	jl = INT( ud / deustar )
828	jl = MIN( jl, njlktbm1 )
829	jl = MAX( jl, 1 )
830
831	zfrac = zd / dezehat - FLOAT( il )
832	ufrac = ud / deustar - FLOAT( jl )
833	zwas = ( 1. - zfrac ) * wslktb(il,jl+1) + zfrac * wslktb(il+1,jl+1)
834	zwbs = ( 1. - zfrac ) * wslktb(il,jl ) + zfrac * wslktb(il+1,jl )
835	zwam = ( 1. - zfrac ) * wmlktb(il,jl+1) + zfrac * wmlktb(il+1,jl+1)
836	zwbm = ( 1. - zfrac ) * wmlktb(il,jl ) + zfrac * wmlktb(il+1,jl )
837	!
838	zws = ( 1. - ufrac ) * zwbs + ufrac * zwas
839	zwm = ( 1. - ufrac ) * zwbm + ufrac * zwam
840	#else
841	! use analytical functions
842	zconm = 0.5 + SIGN( 0.5, ( rzetam - zeta) )
843	zcons = 0.5 + SIGN( 0.5, ( rzetas - zeta) )
844
845	! Momentum : zeta < rzetam (zconm = 1)
846	! Scalars : zeta < rzetas (zcons = 1)
847	zwconm = zustar(ji,jj) * vonk * ( ( ABS( rconam - rconcm * zeta) )**pthird )
848	zwcons = zustar(ji,jj) * vonk * ( ( ABS( rconas - rconcs * zeta) )**pthird )
849
850	! Momentum : rzetam <= zeta < 0 (zconm = 0)
851	! Scalars : rzetas <= zeta < 0 (zcons = 0)
852	zwmun = SQRT( ABS( 1.0 - rconc2 * zeta ) )
853	zwsun = vonk * zustar(ji,jj) * zwmun
854	zwmun = vonk * zustar(ji,jj) * SQRT(zwmun)
855	!
856	zwm = zconm * zwconm + ( 1.0 - zconm ) * zwmun
857	zws = zcons * zwcons + ( 1.0 - zcons ) * zwsun
858
859	#endif
860	ENDIF
861
862
863	! Viscosity, diffusivity values and derivatives at h
864	! --------------------------------------------------------
865
866	! check between at which interfaces is located zhbl(ji)
867	! ztemp = 1, zdepw(ji,2) < zhbl < zdepw(ji,3)
868	! ztemp = 0, zdepw(ji,1) < zhbl < zdepw(ji,2)
869	ztemp = 0.5 + SIGN( 0.5, ( zhbl(ji) - zdepw(ji,2) ) )
870	zdep21 = zdepw(ji,2) - zdepw(ji,1) + epsln
871	zdep32 = zdepw(ji,3) - zdepw(ji,2) + epsln
872	zdep43 = zdepw(ji,4) - zdepw(ji,3) + epsln
873
874	! Compute R as in LMD94, eq D5b
875	zdelta = ( zhbl(ji) - zdepw(ji,2) ) * ztemp / zdep32 &
876	& + ( zhbl(ji) - zdepw(ji,1) ) * ( 1.0 - ztemp ) / zdep21
877
878	! Compute the vertical derivative of viscosities (zdzh) at z=zhbl(ji)
879	zdzup = ( zvisc(ji,2) - zvisc(ji,3) ) * ztemp / zdep32 &
880	& + ( zvisc(ji,1) - zvisc(ji,2) ) * ( 1.0 - ztemp ) / zdep21
881
882	zdzdn = ( zvisc(ji,3) - zvisc(ji,4) ) * ztemp / zdep43 &
883	& + ( zvisc(ji,2) - zvisc(ji,3) ) * ( 1.0 - ztemp ) / zdep32
884
885	! LMD94, eq D5b :
886	zdzh = ( 1.0 - zdelta ) * zdzup + zdelta * zdzdn
887	zdzh = MAX( zdzh , 0. )
888
889	! Compute viscosities (zvath) at z=zhbl(ji), LMD94 eq D5a
890	zvath = ztemp * ( zvisc(ji,3) + zdzh * ( zdepw(ji,3) - zhbl(ji) ) ) &
891	& + ( 1.0 - ztemp ) * ( zvisc(ji,2) + zdzh * ( zdepw(ji,2) - zhbl(ji) ) )
892
893	! Compute G (zgat1) and its derivative (zdat1) at z=hbl(ji), LMD94 eq 18
894
895	! Vertical derivative of velocity scale divided by velocity scale squared at z=hbl(ji)
896	! (non zero only in stable conditions)
897	zflag = -zstabl * rconc1 * zbuofdep / ( zucube * zustar(ji,jj) + epsln )
898
899	! G at its derivative at z=hbl:
900	zgat1 = zvath / ( zhbl(ji) * ( zwm + epsln ) )
901	zdat1 = -zdzh / ( zwm + epsln ) - zflag * zvath / zhbl(ji)
902
903	! G coefficients, LMD94 eq 17
904	za2m(ji) = -2.0 + 3.0 * zgat1 - zdat1
905	za3m(ji) = 1.0 - 2.0 * zgat1 + zdat1
906
907
908	! Compute the vertical derivative of temperature diffusivities (zdzh) at z=zhbl(ji)
909	zdzup = ( zdift(ji,2) - zdift(ji,3) ) * ztemp / zdep32 &
910	& + ( zdift(ji,1) - zdift(ji,2) ) * ( 1.0 - ztemp ) / zdep21
911
912	zdzdn = ( zdift(ji,3) - zdift(ji,4) ) * ztemp / zdep43 &
913	& + ( zdift(ji,2) - zdift(ji,3) ) * ( 1.0 - ztemp ) / zdep32
914
915	! LMD94, eq D5b :
916	zdzh = ( 1.0 - zdelta ) * zdzup + zdelta * zdzdn
917	zdzh = MAX( zdzh , 0. )
918
919
920	! Compute diffusivities (zvath) at z=zhbl(ji), LMD94 eq D5a
921	zvath = ztemp * ( zdift(ji,3) + zdzh * ( zdepw(ji,3) - zhbl(ji) ) ) &
922	& + ( 1.0 - ztemp ) * ( zdift(ji,2) + zdzh * ( zdepw(ji,2) - zhbl(ji) ) )
923
924	! G at its derivative at z=hbl:
925	zgat1 = zvath / ( zhbl(ji) * ( zws + epsln ) )
926	zdat1 = -zdzh / ( zws + epsln ) - zflag * zvath / zhbl(ji)
927
928	! G coefficients, LMD94 eq 17
929	za2t(ji) = -2.0 + 3.0 * zgat1 - zdat1
930	za3t(ji) = 1.0 - 2.0 * zgat1 + zdat1
931
932	#if defined key_zdfddm
933	! Compute the vertical derivative of salinities diffusivities (zdzh) at z=zhbl(ji)
934	zdzup = ( zdifs(ji,2) - zdifs(ji,3) ) * ztemp / zdep32 &
935	& + ( zdifs(ji,1) - zdifs(ji,2) ) * ( 1.0 - ztemp ) / zdep21
936
937	zdzdn = ( zdifs(ji,3) - zdifs(ji,4) ) * ztemp / zdep43 &
938	& + ( zdifs(ji,2) - zdifs(ji,3) ) * ( 1.0 - ztemp ) / zdep32
939
940	! LMD94, eq D5b :
941	zdzh = ( 1.0 - zdelta ) * zdzup + zdelta * zdzdn
942	zdzh = MAX( zdzh , 0. )
943
944	! Compute diffusivities (zvath) at z=zhbl(ji), LMD94 eq D5a
945	zvath = ztemp * ( zdifs(ji,3) + zdzh * ( zdepw(ji,3) - zhbl(ji) ) ) &
946	& + ( 1.0 - ztemp ) * ( zdifs(ji,2) + zdzh * ( zdepw(ji,2) - zhbl(ji) ) )
947
948	! G at its derivative at z=hbl:
949	zgat1 = zvath / ( zhbl(ji) * ( zws + epsln ) )
950	zdat1 = -zdzh / ( zws + epsln ) - zflag * zvath / zhbl(ji)
951
952	! G coefficients, LMD94 eq 17
953	za2s(ji) = -2.0 + 3.0 * zgat1 - zdat1
954	za3s(ji) = 1.0 - 2.0 * zgat1 + zdat1
955	#endif
956
957	!-------------------turn off interior matching here------
958	! za2(ji,1) = -2.0
959	! za3(ji,1) = 1.0
960	! za2(ji,2) = -2.0
961	! za3(ji,2) = 1.0
962	!--------------------------------------------------------
963
964	! Compute Enhanced Mixing Coefficients (LMD94,eq D6)
965	! ---------------------------------------------------------------
966
967	! Delta
968	zdelta = ( zhbl(ji) - zdept(ji,1) ) / ( zdept(ji,2) - zdept(ji,1) + epsln )
969	zdelta2 = zdelta * zdelta
970
971	! Mixing coefficients at first level above h (zdept(ji,1))
972	! and at first interface in the pipe (zdepw(ji,2))
973
974	! At first T level above h (zdept(ji,1)) (always in the boundary layer)
975	zsig = zdept(ji,1) / zhbl(ji)
976	ztemp = zstabl * zsig + ( 1.0 - zstabl ) * MIN( zsig , epsilon )
977	zehat = vonk * ztemp * zhbl(ji) * zbuofdep
978	zeta = zehat / ( zucube + epsln)
979	zwst = vonk * zustar(ji,jj) / ( ABS( 1.0 + rconc1 * zeta ) + epsln)
980	zwm = zstabl * zwst + ( 1.0 - zstabl ) * zwm
981	zws = zstabl * zwst + ( 1.0 - zstabl ) * zws
982
983	zkm1m = zhbl(ji) * zwm * zsig * ( 1.0 + zsig * ( za2m(ji) + zsig * za3m(ji) ) )
984	zkm1t = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2t(ji) + zsig * za3t(ji) ) )
985	#if defined key_zdfddm
986	zkm1s = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2s(ji) + zsig * za3s(ji) ) )
987	#endif
988	! At first W level in the pipe (zdepw(ji,2)) (not always in the boundary layer ):
989	zsig = MIN( zdepw(ji,2) / zhbl(ji) , 1.0 )
990	ztemp = zstabl * zsig + ( 1.0 - zstabl ) * MIN( zsig , epsilon )
991	zehat = vonk * ztemp * zhbl(ji) * zbuofdep
992	zeta = zehat / ( zucube + epsln )
993	zwst = vonk * zustar(ji,jj) / ( ABS( 1.0 + rconc1 * zeta ) + epsln)
994	zws = zstabl * zws + ( 1.0 - zstabl ) * zws
995	zwm = zstabl * zws + ( 1.0 - zstabl ) * zwm
996
997	zkmpm(ji) = zhbl(ji) * zwm * zsig * ( 1.0 + zsig * ( za2m(ji) + zsig * za3m(ji) ) )
998	zkmpt(ji) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2t(ji) + zsig * za3t(ji) ) )
999	#if defined key_zdfddm
1000	zkmps(ji) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2s(ji) + zsig * za3s(ji) ) )
1001	#endif
1002
1003	! check if this point is in the boundary layer,else take interior viscosity/diffusivity:
1004	zflag = 0.5 + SIGN( 0.5, ( zhbl(ji) - zdepw(ji,2) ) )
1005	zkmpm(ji) = zkmpm(ji) * zflag + ( 1.0 - zflag ) * zvisc(ji,2)
1006	zkmpt(ji) = zkmpt(ji) * zflag + ( 1.0 - zflag ) * zdift(ji,2)
1007	#if defined key_zdfddm
1008	zkmps(ji) = zkmps(ji) * zflag + ( 1.0 - zflag ) * zdifs(ji,2)
1009	#endif
1010
1011	! Enhanced viscosity/diffusivity at zdepw(ji,2)
1012	ztemp = ( 1.0 - 2.0 * zdelta + zdelta2 ) * zkm1m + zdelta2 * zkmpm(ji)
1013	zkmpm(ji) = ( 1.0 - zdelta ) * zvisc(ji,2) + zdelta * ztemp
1014	ztemp = ( 1.0 - 2.0 * zdelta + zdelta2 ) * zkm1t + zdelta2 * zkmpt(ji)
1015	zkmpt(ji) = ( 1.0 - zdelta ) * zdift(ji,2) + zdelta * ztemp
1016	#if defined key_zdfddm
1017	ztemp = ( 1.0 - 2.0 * zdelta + zdelta2 ) * zkm1s + zdelta2 * zkmps(ji)
1018	zkmps(ji) = ( 1.0 - zdelta ) * zdifs(ji,2) + zdelta * ztemp
1019	#endif
1020
1021	END DO
1022	!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
1023	! IV. Compute vertical eddy viscosity and diffusivity coefficients
1024	!<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
1025
1026	DO jk = 2, jkmax
1027
1028	! Compute turbulent velocity scales on the interfaces
1029	! --------------------------------------------------------
1030	DO ji = fs_2, fs_jpim1
1031	zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * zatt1
1032	zstabl = 0.5 + SIGN( 0.5 , zbuofdep )
1033	zbuofdep = zbuofdep + zstabl * epsln
1034	zsig = fsdepw(ji,jj,jk) / zhbl(ji)
1035	ztemp = zstabl * zsig + ( 1. - zstabl ) * MIN( zsig , epsilon )
1036	zehat = vonk * ztemp * zhbl(ji) * zbuofdep
1037	zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj)
1038	zeta = zehat / ( zucube + epsln )
1039
1040	IF( zehat > 0. ) THEN
1041	! Stable case
1042	zws = vonk * zustar(ji,jj) / ( 1.0 + rconc1 * zeta )
1043	zwm = zws
1044	ELSE
1045	! Unstable case
1046	#if defined key_kpplktb
1047	! use lookup table
1048	zd = zehat - dehatmin
1049	il = INT( zd / dezehat )
1050	il = MIN( il, nilktbm1 )
1051	il = MAX( il, 1 )
1052
1053	ud = zustar(ji,jj) - ustmin
1054	jl = INT( ud / deustar )
1055	jl = MIN( jl, njlktbm1 )
1056	jl = MAX( jl, 1 )
1057
1058	zfrac = zd / dezehat - FLOAT( il )
1059	ufrac = ud / deustar - FLOAT( jl )
1060	zwas = ( 1. - zfrac ) * wslktb(il,jl+1) + zfrac * wslktb(il+1,jl+1)
1061	zwbs = ( 1. - zfrac ) * wslktb(il,jl ) + zfrac * wslktb(il+1,jl )
1062	zwam = ( 1. - zfrac ) * wmlktb(il,jl+1) + zfrac * wmlktb(il+1,jl+1)
1063	zwbm = ( 1. - zfrac ) * wmlktb(il,jl ) + zfrac * wmlktb(il+1,jl )
1064	!
1065	zws = ( 1. - ufrac ) * zwbs + ufrac * zwas
1066	zwm = ( 1. - ufrac ) * zwbm + ufrac * zwam
1067	#else
1068	! use analytical functions
1069	zconm = 0.5 + SIGN( 0.5, ( rzetam - zeta) )
1070	zcons = 0.5 + SIGN( 0.5, ( rzetas - zeta) )
1071
1072	! Momentum : zeta < rzetam (zconm = 1)
1073	! Scalars : zeta < rzetas (zcons = 1)
1074	zwconm = zustar(ji,jj) * vonk * ( ( ABS( rconam - rconcm * zeta) )**pthird )
1075	zwcons = zustar(ji,jj) * vonk * ( ( ABS( rconas - rconcs * zeta) )**pthird )
1076
1077	! Momentum : rzetam <= zeta < 0 (zconm = 0)
1078	! Scalars : rzetas <= zeta < 0 (zcons = 0)
1079	zwmun = SQRT( ABS( 1.0 - rconc2 * zeta ) )
1080	zwsun = vonk * zustar(ji,jj) * zwmun
1081	zwmun = vonk * zustar(ji,jj) * SQRT(zwmun)
1082	!
1083	zwm = zconm * zwconm + ( 1.0 - zconm ) * zwmun
1084	zws = zcons * zwcons + ( 1.0 - zcons ) * zwsun
1085
1086	#endif
1087	ENDIF
1088
1089	zblcm(ji,jk) = zhbl(ji) * zwm * zsig * ( 1.0 + zsig * ( za2m(ji) + zsig * za3m(ji) ) )
1090	zblct(ji,jk) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2t(ji) + zsig * za3t(ji) ) )
1091	#if defined key_zdfddm
1092	zblcs(ji,jk) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2s(ji) + zsig * za3s(ji) ) )
1093	#endif
1094	! Compute Nonlocal transport term = ghats * <ws>o
1095	! ----------------------------------------------------
1096	ghats(ji,jj,jk-1) = ( 1. - zstabl ) * rcg / ( zws * zhbl(ji) + epsln ) * tmask(ji,jj,jk)
1097
1098	END DO
1099	END DO
1100	! Combine interior and boundary layer coefficients and nonlocal term
1101	! -----------------------------------------------------------------------
1102	DO jk = 2, jpkm1
1103	DO ji = fs_2, fs_jpim1
1104	zflag = zmask(ji,jk) * zmask(ji,jk+1)
1105	zviscos(ji,jj,jk) = ( 1.0 - zmask(ji,jk) ) * avmu (ji,jj,jk) & ! interior viscosities
1106	& + zflag * zblcm(ji,jk ) & ! boundary layer viscosities
1107	& + zmask(ji,jk) * ( 1.0 - zflag ) * zkmpm(ji ) ! viscosity enhancement at W_level near zhbl
1108
1109	zviscos(ji,jj,jk) = zviscos(ji,jj,jk) * tmask(ji,jj,jk)
1110
1111
1112	zdiffut(ji,jj,jk) = ( 1.0 - zmask(ji,jk) ) * avt (ji,jj,jk) & ! interior diffusivities
1113	& + zflag * zblct(ji,jk ) & ! boundary layer diffusivities
1114	& + zmask(ji,jk) * ( 1.0 - zflag ) * zkmpt(ji ) ! diffusivity enhancement at W_level near zhbl
1115
1116	zdiffut(ji,jj,jk) = zdiffut(ji,jj,jk) * tmask(ji,jj,jk)
1117	#if defined key_zdfddm
1118	zdiffus(ji,jj,jk) = ( 1.0 - zmask(ji,jk) ) * avs (ji,jj,jk) & ! interior diffusivities
1119	& + zflag * zblcs(ji,jk ) & ! boundary layer diffusivities
1120	& + zmask(ji,jk) * ( 1.0 - zflag ) * zkmps(ji ) ! diffusivity enhancement at W_level near zhbl
1121
1122	zdiffus(ji,jj,jk) = zdiffus(ji,jj,jk) * tmask(ji,jj,jk)
1123	#endif
1124	! Non local flux in the boundary layer only
1125	ghats(ji,jj,jk-1) = zmask(ji,jk) * ghats(ji,jj,jk-1)
1126
1127	ENDDO
1128	END DO
1129	! ! ===============
1130	END DO ! End of slab
1131	! ! ===============
1132
1133	! Lateral boundary conditions on zvicos and zdiffus (sign unchanged)
1134	CALL lbc_lnk( zviscos(:,:,:), 'U', 1. ) ; CALL lbc_lnk( zdiffut(:,:,:), 'W', 1. )
1135	#if defined key_zdfddm
1136	CALL lbc_lnk( zdiffus(:,:,:), 'W', 1. )
1137	#endif
1138
1139	SELECT CASE ( nave )
1140	!
1141	CASE ( 0 ) ! no viscosity and diffusivity smoothing
1142
1143	DO jk = 2, jpkm1
1144	DO jj = 2, jpjm1
1145	DO ji = fs_2, fs_jpim1
1146	avmu(ji,jj,jk) = ( zviscos(ji,jj,jk) + zviscos(ji+1,jj,jk) ) &
1147	& / MAX( 1., tmask(ji,jj,jk) + tmask (ji + 1,jj,jk) ) * umask(ji,jj,jk)
1148
1149	avmv(ji,jj,jk) = ( zviscos(ji,jj,jk) + zviscos(ji,jj+1,jk) ) &
1150	& / MAX( 1., tmask(ji,jj,jk) + tmask (ji,jj+1,jk) ) * vmask(ji,jj,jk)
1151
1152	avt (ji,jj,jk) = zdiffut(ji,jj,jk) * tmask(ji,jj,jk)
1153	#if defined key_zdfddm
1154	avs (ji,jj,jk) = zdiffus(ji,jj,jk) * tmask(ji,jj,jk)
1155	#endif
1156	END DO
1157	END DO
1158	END DO
1159
1160	CASE ( 1 ) ! viscosity and diffusivity smoothing
1161	!
1162	! ( 1/2 1 1/2 ) ( 1/2 1/2 ) ( 1/2 1 1/2 )
1163	! avt = 1/8 ( 1 2 1 ) avmu = 1/4 ( 1 1 ) avmv= 1/4 ( 1/2 1 1/2 )
1164	! ( 1/2 1 1/2 ) ( 1/2 1/2 )
1165
1166	DO jk = 2, jpkm1
1167	DO jj = 2, jpjm1
1168	DO ji = fs_2, fs_jpim1
1169
1170	avmu(ji,jj,jk) = ( zviscos(ji ,jj ,jk) + zviscos(ji+1,jj ,jk) &
1171	& +.5*( zviscos(ji ,jj-1,jk) + zviscos(ji+1,jj-1,jk) &
1172	& +zviscos(ji ,jj+1,jk) + zviscos(ji+1,jj+1,jk) ) ) * eumean(ji,jj,jk)
1173
1174	avmv(ji,jj,jk) = ( zviscos(ji ,jj ,jk) + zviscos(ji ,jj+1,jk) &
1175	& +.5*( zviscos(ji-1,jj ,jk) + zviscos(ji-1,jj+1,jk) &
1176	& +zviscos(ji+1,jj ,jk) + zviscos(ji+1,jj+1,jk) ) ) * evmean(ji,jj,jk)
1177
1178	avt (ji,jj,jk) = ( .5*( zdiffut(ji-1,jj+1,jk) + zdiffut(ji-1,jj-1,jk) &
1179	& +zdiffut(ji+1,jj+1,jk) + zdiffut(ji+1,jj-1,jk) ) &
1180	& +1.*( zdiffut(ji-1,jj ,jk) + zdiffut(ji ,jj+1,jk) &
1181	& +zdiffut(ji ,jj-1,jk) + zdiffut(ji+1,jj ,jk) ) &
1182	& +2.* zdiffut(ji ,jj ,jk) ) * etmean(ji,jj,jk)
1183	#if defined key_zdfddm
1184	avs (ji,jj,jk) = ( .5*( zdiffus(ji-1,jj+1,jk) + zdiffus(ji-1,jj-1,jk) &
1185	& +zdiffus(ji+1,jj+1,jk) + zdiffus(ji+1,jj-1,jk) ) &
1186	& +1.*( zdiffus(ji-1,jj ,jk) + zdiffus(ji ,jj+1,jk) &
1187	& +zdiffus(ji ,jj-1,jk) + zdiffus(ji+1,jj ,jk) ) &
1188	& +2.* zdiffus(ji ,jj ,jk) ) * etmean(ji,jj,jk)
1189	#endif
1190	END DO
1191	END DO
1192	END DO
1193
1194	END SELECT
1195
1196	DO jk = 2, jpkm1 ! vertical slab
1197	!
1198	! Minimum value on the eddy diffusivity
1199	! ----------------------------------------
1200	DO jj = 2, jpjm1
1201	DO ji = fs_2, fs_jpim1 ! vector opt.
1202	avt(ji,jj,jk) = MAX( avt(ji,jj,jk), avtb(jk) ) * tmask(ji,jj,jk)
1203	#if defined key_zdfddm
1204	avs(ji,jj,jk) = MAX( avs(ji,jj,jk), avtb(jk) ) * tmask(ji,jj,jk)
1205	#endif
1206	END DO
1207	END DO
1208
1209	!
1210	! Minimum value on the eddy viscosity
1211	! ----------------------------------------
1212	DO jj = 1, jpj
1213	DO ji = 1, jpi
1214	avmu(ji,jj,jk) = MAX( avmu(ji,jj,jk), avmb(jk) ) * umask(ji,jj,jk)
1215	avmv(ji,jj,jk) = MAX( avmv(ji,jj,jk), avmb(jk) ) * vmask(ji,jj,jk)
1216	END DO
1217	END DO
1218	!
1219	END DO
1220
1221	! Lateral boundary conditions on avt (sign unchanged)
1222	CALL lbc_lnk( hkpp(:,:), 'T', 1. )
1223
1224	! Lateral boundary conditions on avt (sign unchanged)
1225	CALL lbc_lnk( avt(:,:,:), 'W', 1. )
1226	#if defined key_zdfddm
1227	CALL lbc_lnk( avs(:,:,:), 'W', 1. )
1228	#endif
1229	! Lateral boundary conditions (avmu,avmv) (U- and V- points, sign unchanged)
1230	CALL lbc_lnk( avmu(:,:,:), 'U', 1. ) ; CALL lbc_lnk( avmv(:,:,:), 'V', 1. )
1231
1232	IF(ln_ctl) THEN
1233	#if defined key_zdfddm
1234	CALL prt_ctl(tab3d_1=avt , clinfo1=' kpp - t: ', tab3d_2=avs , clinfo2=' s: ', ovlap=1, kdim=jpk)
1235	#else
1236	CALL prt_ctl(tab3d_1=avt , clinfo1=' kpp - t: ', ovlap=1, kdim=jpk)
1237	#endif
1238	CALL prt_ctl(tab3d_1=avmu, clinfo1=' kpp - u: ', mask1=umask, &
1239	& tab3d_2=avmv, clinfo2= ' v: ', mask2=vmask, ovlap=1, kdim=jpk)
1240	ENDIF
1241
1242	END SUBROUTINE zdf_kpp
1243
1244
1245	SUBROUTINE tra_kpp( kt )
1246	!!----------------------------------------------------------------------
1247	!! * ROUTINE tra_kpp *
1248	!!
1249	!! ** Purpose : compute and add to the tracer trend the non-local
1250	!! tracer flux
1251	!!
1252	!! ** Method : ???
1253	!!
1254	!! history :
1255	!! 9.0 ! 05-11 (G. Madec) Original code
1256	!!----------------------------------------------------------------------
1257	!! * Modules used
1258	USE oce, ONLY : ztrdt => ua, & ! use ua as 3D workspace
1259	ztrds => va ! use va as 3D workspace
1260	!!----------------------------------------------------------------------
1261	INTEGER, INTENT(in) :: kt
1262	INTEGER :: ji, jj, jk
1263
1264	IF( kt == nit000 ) THEN
1265	IF(lwp) WRITE(numout,*)
1266	IF(lwp) WRITE(numout,*) 'tra_kpp : KPP non-local tracer fluxes'
1267	IF(lwp) WRITE(numout,*) '~~~~~~~ '
1268	ENDIF
1269
1270
1271	! Save ta and sa trends
1272	IF( l_trdtra ) THEN
1273	ztrdt(:,:,:) = ta(:,:,:)
1274	ztrds(:,:,:) = sa(:,:,:)
1275	ENDIF
1276
1277	! add non-local temperature and salinity flux ( in convective case only)
1278	DO jk = 1, jpkm1
1279	DO jj = 2, jpjm1
1280	DO ji = fs_2, fs_jpim1
1281	ta(ji,jj,jk) = ta(ji,jj,jk) &
1282	& - ( ghats(ji,jj,jk ) * avt(ji,jj,jk ) &
1283	& - ghats(ji,jj,jk+1) * avt(ji,jj,jk+1) ) * wt0(ji,jj) / fse3t(ji,jj,jk)
1284	sa(ji,jj,jk) = sa(ji,jj,jk) &
1285	& - ( ghats(ji,jj,jk ) * fsavs(ji,jj,jk ) &
1286	& - ghats(ji,jj,jk+1) * fsavs(ji,jj,jk+1) ) * ws0(ji,jj) / fse3t(ji,jj,jk)
1287	END DO
1288	END DO
1289	END DO
1290
1291	! save the non-local tracer flux trends for diagnostic
1292	IF( l_trdtra ) THEN
1293	ztrdt(:,:,:) = ta(:,:,:) - ztrdt(:,:,:)
1294	ztrds(:,:,:) = sa(:,:,:) - ztrds(:,:,:)
1295	!!bug gm jpttdzdf ==> jpttkpp
1296	CALL trd_mod(ztrdt, ztrds, jptra_trd_zdf, 'TRA', kt)
1297	ENDIF
1298
1299	IF(ln_ctl) THEN
1300	CALL prt_ctl( tab3d_1=ta, clinfo1=' kpp - Ta: ', mask1=tmask, &
1301	& tab3d_2=sa, clinfo2= ' Sa: ', mask2=tmask, clinfo3='tra' )
1302	ENDIF
1303
1304	END SUBROUTINE tra_kpp
1305
1306
1307	SUBROUTINE zdf_kpp_init
1308	!!----------------------------------------------------------------------
1309	!! * ROUTINE zdf_kpp_init *
1310	!!
1311	!! ** Purpose : Initialization of the vertical eddy diffivity and
1312	!! viscosity when using a kpp turbulent closure scheme
1313	!!
1314	!! ** Method : Read the namkpp namelist and check the parameters
1315	!! called at the first timestep (nit000)
1316	!!
1317	!! ** input : Namlist namkpp
1318	!!
1319	!!
1320	!! history :
1321	!! 8.1 ! 00-02 (J. Chanut) KPP Mixing
1322	!! 9.0 ! 05-01 (C. Ethe) F90 : free form
1323	!!----------------------------------------------------------------------
1324	!! * local declarations
1325
1326	INTEGER :: &
1327	ji, jj, jk ! dummy loop indices
1328
1329	#if ! defined key_kppcustom
1330	INTEGER :: &
1331	jm ! dummy loop indices
1332	REAL(wp) :: & !!! tempory scalars
1333	zref, zdist
1334	#endif
1335
1336	#if defined key_kpplktb
1337	REAL(wp) :: & !!! tempory scalars
1338	zustar, &
1339	zucube, zustvk, &
1340	zeta, zehat
1341	#endif
1342	REAL(wp) :: & !!! tempory scalars
1343	zhbf
1344	LOGICAL :: &
1345	ll_kppcustom, & ! 1st ocean level taken as surface layer
1346	ll_kpplktb ! Lookup table for turbul. velocity scales
1347
1348	NAMELIST/namkpp/ ln_kpprimix, difmiw, difsiw, Riinfty, difri, bvsqcon, difcon, nave, navb
1349
1350	!!----------------------------------------------------------------------
1351
1352	! Read Namelist namtke : Turbulente Kinetic Energy
1353	! --------------------
1354	REWIND ( numnam )
1355	READ ( numnam, namkpp )
1356
1357	! Parameter control and print
1358	! ---------------------------
1359	REWIND( numnam )
1360	READ ( numnam, namkpp )
1361
1362	! Control print
1363	IF(lwp) THEN
1364	WRITE(numout,*)
1365	WRITE(numout,*) 'zdf_kpp_init : kpp turbulent closure scheme'
1366	WRITE(numout,*) '~~~~~~~~~~~~'
1367	WRITE(numout,*) ' Namelist namkpp : set tke mixing parameters'
1368	WRITE(numout,*) ' Shear instability mixing ln_kpprimix = ', ln_kpprimix
1369	WRITE(numout,*) ' max. internal wave viscosity difmiw = ', difmiw
1370	WRITE(numout,*) ' max. internal wave diffusivity difsiw = ', difsiw
1371	WRITE(numout,*) ' Richardson Number limit for shear instability Riinfty = ', Riinfty
1372	WRITE(numout,*) ' max. shear mixing at Rig = 0 difri = ', difri
1373	WRITE(numout,*) ' Brunt-Vaisala squared for max. convection bvsqcon = ', bvsqcon
1374	WRITE(numout,*) ' max. mix. in interior convec. difcon = ', difcon
1375	WRITE(numout,*) ' horizontal average flag nave = ', nave
1376	WRITE(numout,*) ' constant background or profile navb = ', navb
1377	ENDIF
1378
1379	ll_kppcustom = .FALSE.
1380	ll_kpplktb = .FALSE.
1381
1382	#if defined key_kppcustom
1383	ll_kppcustom = .TRUE.
1384	#endif
1385	#if defined key_kpplktb
1386	ll_kpplktb = .TRUE.
1387	#endif
1388	IF(lwp) THEN
1389	WRITE(numout,*) ' Lookup table for turbul. velocity scales ll_kpplktb = ', ll_kpplktb
1390	WRITE(numout,*) ' 1st ocean level taken as surface layer ll_kppcustom = ', ll_kppcustom
1391	WRITE(numout,*) ' '
1392	ENDIF
1393
1394	IF( lk_zdfddm) THEN
1395	IF(lwp) THEN
1396	WRITE(numout,*)
1397	WRITE(numout,*) ' Double diffusion mixing on temperature and salinity '
1398	WRITE(numout,*) ' CAUTION : done in routine zdfkpp, not in routine zdfddm '
1399	WRITE(numout,*) ' '
1400	ENDIF
1401	ENDIF
1402
1403
1404
1405	!set constants not in namelist
1406	!-----------------------------
1407	Vtc = rconcv * SQRT( 0.2 / ( rconcs * epsilon ) ) / ( vonk * vonk * Ricr )
1408	rcg = rcstar * vonk * ( rconcs * vonk * epsilon )**pthird
1409
1410	IF(lwp) THEN
1411	WRITE(numout,*) ' Constant value for unreso. turbul. velocity shear Vtc = ', Vtc
1412	WRITE(numout,*) ' Non-dimensional coef. for nonlocal transport rcg = ', rcg
1413	WRITE(numout,*) ' '
1414	ENDIF
1415
1416	! ratt is the attenuation coefficient for solar flux
1417	! Should be different is s_coordinate
1418	DO jk = 1, jpk
1419	zhbf = - fsdept(1,1,jk) * hbf
1420	ratt(jk) = 1.0 - ( rabs * EXP( zhbf / xsi1 ) + ( 1.0 - rabs ) * EXP( zhbf / xsi2 ) )
1421	ENDDO
1422
1423	! Horizontal average : initialization of weighting arrays
1424	! -------------------
1425
1426	SELECT CASE ( nave )
1427
1428	CASE ( 0 ) ! no horizontal average
1429	IF(lwp) WRITE(numout,*) ' no horizontal average on avt, avmu, avmv'
1430	IF(lwp) WRITE(numout,*) ' only in very high horizontal resolution !'
1431	! weighting mean arrays etmean, eumean and evmean
1432	! ( 1 1 ) ( 1 )
1433	! avt = 1/4 ( 1 1 ) avmu = 1/2 ( 1 1 ) avmv= 1/2 ( 1 )
1434	!
1435	etmean(:,:,:) = 0.e0
1436	eumean(:,:,:) = 0.e0
1437	evmean(:,:,:) = 0.e0
1438
1439	DO jk = 1, jpkm1
1440	DO jj = 2, jpjm1
1441	DO ji = 2, jpim1 ! vector opt.
1442	etmean(ji,jj,jk) = tmask(ji,jj,jk) &
1443	& / MAX( 1., umask(ji-1,jj ,jk) + umask(ji,jj,jk) &
1444	& + vmask(ji ,jj-1,jk) + vmask(ji,jj,jk) )
1445
1446	eumean(ji,jj,jk) = umask(ji,jj,jk) &
1447	& / MAX( 1., tmask(ji,jj,jk) + tmask(ji+1,jj ,jk) )
1448
1449	evmean(ji,jj,jk) = vmask(ji,jj,jk) &
1450	& / MAX( 1., tmask(ji,jj,jk) + tmask(ji ,jj+1,jk) )
1451	END DO
1452	END DO
1453	END DO
1454
1455	CASE ( 1 ) ! horizontal average
1456	IF(lwp) WRITE(numout,*) ' horizontal average on avt, avmu, avmv'
1457	! weighting mean arrays etmean, eumean and evmean
1458	! ( 1/2 1 1/2 ) ( 1/2 1/2 ) ( 1/2 1 1/2 )
1459	! avt = 1/8 ( 1 2 1 ) avmu = 1/4 ( 1 1 ) avmv= 1/4 ( 1/2 1 1/2 )
1460	! ( 1/2 1 1/2 ) ( 1/2 1/2 )
1461	etmean(:,:,:) = 0.e0
1462	eumean(:,:,:) = 0.e0
1463	evmean(:,:,:) = 0.e0
1464
1465	DO jk = 1, jpkm1
1466	DO jj = 2, jpjm1
1467	DO ji = fs_2, fs_jpim1 ! vector opt.
1468	etmean(ji,jj,jk) = tmask(ji, jj,jk) &
1469	& / MAX( 1., 2.* tmask(ji,jj,jk) &
1470	& +.5 * ( tmask(ji-1,jj+1,jk) + tmask(ji-1,jj-1,jk) &
1471	& +tmask(ji+1,jj+1,jk) + tmask(ji+1,jj-1,jk) ) &
1472	& +1. * ( tmask(ji-1,jj ,jk) + tmask(ji ,jj+1,jk) &
1473	& +tmask(ji ,jj-1,jk) + tmask(ji+1,jj ,jk) ) )
1474
1475	eumean(ji,jj,jk) = umask(ji,jj,jk) &
1476	& / MAX( 1., tmask(ji,jj ,jk) + tmask(ji+1,jj ,jk) &
1477	& +.5 * ( tmask(ji,jj-1,jk) + tmask(ji+1,jj-1,jk) &
1478	& +tmask(ji,jj+1,jk) + tmask(ji+1,jj+1,jk) ) )
1479
1480	evmean(ji,jj,jk) = vmask(ji,jj,jk) &
1481	& / MAX( 1., tmask(ji ,jj,jk) + tmask(ji ,jj+1,jk) &
1482	& +.5 * ( tmask(ji-1,jj,jk) + tmask(ji-1,jj+1,jk) &
1483	& +tmask(ji+1,jj,jk) + tmask(ji+1,jj+1,jk) ) )
1484	END DO
1485	END DO
1486	END DO
1487
1488	CASE DEFAULT
1489	WRITE(ctmp1,*) ' bad flag value for nave = ', nave
1490	CALL ctl_stop( ctmp1 )
1491
1492	END SELECT
1493
1494
1495
1496	! Background eddy viscosity and diffusivity profil
1497	! ------------------------------------------------
1498	IF( navb == 0 ) THEN
1499	! Define avmb, avtb from namelist parameter
1500	avmb(:) = avm0
1501	avtb(:) = avt0
1502	ELSE
1503	! Background profile of avt (fit a theoretical/observational profile (Krauss 1990)
1504	avmb(:) = avm0
1505	avtb(:) = 1.e-5 + 2.8e-8 * gdepw_0(:) ! m2/s
1506	ENDIF
1507
1508	! Increase the background in the surface layers
1509	!! avmb(1) = 1. * avmb(1) ; avtb(1) = 1. * avtb(1)
1510	!! avmb(2) = 1. * avmb(2) ; avtb(2) = 1. * avtb(2)
1511	!! avmb(3) = 1. * avmb(3) ; avtb(3) = 1. * avtb(3)
1512	!! avmb(4) = 1. * avmb(4) ; avtb(4) = 1. * avtb(4)
1513
1514
1515	! Initialization of vertical eddy coef. to the background value
1516	! -------------------------------------------------------------
1517	DO jk = 1, jpk
1518	avt (:,:,jk) = avtb(jk) * tmask(:,:,jk)
1519	avmu(:,:,jk) = avmb(jk) * umask(:,:,jk)
1520	avmv(:,:,jk) = avmb(jk) * vmask(:,:,jk)
1521	END DO
1522
1523	! zero the surface flux for non local term and kpp mixed layer depth
1524	! ------------------------------------------------------------------
1525	ghats(:,:,:) = 0.
1526	wt0 (:,: ) = 0.
1527	ws0 (:,: ) = 0.
1528	hkpp (:,: ) = 0. ! just a diagnostic (not essential)
1529
1530	#if ! defined key_kppcustom
1531	! compute arrays (del, wz) for reference mean values
1532	! (increase speed for vectorization key_kppcustom not defined)
1533	del(1:jpk, 1:jpk) = 0.
1534	DO jk = 1, jpk
1535	zref = epsilon * fsdept(1,1,jk)
1536	DO jm = 1 , jpk
1537	zdist = zref - fsdepw(1,1,jm)
1538	IF( zdist > 0. ) THEN
1539	del(jk,jm) = MIN( zdist, fse3t(1,1,jm) ) / zref
1540	ELSE
1541	del(jk,jm) = 0.
1542	ENDIF
1543	ENDDO
1544	ENDDO
1545	#endif
1546
1547	#if defined key_kpplktb
1548	! build lookup table for turbulent velocity scales
1549	dezehat = ( dehatmax - dehatmin ) / nilktbm1
1550	deustar = ( ustmax - ustmin ) / njlktbm1
1551
1552	DO jj = 1, njlktb
1553	zustar = ( jj - 1) * deustar + ustmin
1554	zustvk = vonk * zustar
1555	zucube = zustar * zustar * zustar
1556	DO ji = 1 , nilktb
1557	zehat = ( ji - 1 ) * dezehat + dehatmin
1558	zeta = zehat / ( zucube + epsln )
1559	IF( zehat >= 0 ) THEN ! Stable case
1560	wmlktb(ji,jj) = zustvk / ABS( 1.0 + rconc1 * zeta + epsln )
1561	wslktb(ji,jj) = wmlktb(ji,jj)
1562	ELSE ! Unstable case
1563	IF( zeta > rzetam ) THEN
1564	wmlktb(ji,jj) = zustvk * ABS( 1.0 - rconc2 * zeta )**pfourth
1565	ELSE
1566	wmlktb(ji,jj) = zustvk * ABS( rconam - rconcm * zeta )**pthird
1567	ENDIF
1568
1569	IF( zeta > rzetas ) THEN
1570	wslktb(ji,jj) = zustvk * SQRT( ABS( 1.0 - rconc2 * zeta ) )
1571	ELSE
1572	wslktb(ji,jj) = zustvk * ABS( rconas - rconcs * zeta )**pthird
1573	ENDIF
1574	ENDIF
1575	END DO
1576	END DO
1577	#endif
1578	END SUBROUTINE zdf_kpp_init
1579
1580	#else
1581	!!----------------------------------------------------------------------
1582	!! Dummy module : NO KPP scheme
1583	!!----------------------------------------------------------------------
1584	LOGICAL, PUBLIC, PARAMETER :: lk_zdfkpp = .FALSE. !: KPP flag
1585	CONTAINS
1586	SUBROUTINE zdf_kpp( kt ) ! Empty routine
1587	WRITE(,) 'zdf_kpp: You should not have seen this print! error?', kt
1588	END SUBROUTINE zdf_kpp
1589	SUBROUTINE tra_kpp( kt ) ! Empty routine
1590	WRITE(,) 'tra_kpp: You should not have seen this print! error?', kt
1591	END SUBROUTINE tra_kpp
1592	#endif
1593
1594	!!======================================================================
1595	END MODULE zdfkpp

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