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ldftra.F90 in NEMO/trunk/src/OCE/LDF – NEMO

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source: NEMO/trunk/src/OCE/LDF/ldftra.F90 @ 12278

Last change on this file since 12278 was 12278, checked in by cetlod, 4 years ago
trunk : minor correction in use of diaptr
Property svn:keywords set to `Id`
File size: 53.2 KB

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1	MODULE ldftra
2	!!======================================================================
3	!! * MODULE ldftra *
4	!! Ocean physics: lateral diffusivity coefficients
5	!!=====================================================================
6	!! History : ! 1997-07 (G. Madec) from inimix.F split in 2 routines
7	!! NEMO 1.0 ! 2002-09 (G. Madec) F90: Free form and module
8	!! 2.0 ! 2005-11 (G. Madec)
9	!! 3.7 ! 2013-12 (F. Lemarie, G. Madec) restructuration/simplification of aht/aeiv specification,
10	!! ! add velocity dependent coefficient and optional read in file
11	!!----------------------------------------------------------------------
12
13	!!----------------------------------------------------------------------
14	!! ldf_tra_init : initialization, namelist read, and parameters control
15	!! ldf_tra : update lateral eddy diffusivity coefficients at each time step
16	!! ldf_eiv_init : initialization of the eiv coeff. from namelist choices
17	!! ldf_eiv : time evolution of the eiv coefficients (function of the growth rate of baroclinic instability)
18	!! ldf_eiv_trp : add to the input ocean transport the contribution of the EIV parametrization
19	!! ldf_eiv_dia : diagnose the eddy induced velocity from the eiv streamfunction
20	!!----------------------------------------------------------------------
21	USE oce ! ocean dynamics and tracers
22	USE dom_oce ! ocean space and time domain
23	USE phycst ! physical constants
24	USE ldfslp ! lateral diffusion: slope of iso-neutral surfaces
25	USE ldfc1d_c2d ! lateral diffusion: 1D & 2D cases
26	USE diaptr
27	!
28	USE in_out_manager ! I/O manager
29	USE iom ! I/O module for ehanced bottom friction file
30	USE lib_mpp ! distribued memory computing library
31	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
32
33	IMPLICIT NONE
34	PRIVATE
35
36	PUBLIC ldf_tra_init ! called by nemogcm.F90
37	PUBLIC ldf_tra ! called by step.F90
38	PUBLIC ldf_eiv_init ! called by nemogcm.F90
39	PUBLIC ldf_eiv ! called by step.F90
40	PUBLIC ldf_eiv_trp ! called by traadv.F90
41	PUBLIC ldf_eiv_dia ! called by traldf_iso and traldf_iso_triad.F90
42
43	! !!* Namelist namtra_ldf : lateral mixing on tracers *
44	! != Operator type =!
45	LOGICAL , PUBLIC :: ln_traldf_OFF !: no operator: No explicit diffusion
46	LOGICAL , PUBLIC :: ln_traldf_lap !: laplacian operator
47	LOGICAL , PUBLIC :: ln_traldf_blp !: bilaplacian operator
48	! != Direction of action =!
49	LOGICAL , PUBLIC :: ln_traldf_lev !: iso-level direction
50	LOGICAL , PUBLIC :: ln_traldf_hor !: horizontal (geopotential) direction
51	! LOGICAL , PUBLIC :: ln_traldf_iso !: iso-neutral direction (see ldfslp)
52	! != iso-neutral options =!
53	! LOGICAL , PUBLIC :: ln_traldf_triad !: griffies triad scheme (see ldfslp)
54	LOGICAL , PUBLIC :: ln_traldf_msc !: Method of Stabilizing Correction
55	! LOGICAL , PUBLIC :: ln_triad_iso !: pure horizontal mixing in ML (see ldfslp)
56	! LOGICAL , PUBLIC :: ln_botmix_triad !: mixing on bottom (see ldfslp)
57	! REAL(wp), PUBLIC :: rn_sw_triad !: =1/0 switching triad / all 4 triads used (see ldfslp)
58	! REAL(wp), PUBLIC :: rn_slpmax !: slope limit (see ldfslp)
59	! != Coefficients =!
60	INTEGER , PUBLIC :: nn_aht_ijk_t !: choice of time & space variations of the lateral eddy diffusivity coef.
61	! ! time invariant coefficients: aht_0 = 1/2 Ud*Ld (lap case)
62	! ! bht_0 = 1/12 Ud*Ld^3 (blp case)
63	REAL(wp), PUBLIC :: rn_Ud !: lateral diffusive velocity [m/s]
64	REAL(wp), PUBLIC :: rn_Ld !: lateral diffusive length [m]
65
66	! !!* Namelist namtra_eiv : eddy induced velocity param. *
67	! != Use/diagnose eiv =!
68	LOGICAL , PUBLIC :: ln_ldfeiv !: eddy induced velocity flag
69	LOGICAL , PUBLIC :: ln_ldfeiv_dia !: diagnose & output eiv streamfunction and velocity (IOM)
70	! != Coefficients =!
71	INTEGER , PUBLIC :: nn_aei_ijk_t !: choice of time/space variation of the eiv coeff.
72	REAL(wp), PUBLIC :: rn_Ue !: lateral diffusive velocity [m/s]
73	REAL(wp), PUBLIC :: rn_Le !: lateral diffusive length [m]
74
75	! ! Flag to control the type of lateral diffusive operator
76	INTEGER, PARAMETER, PUBLIC :: np_ERROR =-10 ! error in specification of lateral diffusion
77	INTEGER, PARAMETER, PUBLIC :: np_no_ldf = 00 ! without operator (i.e. no lateral diffusive trend)
78	! !! laplacian ! bilaplacian !
79	INTEGER, PARAMETER, PUBLIC :: np_lap = 10 , np_blp = 20 ! iso-level operator
80	INTEGER, PARAMETER, PUBLIC :: np_lap_i = 11 , np_blp_i = 21 ! standard iso-neutral or geopotential operator
81	INTEGER, PARAMETER, PUBLIC :: np_lap_it = 12 , np_blp_it = 22 ! triad iso-neutral or geopotential operator
82
83	INTEGER , PUBLIC :: nldf_tra = 0 !: type of lateral diffusion used defined from ln_traldf_... (namlist logicals)
84	LOGICAL , PUBLIC :: l_ldftra_time = .FALSE. !: flag for time variation of the lateral eddy diffusivity coef.
85	LOGICAL , PUBLIC :: l_ldfeiv_time = .FALSE. !: flag for time variation of the eiv coef.
86
87	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: ahtu, ahtv !: eddy diffusivity coef. at U- and V-points [m2/s]
88	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: aeiu, aeiv !: eddy induced velocity coeff. [m2/s]
89
90	REAL(wp) :: aht0, aei0 ! constant eddy coefficients (deduced from namelist values) [m2/s]
91	REAL(wp) :: r1_2 = 0.5_wp ! =1/2
92	REAL(wp) :: r1_4 = 0.25_wp ! =1/4
93	REAL(wp) :: r1_12 = 1._wp / 12._wp ! =1/12
94
95	!! * Substitutions
96	# include "vectopt_loop_substitute.h90"
97	!!----------------------------------------------------------------------
98	!! NEMO/OCE 4.0 , NEMO Consortium (2018)
99	!! $Id$
100	!! Software governed by the CeCILL license (see ./LICENSE)
101	!!----------------------------------------------------------------------
102	CONTAINS
103
104	SUBROUTINE ldf_tra_init
105	!!----------------------------------------------------------------------
106	!! * ROUTINE ldf_tra_init *
107	!!
108	!! ** Purpose : initializations of the tracer lateral mixing coeff.
109	!!
110	!! ** Method : * the eddy diffusivity coef. specification depends on:
111	!!
112	!! ln_traldf_lap = T laplacian operator
113	!! ln_traldf_blp = T bilaplacian operator
114	!!
115	!! nn_aht_ijk_t = 0 => = constant
116	!! !
117	!! = 10 => = F(z) : constant with a reduction of 1/4 with depth
118	!! !
119	!! =-20 => = F(i,j) = shape read in 'eddy_diffusivity.nc' file
120	!! = 20 = F(i,j) = F(e1,e2) or F(e1^3,e2^3) (lap or bilap case)
121	!! = 21 = F(i,j,t) = F(growth rate of baroclinic instability)
122	!! !
123	!! =-30 => = F(i,j,k) = shape read in 'eddy_diffusivity.nc' file
124	!! = 30 = F(i,j,k) = 2D (case 20) + decrease with depth (case 10)
125	!! = 31 = F(i,j,k,t) = F(local velocity) ( 1/2 \|u\|e laplacian operator
126	!! or 1/12 \|u\|e^3 bilaplacian operator )
127	!! * initialisation of the eddy induced velocity coefficient by a call to ldf_eiv_init
128	!!
129	!! ** action : ahtu, ahtv initialized one for all or l_ldftra_time set to true
130	!! aeiu, aeiv initialized one for all or l_ldfeiv_time set to true
131	!!----------------------------------------------------------------------
132	INTEGER :: jk ! dummy loop indices
133	INTEGER :: ioptio, ierr, inum, ios, inn ! local integer
134	REAL(wp) :: zah_max, zUfac ! - -
135	CHARACTER(len=5) :: cl_Units ! units (m2/s or m4/s)
136	!!
137	NAMELIST/namtra_ldf/ ln_traldf_OFF, ln_traldf_lap , ln_traldf_blp , & ! type of operator
138	& ln_traldf_lev, ln_traldf_hor , ln_traldf_triad, & ! acting direction of the operator
139	& ln_traldf_iso, ln_traldf_msc , rn_slpmax , & ! option for iso-neutral operator
140	& ln_triad_iso , ln_botmix_triad, rn_sw_triad , & ! option for triad operator
141	& nn_aht_ijk_t , rn_Ud , rn_Ld ! lateral eddy coefficient
142	!!----------------------------------------------------------------------
143	!
144	IF(lwp) THEN ! control print
145	WRITE(numout,*)
146	WRITE(numout,*) 'ldf_tra_init : lateral tracer diffusion'
147	WRITE(numout,*) '~~~~~~~~~~~~ '
148	ENDIF
149
150	!
151	! Choice of lateral tracer physics
152	! =================================
153	!
154	REWIND( numnam_ref )
155	READ ( numnam_ref, namtra_ldf, IOSTAT = ios, ERR = 901)
156	901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namtra_ldf in reference namelist' )
157
158	REWIND( numnam_cfg )
159	READ ( numnam_cfg, namtra_ldf, IOSTAT = ios, ERR = 902 )
160	902 IF( ios > 0 ) CALL ctl_nam ( ios , 'namtra_ldf in configuration namelist' )
161	IF(lwm) WRITE( numond, namtra_ldf )
162	!
163	IF(lwp) THEN ! control print
164	WRITE(numout,*) ' Namelist : namtra_ldf --- lateral mixing parameters (type, direction, coefficients)'
165	WRITE(numout,*) ' type :'
166	WRITE(numout,*) ' no explicit diffusion ln_traldf_OFF = ', ln_traldf_OFF
167	WRITE(numout,*) ' laplacian operator ln_traldf_lap = ', ln_traldf_lap
168	WRITE(numout,*) ' bilaplacian operator ln_traldf_blp = ', ln_traldf_blp
169	WRITE(numout,*) ' direction of action :'
170	WRITE(numout,*) ' iso-level ln_traldf_lev = ', ln_traldf_lev
171	WRITE(numout,*) ' horizontal (geopotential) ln_traldf_hor = ', ln_traldf_hor
172	WRITE(numout,*) ' iso-neutral Madec operator ln_traldf_iso = ', ln_traldf_iso
173	WRITE(numout,*) ' iso-neutral triad operator ln_traldf_triad = ', ln_traldf_triad
174	WRITE(numout,*) ' use the Method of Stab. Correction ln_traldf_msc = ', ln_traldf_msc
175	WRITE(numout,*) ' maximum isoppycnal slope rn_slpmax = ', rn_slpmax
176	WRITE(numout,*) ' pure lateral mixing in ML ln_triad_iso = ', ln_triad_iso
177	WRITE(numout,*) ' switching triad or not rn_sw_triad = ', rn_sw_triad
178	WRITE(numout,*) ' lateral mixing on bottom ln_botmix_triad = ', ln_botmix_triad
179	WRITE(numout,*) ' coefficients :'
180	WRITE(numout,*) ' type of time-space variation nn_aht_ijk_t = ', nn_aht_ijk_t
181	WRITE(numout,*) ' lateral diffusive velocity (if cst) rn_Ud = ', rn_Ud, ' m/s'
182	WRITE(numout,*) ' lateral diffusive length (if cst) rn_Ld = ', rn_Ld, ' m'
183	ENDIF
184	!
185	!
186	! Operator and its acting direction (set nldf_tra)
187	! =================================
188	!
189	nldf_tra = np_ERROR
190	ioptio = 0
191	IF( ln_traldf_OFF ) THEN ; nldf_tra = np_no_ldf ; ioptio = ioptio + 1 ; ENDIF
192	IF( ln_traldf_lap ) THEN ; ioptio = ioptio + 1 ; ENDIF
193	IF( ln_traldf_blp ) THEN ; ioptio = ioptio + 1 ; ENDIF
194	IF( ioptio /= 1 ) CALL ctl_stop( 'tra_ldf_init: use ONE of the 3 operator options (NONE/lap/blp)' )
195	!
196	IF( .NOT.ln_traldf_OFF ) THEN !== direction ==>> type of operator ==!
197	ioptio = 0
198	IF( ln_traldf_lev ) ioptio = ioptio + 1
199	IF( ln_traldf_hor ) ioptio = ioptio + 1
200	IF( ln_traldf_iso ) ioptio = ioptio + 1
201	IF( ln_traldf_triad ) ioptio = ioptio + 1
202	IF( ioptio /= 1 ) CALL ctl_stop( 'tra_ldf_init: use ONE direction (level/hor/iso/triad)' )
203	!
204	! ! defined the type of lateral diffusion from ln_traldf_... logicals
205	ierr = 0
206	IF ( ln_traldf_lap ) THEN ! laplacian operator
207	IF ( ln_zco ) THEN ! z-coordinate
208	IF ( ln_traldf_lev ) nldf_tra = np_lap ! iso-level = horizontal (no rotation)
209	IF ( ln_traldf_hor ) nldf_tra = np_lap ! iso-level = horizontal (no rotation)
210	IF ( ln_traldf_iso ) nldf_tra = np_lap_i ! iso-neutral: standard ( rotation)
211	IF ( ln_traldf_triad ) nldf_tra = np_lap_it ! iso-neutral: triad ( rotation)
212	ENDIF
213	IF ( ln_zps ) THEN ! z-coordinate with partial step
214	IF ( ln_traldf_lev ) ierr = 1 ! iso-level not allowed
215	IF ( ln_traldf_hor ) nldf_tra = np_lap ! horizontal (no rotation)
216	IF ( ln_traldf_iso ) nldf_tra = np_lap_i ! iso-neutral: standard (rotation)
217	IF ( ln_traldf_triad ) nldf_tra = np_lap_it ! iso-neutral: triad (rotation)
218	ENDIF
219	IF ( ln_sco ) THEN ! s-coordinate
220	IF ( ln_traldf_lev ) nldf_tra = np_lap ! iso-level (no rotation)
221	IF ( ln_traldf_hor ) nldf_tra = np_lap_i ! horizontal ( rotation)
222	IF ( ln_traldf_iso ) nldf_tra = np_lap_i ! iso-neutral: standard ( rotation)
223	IF ( ln_traldf_triad ) nldf_tra = np_lap_it ! iso-neutral: triad ( rotation)
224	ENDIF
225	ENDIF
226	!
227	IF( ln_traldf_blp ) THEN ! bilaplacian operator
228	IF ( ln_zco ) THEN ! z-coordinate
229	IF ( ln_traldf_lev ) nldf_tra = np_blp ! iso-level = horizontal (no rotation)
230	IF ( ln_traldf_hor ) nldf_tra = np_blp ! iso-level = horizontal (no rotation)
231	IF ( ln_traldf_iso ) nldf_tra = np_blp_i ! iso-neutral: standard ( rotation)
232	IF ( ln_traldf_triad ) nldf_tra = np_blp_it ! iso-neutral: triad ( rotation)
233	ENDIF
234	IF ( ln_zps ) THEN ! z-coordinate with partial step
235	IF ( ln_traldf_lev ) ierr = 1 ! iso-level not allowed
236	IF ( ln_traldf_hor ) nldf_tra = np_blp ! horizontal (no rotation)
237	IF ( ln_traldf_iso ) nldf_tra = np_blp_i ! iso-neutral: standard ( rotation)
238	IF ( ln_traldf_triad ) nldf_tra = np_blp_it ! iso-neutral: triad ( rotation)
239	ENDIF
240	IF ( ln_sco ) THEN ! s-coordinate
241	IF ( ln_traldf_lev ) nldf_tra = np_blp ! iso-level (no rotation)
242	IF ( ln_traldf_hor ) nldf_tra = np_blp_it ! horizontal ( rotation)
243	IF ( ln_traldf_iso ) nldf_tra = np_blp_i ! iso-neutral: standard ( rotation)
244	IF ( ln_traldf_triad ) nldf_tra = np_blp_it ! iso-neutral: triad ( rotation)
245	ENDIF
246	ENDIF
247	IF ( ierr == 1 ) CALL ctl_stop( 'iso-level in z-partial step, not allowed' )
248	ENDIF
249	!
250	IF( ln_ldfeiv .AND. .NOT.( ln_traldf_iso .OR. ln_traldf_triad ) ) &
251	& CALL ctl_stop( 'ln_ldfeiv=T requires iso-neutral laplacian diffusion' )
252	IF( ln_isfcav .AND. ln_traldf_triad ) &
253	& CALL ctl_stop( ' ice shelf cavity and traldf_triad not tested' )
254	!
255	IF( nldf_tra == np_lap_i .OR. nldf_tra == np_lap_it .OR. &
256	& nldf_tra == np_blp_i .OR. nldf_tra == np_blp_it ) l_ldfslp = .TRUE. ! slope of neutral surfaces required
257	!
258	IF( ln_traldf_blp .AND. ( ln_traldf_iso .OR. ln_traldf_triad) ) THEN ! iso-neutral bilaplacian need MSC
259	IF( .NOT.ln_traldf_msc ) CALL ctl_stop( 'tra_ldf_init: iso-neutral bilaplacian requires ln_traldf_msc=.true.' )
260	ENDIF
261	!
262	IF(lwp) THEN
263	WRITE(numout,*)
264	SELECT CASE( nldf_tra )
265	CASE( np_no_ldf ) ; WRITE(numout,*) ' ==>>> NO lateral diffusion'
266	CASE( np_lap ) ; WRITE(numout,*) ' ==>>> laplacian iso-level operator'
267	CASE( np_lap_i ) ; WRITE(numout,*) ' ==>>> Rotated laplacian operator (standard)'
268	CASE( np_lap_it ) ; WRITE(numout,*) ' ==>>> Rotated laplacian operator (triad)'
269	CASE( np_blp ) ; WRITE(numout,*) ' ==>>> bilaplacian iso-level operator'
270	CASE( np_blp_i ) ; WRITE(numout,*) ' ==>>> Rotated bilaplacian operator (standard)'
271	CASE( np_blp_it ) ; WRITE(numout,*) ' ==>>> Rotated bilaplacian operator (triad)'
272	END SELECT
273	WRITE(numout,*)
274	ENDIF
275
276	!
277	! Space/time variation of eddy coefficients
278	! ===========================================
279	!
280	l_ldftra_time = .FALSE. ! no time variation except in case defined below
281	!
282	IF( ln_traldf_OFF ) THEN !== no explicit diffusive operator ==!
283	!
284	IF(lwp) WRITE(numout,*) ' ==>>> No diffusive operator selected. ahtu and ahtv are not allocated'
285	RETURN
286	!
287	ELSE !== a lateral diffusion operator is used ==!
288	!
289	! ! allocate the aht arrays
290	ALLOCATE( ahtu(jpi,jpj,jpk) , ahtv(jpi,jpj,jpk) , STAT=ierr )
291	IF( ierr /= 0 ) CALL ctl_stop( 'STOP', 'ldf_tra_init: failed to allocate arrays')
292	!
293	ahtu(:,:,jpk) = 0._wp ! last level always 0
294	ahtv(:,:,jpk) = 0._wp
295	!.
296	! ! value of lap/blp eddy mixing coef.
297	IF( ln_traldf_lap ) THEN ; zUfac = r1_2 *rn_Ud ; inn = 1 ; cl_Units = ' m2/s' ! laplacian
298	ELSEIF( ln_traldf_blp ) THEN ; zUfac = r1_12*rn_Ud ; inn = 3 ; cl_Units = ' m4/s' ! bilaplacian
299	ENDIF
300	aht0 = zUfac * rn_Ld**inn ! mixing coefficient
301	zah_max = zUfac * (rarad)*inn ! maximum reachable coefficient (value at the Equator for e1=1 degree)
302	!
303	!
304	SELECT CASE( nn_aht_ijk_t ) !* Specification of space-time variations of ahtu, ahtv
305	!
306	CASE( 0 ) !== constant ==!
307	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = constant = ', aht0, cl_Units
308	ahtu(:,:,1:jpkm1) = aht0
309	ahtv(:,:,1:jpkm1) = aht0
310	!
311	CASE( 10 ) !== fixed profile ==!
312	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = F( depth )'
313	IF(lwp) WRITE(numout,*) ' surface eddy diffusivity = constant = ', aht0, cl_Units
314	ahtu(:,:,1) = aht0 ! constant surface value
315	ahtv(:,:,1) = aht0
316	CALL ldf_c1d( 'TRA', ahtu(:,:,1), ahtv(:,:,1), ahtu, ahtv )
317	!
318	CASE ( -20 ) !== fixed horizontal shape and magnitude read in file ==!
319	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = F(i,j) read in eddy_diffusivity.nc file'
320	CALL iom_open( 'eddy_diffusivity_2D.nc', inum )
321	CALL iom_get ( inum, jpdom_data, 'ahtu_2D', ahtu(:,:,1) )
322	CALL iom_get ( inum, jpdom_data, 'ahtv_2D', ahtv(:,:,1) )
323	CALL iom_close( inum )
324	DO jk = 2, jpkm1
325	ahtu(:,:,jk) = ahtu(:,:,1)
326	ahtv(:,:,jk) = ahtv(:,:,1)
327	END DO
328	!
329	CASE( 20 ) !== fixed horizontal shape ==!
330	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = F( e1, e2 ) or F( e1^3, e2^3 ) (lap or blp case)'
331	IF(lwp) WRITE(numout,*) ' using a fixed diffusive velocity = ', rn_Ud,' m/s and Ld = Max(e1,e2)'
332	IF(lwp) WRITE(numout,*) ' maximum reachable coefficient (at the Equator) = ', zah_max, cl_Units, ' for e1=1°)'
333	CALL ldf_c2d( 'TRA', zUfac , inn , ahtu, ahtv ) ! value proportional to scale factor^inn
334	!
335	CASE( 21 ) !== time varying 2D field ==!
336	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = F( latitude, longitude, time )'
337	IF(lwp) WRITE(numout,*) ' = F( growth rate of baroclinic instability )'
338	IF(lwp) WRITE(numout,) ' min value = 0.2 aht0 (with aht0= 1/2 rn_Ud*rn_Ld)'
339	IF(lwp) WRITE(numout,) ' max value = aei0 (with aei0=1/2 rn_UeLe increased to aht0 within 20N-20S'
340	!
341	l_ldftra_time = .TRUE. ! will be calculated by call to ldf_tra routine in step.F90
342	!
343	IF( ln_traldf_blp ) CALL ctl_stop( 'ldf_tra_init: aht=F( growth rate of baroc. insta .)', &
344	& ' incompatible with bilaplacian operator' )
345	!
346	CASE( -30 ) !== fixed 3D shape read in file ==!
347	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = F(i,j,k) read in eddy_diffusivity.nc file'
348	CALL iom_open( 'eddy_diffusivity_3D.nc', inum )
349	CALL iom_get ( inum, jpdom_data, 'ahtu_3D', ahtu )
350	CALL iom_get ( inum, jpdom_data, 'ahtv_3D', ahtv )
351	CALL iom_close( inum )
352	!
353	CASE( 30 ) !== fixed 3D shape ==!
354	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = F( latitude, longitude, depth )'
355	IF(lwp) WRITE(numout,*) ' using a fixed diffusive velocity = ', rn_Ud,' m/s and Ld = Max(e1,e2)'
356	IF(lwp) WRITE(numout,*) ' maximum reachable coefficient (at the Equator) = ', zah_max, cl_Units, ' for e1=1°)'
357	CALL ldf_c2d( 'TRA', zUfac , inn , ahtu, ahtv ) ! surface value proportional to scale factor^inn
358	CALL ldf_c1d( 'TRA', ahtu(:,:,1), ahtv(:,:,1), ahtu, ahtv ) ! reduction with depth
359	!
360	CASE( 31 ) !== time varying 3D field ==!
361	IF(lwp) WRITE(numout,*) ' ==>>> eddy diffusivity = F( latitude, longitude, depth , time )'
362	IF(lwp) WRITE(numout,*) ' proportional to the velocity : 1/2 \|u\|e or 1/12 \|u\|e^3'
363	!
364	l_ldftra_time = .TRUE. ! will be calculated by call to ldf_tra routine in step.F90
365	!
366	CASE DEFAULT
367	CALL ctl_stop('ldf_tra_init: wrong choice for nn_aht_ijk_t, the type of space-time variation of aht')
368	END SELECT
369	!
370	IF( .NOT.l_ldftra_time ) THEN !* No time variation
371	IF( ln_traldf_lap ) THEN ! laplacian operator (mask only)
372	ahtu(:,:,1:jpkm1) = ahtu(:,:,1:jpkm1) * umask(:,:,1:jpkm1)
373	ahtv(:,:,1:jpkm1) = ahtv(:,:,1:jpkm1) * vmask(:,:,1:jpkm1)
374	ELSEIF( ln_traldf_blp ) THEN ! bilaplacian operator (square root + mask)
375	ahtu(:,:,1:jpkm1) = SQRT( ahtu(:,:,1:jpkm1) ) * umask(:,:,1:jpkm1)
376	ahtv(:,:,1:jpkm1) = SQRT( ahtv(:,:,1:jpkm1) ) * vmask(:,:,1:jpkm1)
377	ENDIF
378	ENDIF
379	!
380	ENDIF
381	!
382	END SUBROUTINE ldf_tra_init
383
384
385	SUBROUTINE ldf_tra( kt )
386	!!----------------------------------------------------------------------
387	!! * ROUTINE ldf_tra *
388	!!
389	!! ** Purpose : update at kt the tracer lateral mixing coeff. (aht and aeiv)
390	!!
391	!! ** Method : * time varying eddy diffusivity coefficients:
392	!!
393	!! nn_aei_ijk_t = 21 aeiu, aeiv = F(i,j, t) = F(growth rate of baroclinic instability)
394	!! with a reduction to 0 in vicinity of the Equator
395	!! nn_aht_ijk_t = 21 ahtu, ahtv = F(i,j, t) = F(growth rate of baroclinic instability)
396	!!
397	!! = 31 ahtu, ahtv = F(i,j,k,t) = F(local velocity) ( \|u\|e /12 laplacian operator
398	!! or \|u\|e^3/12 bilaplacian operator )
399	!!
400	!! * time varying EIV coefficients: call to ldf_eiv routine
401	!!
402	!! ** action : ahtu, ahtv update at each time step
403	!! aeiu, aeiv - - - - (if ln_ldfeiv=T)
404	!!----------------------------------------------------------------------
405	INTEGER, INTENT(in) :: kt ! time step
406	!
407	INTEGER :: ji, jj, jk ! dummy loop indices
408	REAL(wp) :: zaht, zahf, zaht_min, zDaht, z1_f20 ! local scalar
409	!!----------------------------------------------------------------------
410	!
411	IF( ln_ldfeiv .AND. nn_aei_ijk_t == 21 ) THEN ! eddy induced velocity coefficients
412	! ! =F(growth rate of baroclinic instability)
413	! ! max value aeiv_0 ; decreased to 0 within 20N-20S
414	CALL ldf_eiv( kt, aei0, aeiu, aeiv )
415	ENDIF
416	!
417	SELECT CASE( nn_aht_ijk_t ) ! Eddy diffusivity coefficients
418	!
419	CASE( 21 ) !== time varying 2D field ==! = F( growth rate of baroclinic instability )
420	! ! min value 0.2*aht0
421	! ! max value aht0 (aei0 if nn_aei_ijk_t=21)
422	! ! increase to aht0 within 20N-20S
423	IF( ln_ldfeiv .AND. nn_aei_ijk_t == 21 ) THEN ! use the already computed aei.
424	ahtu(:,:,1) = aeiu(:,:,1)
425	ahtv(:,:,1) = aeiv(:,:,1)
426	ELSE ! compute aht.
427	CALL ldf_eiv( kt, aht0, ahtu, ahtv )
428	ENDIF
429	!
430	z1_f20 = 1._wp / ( 2._wp * omega * SIN( rad * 20._wp ) ) ! 1 / ff(20 degrees)
431	zaht_min = 0.2_wp * aht0 ! minimum value for aht
432	zDaht = aht0 - zaht_min
433	DO jj = 1, jpj
434	DO ji = 1, jpi
435	!!gm CAUTION : here we assume lat/lon grid in 20deg N/S band (like all ORCA cfg)
436	!! ==>>> The Coriolis value is identical for t- & u_points, and for v- and f-points
437	zaht = ( 1._wp - MIN( 1._wp , ABS( ff_t(ji,jj) * z1_f20 ) ) ) * zDaht
438	zahf = ( 1._wp - MIN( 1._wp , ABS( ff_f(ji,jj) * z1_f20 ) ) ) * zDaht
439	ahtu(ji,jj,1) = ( MAX( zaht_min, ahtu(ji,jj,1) ) + zaht ) ! min value zaht_min
440	ahtv(ji,jj,1) = ( MAX( zaht_min, ahtv(ji,jj,1) ) + zahf ) ! increase within 20S-20N
441	END DO
442	END DO
443	DO jk = 1, jpkm1 ! deeper value = surface value + mask for all levels
444	ahtu(:,:,jk) = ahtu(:,:,1) * umask(:,:,jk)
445	ahtv(:,:,jk) = ahtv(:,:,1) * vmask(:,:,jk)
446	END DO
447	!
448	CASE( 31 ) !== time varying 3D field ==! = F( local velocity )
449	IF( ln_traldf_lap ) THEN ! laplacian operator \|u\| e /12
450	DO jk = 1, jpkm1
451	ahtu(:,:,jk) = ABS( ub(:,:,jk) ) * e1u(:,:) * r1_12 ! n.b. ub,vb are masked
452	ahtv(:,:,jk) = ABS( vb(:,:,jk) ) * e2v(:,:) * r1_12
453	END DO
454	ELSEIF( ln_traldf_blp ) THEN ! bilaplacian operator sqrt( \|u\| e^3 /12 ) = sqrt( \|u\| e /12 ) * e
455	DO jk = 1, jpkm1
456	ahtu(:,:,jk) = SQRT( ABS( ub(:,:,jk) ) * e1u(:,:) * r1_12 ) * e1u(:,:)
457	ahtv(:,:,jk) = SQRT( ABS( vb(:,:,jk) ) * e2v(:,:) * r1_12 ) * e2v(:,:)
458	END DO
459	ENDIF
460	!
461	END SELECT
462	!
463	CALL iom_put( "ahtu_2d", ahtu(:,:,1) ) ! surface u-eddy diffusivity coeff.
464	CALL iom_put( "ahtv_2d", ahtv(:,:,1) ) ! surface v-eddy diffusivity coeff.
465	CALL iom_put( "ahtu_3d", ahtu(:,:,:) ) ! 3D u-eddy diffusivity coeff.
466	CALL iom_put( "ahtv_3d", ahtv(:,:,:) ) ! 3D v-eddy diffusivity coeff.
467	!
468	IF( ln_ldfeiv ) THEN
469	CALL iom_put( "aeiu_2d", aeiu(:,:,1) ) ! surface u-EIV coeff.
470	CALL iom_put( "aeiv_2d", aeiv(:,:,1) ) ! surface v-EIV coeff.
471	CALL iom_put( "aeiu_3d", aeiu(:,:,:) ) ! 3D u-EIV coeff.
472	CALL iom_put( "aeiv_3d", aeiv(:,:,:) ) ! 3D v-EIV coeff.
473	ENDIF
474	!
475	END SUBROUTINE ldf_tra
476
477
478	SUBROUTINE ldf_eiv_init
479	!!----------------------------------------------------------------------
480	!! * ROUTINE ldf_eiv_init *
481	!!
482	!! ** Purpose : initialization of the eiv coeff. from namelist choices.
483	!!
484	!! ** Method : the eiv diffusivity coef. specification depends on:
485	!! nn_aei_ijk_t = 0 => = constant
486	!! !
487	!! = 10 => = F(z) : constant with a reduction of 1/4 with depth
488	!! !
489	!! =-20 => = F(i,j) = shape read in 'eddy_diffusivity.nc' file
490	!! = 20 = F(i,j) = F(e1,e2) or F(e1^3,e2^3) (lap or bilap case)
491	!! = 21 = F(i,j,t) = F(growth rate of baroclinic instability)
492	!! !
493	!! =-30 => = F(i,j,k) = shape read in 'eddy_diffusivity.nc' file
494	!! = 30 = F(i,j,k) = 2D (case 20) + decrease with depth (case 10)
495	!!
496	!! ** Action : aeiu , aeiv : initialized one for all or l_ldftra_time set to true
497	!! l_ldfeiv_time : =T if EIV coefficients vary with time
498	!!----------------------------------------------------------------------
499	INTEGER :: jk ! dummy loop indices
500	INTEGER :: ierr, inum, ios, inn ! local integer
501	REAL(wp) :: zah_max, zUfac ! - scalar
502	!!
503	NAMELIST/namtra_eiv/ ln_ldfeiv , ln_ldfeiv_dia, & ! eddy induced velocity (eiv)
504	& nn_aei_ijk_t, rn_Ue, rn_Le ! eiv coefficient
505	!!----------------------------------------------------------------------
506	!
507	IF(lwp) THEN ! control print
508	WRITE(numout,*)
509	WRITE(numout,*) 'ldf_eiv_init : eddy induced velocity parametrization'
510	WRITE(numout,*) '~~~~~~~~~~~~ '
511	ENDIF
512	!
513	REWIND( numnam_ref )
514	READ ( numnam_ref, namtra_eiv, IOSTAT = ios, ERR = 901)
515	901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namtra_eiv in reference namelist' )
516	!
517	REWIND( numnam_cfg )
518	READ ( numnam_cfg, namtra_eiv, IOSTAT = ios, ERR = 902 )
519	902 IF( ios > 0 ) CALL ctl_nam ( ios , 'namtra_eiv in configuration namelist' )
520	IF(lwm) WRITE ( numond, namtra_eiv )
521
522	IF(lwp) THEN ! control print
523	WRITE(numout,*) ' Namelist namtra_eiv : '
524	WRITE(numout,*) ' Eddy Induced Velocity (eiv) param. ln_ldfeiv = ', ln_ldfeiv
525	WRITE(numout,*) ' eiv streamfunction & velocity diag. ln_ldfeiv_dia = ', ln_ldfeiv_dia
526	WRITE(numout,*) ' coefficients :'
527	WRITE(numout,*) ' type of time-space variation nn_aei_ijk_t = ', nn_aht_ijk_t
528	WRITE(numout,*) ' lateral diffusive velocity (if cst) rn_Ue = ', rn_Ue, ' m/s'
529	WRITE(numout,*) ' lateral diffusive length (if cst) rn_Le = ', rn_Le, ' m'
530	WRITE(numout,*)
531	ENDIF
532	!
533	l_ldfeiv_time = .FALSE. ! no time variation except in case defined below
534	!
535	!
536	IF( .NOT.ln_ldfeiv ) THEN !== Parametrization not used ==!
537	!
538	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity param is NOT used'
539	ln_ldfeiv_dia = .FALSE.
540	!
541	ELSE !== use the parametrization ==!
542	!
543	IF(lwp) WRITE(numout,*) ' ==>>> use eddy induced velocity parametrization'
544	IF(lwp) WRITE(numout,*)
545	!
546	IF( ln_traldf_blp ) CALL ctl_stop( 'ldf_eiv_init: eddy induced velocity ONLY with laplacian diffusivity' )
547	!
548	! != allocate the aei arrays
549	ALLOCATE( aeiu(jpi,jpj,jpk), aeiv(jpi,jpj,jpk), STAT=ierr )
550	IF( ierr /= 0 ) CALL ctl_stop('STOP', 'ldf_eiv: failed to allocate arrays')
551	!
552	! != Specification of space-time variations of eaiu, aeiv
553	!
554	aeiu(:,:,jpk) = 0._wp ! last level always 0
555	aeiv(:,:,jpk) = 0._wp
556	! ! value of EIV coef. (laplacian operator)
557	zUfac = r1_2 *rn_Ue ! velocity factor
558	inn = 1 ! L-exponent
559	aei0 = zUfac * rn_Le**inn ! mixing coefficient
560	zah_max = zUfac * (rarad)*inn ! maximum reachable coefficient (value at the Equator)
561
562	SELECT CASE( nn_aei_ijk_t ) !* Specification of space-time variations
563	!
564	CASE( 0 ) !-- constant --!
565	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity coef. = constant = ', aei0, ' m2/s'
566	aeiu(:,:,1:jpkm1) = aei0
567	aeiv(:,:,1:jpkm1) = aei0
568	!
569	CASE( 10 ) !-- fixed profile --!
570	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity coef. = F( depth )'
571	IF(lwp) WRITE(numout,*) ' surface eddy diffusivity = constant = ', aht0, ' m2/s'
572	aeiu(:,:,1) = aei0 ! constant surface value
573	aeiv(:,:,1) = aei0
574	CALL ldf_c1d( 'TRA', aeiu(:,:,1), aeiv(:,:,1), aeiu, aeiv )
575	!
576	CASE ( -20 ) !-- fixed horizontal shape read in file --!
577	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity coef. = F(i,j) read in eddy_diffusivity_2D.nc file'
578	CALL iom_open ( 'eddy_induced_velocity_2D.nc', inum )
579	CALL iom_get ( inum, jpdom_data, 'aeiu', aeiu(:,:,1) )
580	CALL iom_get ( inum, jpdom_data, 'aeiv', aeiv(:,:,1) )
581	CALL iom_close( inum )
582	DO jk = 2, jpkm1
583	aeiu(:,:,jk) = aeiu(:,:,1)
584	aeiv(:,:,jk) = aeiv(:,:,1)
585	END DO
586	!
587	CASE( 20 ) !-- fixed horizontal shape --!
588	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity coef. = F( e1, e2 )'
589	IF(lwp) WRITE(numout,*) ' using a fixed diffusive velocity = ', rn_Ue, ' m/s and Le = Max(e1,e2)'
590	IF(lwp) WRITE(numout,*) ' maximum reachable coefficient (at the Equator) = ', zah_max, ' m2/s for e1=1°)'
591	CALL ldf_c2d( 'TRA', zUfac , inn , aeiu, aeiv ) ! value proportional to scale factor^inn
592	!
593	CASE( 21 ) !-- time varying 2D field --!
594	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity coef. = F( latitude, longitude, time )'
595	IF(lwp) WRITE(numout,*) ' = F( growth rate of baroclinic instability )'
596	IF(lwp) WRITE(numout,*) ' maximum allowed value: aei0 = ', aei0, ' m2/s'
597	!
598	l_ldfeiv_time = .TRUE. ! will be calculated by call to ldf_tra routine in step.F90
599	!
600	CASE( -30 ) !-- fixed 3D shape read in file --!
601	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity coef. = F(i,j,k) read in eddy_diffusivity_3D.nc file'
602	CALL iom_open ( 'eddy_induced_velocity_3D.nc', inum )
603	CALL iom_get ( inum, jpdom_data, 'aeiu', aeiu )
604	CALL iom_get ( inum, jpdom_data, 'aeiv', aeiv )
605	CALL iom_close( inum )
606	!
607	CASE( 30 ) !-- fixed 3D shape --!
608	IF(lwp) WRITE(numout,*) ' ==>>> eddy induced velocity coef. = F( latitude, longitude, depth )'
609	CALL ldf_c2d( 'TRA', zUfac , inn , aeiu, aeiv ) ! surface value proportional to scale factor^inn
610	CALL ldf_c1d( 'TRA', aeiu(:,:,1), aeiv(:,:,1), aeiu, aeiv ) ! reduction with depth
611	!
612	CASE DEFAULT
613	CALL ctl_stop('ldf_tra_init: wrong choice for nn_aei_ijk_t, the type of space-time variation of aei')
614	END SELECT
615	!
616	IF( .NOT.l_ldfeiv_time ) THEN !* mask if No time variation
617	DO jk = 1, jpkm1
618	aeiu(:,:,jk) = aeiu(:,:,jk) * umask(:,:,jk)
619	ahtv(:,:,jk) = ahtv(:,:,jk) * vmask(:,:,jk)
620	END DO
621	ENDIF
622	!
623	ENDIF
624	!
625	END SUBROUTINE ldf_eiv_init
626
627
628	SUBROUTINE ldf_eiv( kt, paei0, paeiu, paeiv )
629	!!----------------------------------------------------------------------
630	!! * ROUTINE ldf_eiv *
631	!!
632	!! ** Purpose : Compute the eddy induced velocity coefficient from the
633	!! growth rate of baroclinic instability.
634	!!
635	!! ** Method : coefficient function of the growth rate of baroclinic instability
636	!!
637	!! Reference : Treguier et al. JPO 1997 ; Held and Larichev JAS 1996
638	!!----------------------------------------------------------------------
639	INTEGER , INTENT(in ) :: kt ! ocean time-step index
640	REAL(wp) , INTENT(inout) :: paei0 ! max value [m2/s]
641	REAL(wp), DIMENSION(jpi,jpj,jpk), INTENT(inout) :: paeiu, paeiv ! eiv coefficient [m2/s]
642	!
643	INTEGER :: ji, jj, jk ! dummy loop indices
644	REAL(wp) :: zfw, ze3w, zn2, z1_f20, zaht, zaht_min, zzaei ! local scalars
645	REAL(wp), DIMENSION(jpi,jpj) :: zn, zah, zhw, zRo, zaeiw ! 2D workspace
646	!!----------------------------------------------------------------------
647	!
648	zn (:,:) = 0._wp ! Local initialization
649	zhw(:,:) = 5._wp
650	zah(:,:) = 0._wp
651	zRo(:,:) = 0._wp
652	! ! Compute lateral diffusive coefficient at T-point
653	IF( ln_traldf_triad ) THEN
654	DO jk = 1, jpk
655	DO jj = 2, jpjm1
656	DO ji = 2, jpim1
657	! Take the max of N^2 and zero then take the vertical sum
658	! of the square root of the resulting N^2 ( required to compute
659	! internal Rossby radius Ro = .5 * sum_jpk(N) / f
660	zn2 = MAX( rn2b(ji,jj,jk), 0._wp )
661	zn(ji,jj) = zn(ji,jj) + SQRT( zn2 ) * e3w_n(ji,jj,jk)
662	! Compute elements required for the inverse time scale of baroclinic
663	! eddies using the isopycnal slopes calculated in ldfslp.F :
664	! T^-1 = sqrt(m_jpk(N^2(r1^2+r2^2)e3w))
665	ze3w = e3w_n(ji,jj,jk) * wmask(ji,jj,jk)
666	zah(ji,jj) = zah(ji,jj) + zn2 * wslp2(ji,jj,jk) * ze3w
667	zhw(ji,jj) = zhw(ji,jj) + ze3w
668	END DO
669	END DO
670	END DO
671	ELSE
672	DO jk = 1, jpk
673	DO jj = 2, jpjm1
674	DO ji = 2, jpim1
675	! Take the max of N^2 and zero then take the vertical sum
676	! of the square root of the resulting N^2 ( required to compute
677	! internal Rossby radius Ro = .5 * sum_jpk(N) / f
678	zn2 = MAX( rn2b(ji,jj,jk), 0._wp )
679	zn(ji,jj) = zn(ji,jj) + SQRT( zn2 ) * e3w_n(ji,jj,jk)
680	! Compute elements required for the inverse time scale of baroclinic
681	! eddies using the isopycnal slopes calculated in ldfslp.F :
682	! T^-1 = sqrt(m_jpk(N^2(r1^2+r2^2)e3w))
683	ze3w = e3w_n(ji,jj,jk) * wmask(ji,jj,jk)
684	zah(ji,jj) = zah(ji,jj) + zn2 * ( wslpi(ji,jj,jk) * wslpi(ji,jj,jk) &
685	& + wslpj(ji,jj,jk) * wslpj(ji,jj,jk) ) * ze3w
686	zhw(ji,jj) = zhw(ji,jj) + ze3w
687	END DO
688	END DO
689	END DO
690	ENDIF
691
692	DO jj = 2, jpjm1
693	DO ji = fs_2, fs_jpim1 ! vector opt.
694	zfw = MAX( ABS( 2. * omega * SIN( rad * gphit(ji,jj) ) ) , 1.e-10 )
695	! Rossby radius at w-point taken betwenn 2 km and 40km
696	zRo(ji,jj) = MAX( 2.e3 , MIN( .4 * zn(ji,jj) / zfw, 40.e3 ) )
697	! Compute aeiw by multiplying Ro^2 and T^-1
698	zaeiw(ji,jj) = zRo(ji,jj) * zRo(ji,jj) * SQRT( zah(ji,jj) / zhw(ji,jj) ) * tmask(ji,jj,1)
699	END DO
700	END DO
701
702	! !== Bound on eiv coeff. ==!
703	z1_f20 = 1._wp / ( 2._wp * omega * sin( rad * 20._wp ) )
704	DO jj = 2, jpjm1
705	DO ji = fs_2, fs_jpim1 ! vector opt.
706	zzaei = MIN( 1._wp, ABS( ff_t(ji,jj) * z1_f20 ) ) * zaeiw(ji,jj) ! tropical decrease
707	zaeiw(ji,jj) = MIN( zzaei , paei0 ) ! Max value = paei0
708	END DO
709	END DO
710	CALL lbc_lnk( 'ldftra', zaeiw(:,:), 'W', 1. ) ! lateral boundary condition
711	!
712	DO jj = 2, jpjm1 !== aei at u- and v-points ==!
713	DO ji = fs_2, fs_jpim1 ! vector opt.
714	paeiu(ji,jj,1) = 0.5_wp * ( zaeiw(ji,jj) + zaeiw(ji+1,jj ) ) * umask(ji,jj,1)
715	paeiv(ji,jj,1) = 0.5_wp * ( zaeiw(ji,jj) + zaeiw(ji ,jj+1) ) * vmask(ji,jj,1)
716	END DO
717	END DO
718	CALL lbc_lnk_multi( 'ldftra', paeiu(:,:,1), 'U', 1. , paeiv(:,:,1), 'V', 1. ) ! lateral boundary condition
719
720	DO jk = 2, jpkm1 !== deeper values equal the surface one ==!
721	paeiu(:,:,jk) = paeiu(:,:,1) * umask(:,:,jk)
722	paeiv(:,:,jk) = paeiv(:,:,1) * vmask(:,:,jk)
723	END DO
724	!
725	END SUBROUTINE ldf_eiv
726
727
728	SUBROUTINE ldf_eiv_trp( kt, kit000, pun, pvn, pwn, cdtype )
729	!!----------------------------------------------------------------------
730	!! * ROUTINE ldf_eiv_trp *
731	!!
732	!! ** Purpose : add to the input ocean transport the contribution of
733	!! the eddy induced velocity parametrization.
734	!!
735	!! ** Method : The eddy induced transport is computed from a flux stream-
736	!! function which depends on the slope of iso-neutral surfaces
737	!! (see ldf_slp). For example, in the i-k plan :
738	!! psi_uw = mk(aeiu) e2u mi(wslpi) [in m3/s]
739	!! Utr_eiv = - dk[psi_uw]
740	!! Vtr_eiv = + di[psi_uw]
741	!! ln_ldfeiv_dia = T : output the associated streamfunction,
742	!! velocity and heat transport (call ldf_eiv_dia)
743	!!
744	!! ** Action : pun, pvn increased by the eiv transport
745	!!----------------------------------------------------------------------
746	INTEGER , INTENT(in ) :: kt ! ocean time-step index
747	INTEGER , INTENT(in ) :: kit000 ! first time step index
748	CHARACTER(len=3) , INTENT(in ) :: cdtype ! =TRA or TRC (tracer indicator)
749	REAL(wp), DIMENSION(jpi,jpj,jpk), INTENT(inout) :: pun ! in : 3 ocean transport components [m3/s]
750	REAL(wp), DIMENSION(jpi,jpj,jpk), INTENT(inout) :: pvn ! out: 3 ocean transport components [m3/s]
751	REAL(wp), DIMENSION(jpi,jpj,jpk), INTENT(inout) :: pwn ! increased by the eiv [m3/s]
752	!!
753	INTEGER :: ji, jj, jk ! dummy loop indices
754	REAL(wp) :: zuwk, zuwk1, zuwi, zuwi1 ! local scalars
755	REAL(wp) :: zvwk, zvwk1, zvwj, zvwj1 ! - -
756	REAL(wp), DIMENSION(jpi,jpj,jpk) :: zpsi_uw, zpsi_vw
757	!!----------------------------------------------------------------------
758	!
759	IF( kt == kit000 ) THEN
760	IF(lwp) WRITE(numout,*)
761	IF(lwp) WRITE(numout,*) 'ldf_eiv_trp : eddy induced advection on ', cdtype,' :'
762	IF(lwp) WRITE(numout,*) '~~~~~~~~~~~ add to velocity fields the eiv component'
763	ENDIF
764
765
766	zpsi_uw(:,:, 1 ) = 0._wp ; zpsi_vw(:,:, 1 ) = 0._wp
767	zpsi_uw(:,:,jpk) = 0._wp ; zpsi_vw(:,:,jpk) = 0._wp
768	!
769	DO jk = 2, jpkm1
770	DO jj = 1, jpjm1
771	DO ji = 1, fs_jpim1 ! vector opt.
772	zpsi_uw(ji,jj,jk) = - r1_4 * e2u(ji,jj) * ( wslpi(ji,jj,jk ) + wslpi(ji+1,jj,jk) ) &
773	& * ( aeiu (ji,jj,jk-1) + aeiu (ji ,jj,jk) ) * umask(ji,jj,jk)
774	zpsi_vw(ji,jj,jk) = - r1_4 * e1v(ji,jj) * ( wslpj(ji,jj,jk ) + wslpj(ji,jj+1,jk) ) &
775	& * ( aeiv (ji,jj,jk-1) + aeiv (ji,jj ,jk) ) * vmask(ji,jj,jk)
776	END DO
777	END DO
778	END DO
779	!
780	DO jk = 1, jpkm1
781	DO jj = 1, jpjm1
782	DO ji = 1, fs_jpim1 ! vector opt.
783	pun(ji,jj,jk) = pun(ji,jj,jk) - ( zpsi_uw(ji,jj,jk) - zpsi_uw(ji,jj,jk+1) )
784	pvn(ji,jj,jk) = pvn(ji,jj,jk) - ( zpsi_vw(ji,jj,jk) - zpsi_vw(ji,jj,jk+1) )
785	END DO
786	END DO
787	END DO
788	DO jk = 1, jpkm1
789	DO jj = 2, jpjm1
790	DO ji = fs_2, fs_jpim1 ! vector opt.
791	pwn(ji,jj,jk) = pwn(ji,jj,jk) + ( zpsi_uw(ji,jj,jk) - zpsi_uw(ji-1,jj ,jk) &
792	& + zpsi_vw(ji,jj,jk) - zpsi_vw(ji ,jj-1,jk) )
793	END DO
794	END DO
795	END DO
796	!
797	! ! diagnose the eddy induced velocity and associated heat transport
798	IF( ln_ldfeiv_dia .AND. cdtype == 'TRA' ) CALL ldf_eiv_dia( zpsi_uw, zpsi_vw )
799	!
800	END SUBROUTINE ldf_eiv_trp
801
802
803	SUBROUTINE ldf_eiv_dia( psi_uw, psi_vw )
804	!!----------------------------------------------------------------------
805	!! * ROUTINE ldf_eiv_dia *
806	!!
807	!! ** Purpose : diagnose the eddy induced velocity and its associated
808	!! vertically integrated heat transport.
809	!!
810	!! ** Method :
811	!!
812	!!----------------------------------------------------------------------
813	REAL(wp), DIMENSION(jpi,jpj,jpk), INTENT(inout) :: psi_uw, psi_vw ! streamfunction [m3/s]
814	!
815	INTEGER :: ji, jj, jk ! dummy loop indices
816	REAL(wp) :: zztmp ! local scalar
817	REAL(wp), DIMENSION(jpi,jpj) :: zw2d ! 2D workspace
818	REAL(wp), DIMENSION(jpi,jpj,jpk) :: zw3d ! 3D workspace
819	!!----------------------------------------------------------------------
820	!
821	!!gm I don't like this routine.... Crazy way of doing things, not optimal at all...
822	!!gm to be redesigned....
823	! !== eiv stream function: output ==!
824	CALL lbc_lnk_multi( 'ldftra', psi_uw, 'U', -1. , psi_vw, 'V', -1. )
825	!
826	!!gm CALL iom_put( "psi_eiv_uw", psi_uw ) ! output
827	!!gm CALL iom_put( "psi_eiv_vw", psi_vw )
828	!
829	! !== eiv velocities: calculate and output ==!
830	!
831	zw3d(:,:,jpk) = 0._wp ! bottom value always 0
832	!
833	DO jk = 1, jpkm1 ! e2u e3u u_eiv = -dk[psi_uw]
834	zw3d(:,:,jk) = ( psi_uw(:,:,jk+1) - psi_uw(:,:,jk) ) / ( e2u(:,:) * e3u_n(:,:,jk) )
835	END DO
836	CALL iom_put( "uoce_eiv", zw3d )
837	!
838	DO jk = 1, jpkm1 ! e1v e3v v_eiv = -dk[psi_vw]
839	zw3d(:,:,jk) = ( psi_vw(:,:,jk+1) - psi_vw(:,:,jk) ) / ( e1v(:,:) * e3v_n(:,:,jk) )
840	END DO
841	CALL iom_put( "voce_eiv", zw3d )
842	!
843	DO jk = 1, jpkm1 ! e1 e2 w_eiv = dk[psix] + dk[psix]
844	DO jj = 2, jpjm1
845	DO ji = fs_2, fs_jpim1 ! vector opt.
846	zw3d(ji,jj,jk) = ( psi_vw(ji,jj,jk) - psi_vw(ji ,jj-1,jk) &
847	& + psi_uw(ji,jj,jk) - psi_uw(ji-1,jj ,jk) ) / e1e2t(ji,jj)
848	END DO
849	END DO
850	END DO
851	CALL lbc_lnk( 'ldftra', zw3d, 'T', 1. ) ! lateral boundary condition
852	CALL iom_put( "woce_eiv", zw3d )
853	!
854	IF( iom_use('weiv_masstr') ) THEN ! vertical mass transport & its square value
855	zw2d(:,:) = rau0 * e1e2t(:,:)
856	DO jk = 1, jpk
857	zw3d(:,:,jk) = zw3d(:,:,jk) * zw2d(:,:)
858	END DO
859	CALL iom_put( "weiv_masstr" , zw3d )
860	ENDIF
861	!
862	IF( iom_use('ueiv_masstr') ) THEN
863	zw3d(:,:,:) = 0.e0
864	DO jk = 1, jpkm1
865	zw3d(:,:,jk) = rau0 * ( psi_uw(:,:,jk+1) - psi_uw(:,:,jk) )
866	END DO
867	CALL iom_put( "ueiv_masstr", zw3d ) ! mass transport in i-direction
868	ENDIF
869	!
870	zztmp = 0.5_wp * rau0 * rcp
871	IF( iom_use('ueiv_heattr') .OR. iom_use('ueiv_heattr3d') ) THEN
872	zw2d(:,:) = 0._wp
873	zw3d(:,:,:) = 0._wp
874	DO jk = 1, jpkm1
875	DO jj = 2, jpjm1
876	DO ji = fs_2, fs_jpim1 ! vector opt.
877	zw3d(ji,jj,jk) = zw3d(ji,jj,jk) + ( psi_uw(ji,jj,jk+1) - psi_uw(ji,jj,jk) ) &
878	& * ( tsn (ji,jj,jk,jp_tem) + tsn (ji+1,jj,jk,jp_tem) )
879	zw2d(ji,jj) = zw2d(ji,jj) + zw3d(ji,jj,jk)
880	END DO
881	END DO
882	END DO
883	CALL lbc_lnk( 'ldftra', zw2d, 'U', -1. )
884	CALL lbc_lnk( 'ldftra', zw3d, 'U', -1. )
885	CALL iom_put( "ueiv_heattr" , zztmp * zw2d ) ! heat transport in i-direction
886	CALL iom_put( "ueiv_heattr3d", zztmp * zw3d ) ! heat transport in i-direction
887	ENDIF
888	!
889	IF( iom_use('veiv_masstr') ) THEN
890	zw3d(:,:,:) = 0.e0
891	DO jk = 1, jpkm1
892	zw3d(:,:,jk) = rau0 * ( psi_vw(:,:,jk+1) - psi_vw(:,:,jk) )
893	END DO
894	CALL iom_put( "veiv_masstr", zw3d ) ! mass transport in i-direction
895	ENDIF
896	!
897	zw2d(:,:) = 0._wp
898	zw3d(:,:,:) = 0._wp
899	DO jk = 1, jpkm1
900	DO jj = 2, jpjm1
901	DO ji = fs_2, fs_jpim1 ! vector opt.
902	zw3d(ji,jj,jk) = zw3d(ji,jj,jk) + ( psi_vw(ji,jj,jk+1) - psi_vw(ji,jj,jk) ) &
903	& * ( tsn (ji,jj,jk,jp_tem) + tsn (ji,jj+1,jk,jp_tem) )
904	zw2d(ji,jj) = zw2d(ji,jj) + zw3d(ji,jj,jk)
905	END DO
906	END DO
907	END DO
908	CALL lbc_lnk( 'ldftra', zw2d, 'V', -1. )
909	CALL iom_put( "veiv_heattr", zztmp * zw2d ) ! heat transport in j-direction
910	CALL iom_put( "veiv_heattr", zztmp * zw3d ) ! heat transport in j-direction
911	!
912	IF( ln_diaptr ) CALL dia_ptr_hst( jp_tem, 'eiv', 0.5 * zw3d )
913	!
914	zztmp = 0.5_wp * 0.5
915	IF( iom_use('ueiv_salttr') .OR. iom_use('ueiv_salttr3d')) THEN
916	zw2d(:,:) = 0._wp
917	zw3d(:,:,:) = 0._wp
918	DO jk = 1, jpkm1
919	DO jj = 2, jpjm1
920	DO ji = fs_2, fs_jpim1 ! vector opt.
921	zw3d(ji,jj,jk) = zw3d(ji,jj,jk) * ( psi_uw(ji,jj,jk+1) - psi_uw(ji,jj,jk) ) &
922	& * ( tsn (ji,jj,jk,jp_sal) + tsn (ji+1,jj,jk,jp_sal) )
923	zw2d(ji,jj) = zw2d(ji,jj) + zw3d(ji,jj,jk)
924	END DO
925	END DO
926	END DO
927	CALL lbc_lnk( 'ldftra', zw2d, 'U', -1. )
928	CALL lbc_lnk( 'ldftra', zw3d, 'U', -1. )
929	CALL iom_put( "ueiv_salttr", zztmp * zw2d ) ! salt transport in i-direction
930	CALL iom_put( "ueiv_salttr3d", zztmp * zw3d ) ! salt transport in i-direction
931	ENDIF
932	zw2d(:,:) = 0._wp
933	zw3d(:,:,:) = 0._wp
934	DO jk = 1, jpkm1
935	DO jj = 2, jpjm1
936	DO ji = fs_2, fs_jpim1 ! vector opt.
937	zw3d(ji,jj,jk) = zw3d(ji,jj,jk) + ( psi_vw(ji,jj,jk+1) - psi_vw(ji,jj,jk) ) &
938	& * ( tsn (ji,jj,jk,jp_sal) + tsn (ji,jj+1,jk,jp_sal) )
939	zw2d(ji,jj) = zw2d(ji,jj) + zw3d(ji,jj,jk)
940	END DO
941	END DO
942	END DO
943	CALL lbc_lnk( 'ldftra', zw2d, 'V', -1. )
944	CALL iom_put( "veiv_salttr", zztmp * zw2d ) ! salt transport in j-direction
945	CALL iom_put( "veiv_salttr", zztmp * zw3d ) ! salt transport in j-direction
946	!
947	IF( ln_diaptr ) CALL dia_ptr_hst( jp_sal, 'eiv', 0.5 * zw3d )
948	!
949	!
950	END SUBROUTINE ldf_eiv_dia
951
952	!!======================================================================
953	END MODULE ldftra

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