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eosbn2.F90 in NEMO/branches/2019/dev_r11943_MERGE_2019/src/OCE/TRA – NEMO

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source: NEMO/branches/2019/dev_r11943_MERGE_2019/src/OCE/TRA/eosbn2.F90 @ 11949

Last change on this file since 11949 was 11949, checked in by acc, 4 years ago
Merge in changes from 2019/dev_r10721_KERNEL-02_Storkey_Coward_IMMERSE_first_steps. This just creates a fresh copy of this branch to use as the merge base. See ticket #2341
Property svn:keywords set to `Id`
File size: 75.8 KB

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1	MODULE eosbn2
2	!!==============================================================================
3	!! * MODULE eosbn2 *
4	!! Equation Of Seawater : in situ density - Brunt-Vaisala frequency
5	!!==============================================================================
6	!! History : OPA ! 1989-03 (O. Marti) Original code
7	!! 6.0 ! 1994-07 (G. Madec, M. Imbard) add bn2
8	!! 6.0 ! 1994-08 (G. Madec) Add Jackett & McDougall eos
9	!! 7.0 ! 1996-01 (G. Madec) statement function for e3
10	!! 8.1 ! 1997-07 (G. Madec) density instead of volumic mass
11	!! - ! 1999-02 (G. Madec, N. Grima) semi-implicit pressure gradient
12	!! 8.2 ! 2001-09 (M. Ben Jelloul) bugfix on linear eos
13	!! NEMO 1.0 ! 2002-10 (G. Madec) add eos_init
14	!! - ! 2002-11 (G. Madec, A. Bozec) partial step, eos_insitu_2d
15	!! - ! 2003-08 (G. Madec) F90, free form
16	!! 3.0 ! 2006-08 (G. Madec) add tfreez function (now eos_fzp function)
17	!! 3.3 ! 2010-05 (C. Ethe, G. Madec) merge TRC-TRA
18	!! - ! 2010-10 (G. Nurser, G. Madec) add alpha/beta used in ldfslp
19	!! 3.7 ! 2012-03 (F. Roquet, G. Madec) add primitive of alpha and beta used in PE computation
20	!! - ! 2012-05 (F. Roquet) add Vallis and original JM95 equation of state
21	!! - ! 2013-04 (F. Roquet, G. Madec) add eos_rab, change bn2 computation and reorganize the module
22	!! - ! 2014-09 (F. Roquet) add TEOS-10, S-EOS, and modify EOS-80
23	!! - ! 2015-06 (P.A. Bouttier) eos_fzp functions changed to subroutines for AGRIF
24	!!----------------------------------------------------------------------
25
26	!!----------------------------------------------------------------------
27	!! eos : generic interface of the equation of state
28	!! eos_insitu : Compute the in situ density
29	!! eos_insitu_pot: Compute the insitu and surface referenced potential volumic mass
30	!! eos_insitu_2d : Compute the in situ density for 2d fields
31	!! bn2 : Compute the Brunt-Vaisala frequency
32	!! bn2 : compute the Brunt-Vaisala frequency
33	!! eos_pt_from_ct: compute the potential temperature from the Conservative Temperature
34	!! eos_rab : generic interface of in situ thermal/haline expansion ratio
35	!! eos_rab_3d : compute in situ thermal/haline expansion ratio
36	!! eos_rab_2d : compute in situ thermal/haline expansion ratio for 2d fields
37	!! eos_fzp_2d : freezing temperature for 2d fields
38	!! eos_fzp_0d : freezing temperature for scalar
39	!! eos_init : set eos parameters (namelist)
40	!!----------------------------------------------------------------------
41	USE dom_oce ! ocean space and time domain
42	USE phycst ! physical constants
43	USE stopar ! Stochastic T/S fluctuations
44	USE stopts ! Stochastic T/S fluctuations
45	!
46	USE in_out_manager ! I/O manager
47	USE lib_mpp ! MPP library
48	USE lib_fortran ! Fortran utilities (allows no signed zero when 'key_nosignedzero' defined)
49	USE prtctl ! Print control
50	USE lbclnk ! ocean lateral boundary conditions
51	USE timing ! Timing
52
53	IMPLICIT NONE
54	PRIVATE
55
56	! !! * Interface
57	INTERFACE eos
58	MODULE PROCEDURE eos_insitu, eos_insitu_pot, eos_insitu_2d
59	END INTERFACE
60	!
61	INTERFACE eos_rab
62	MODULE PROCEDURE rab_3d, rab_2d, rab_0d
63	END INTERFACE
64	!
65	INTERFACE eos_fzp
66	MODULE PROCEDURE eos_fzp_2d, eos_fzp_0d
67	END INTERFACE
68	!
69	PUBLIC eos ! called by step, istate, tranpc and zpsgrd modules
70	PUBLIC bn2 ! called by step module
71	PUBLIC eos_rab ! called by ldfslp, zdfddm, trabbl
72	PUBLIC eos_pt_from_ct ! called by sbcssm
73	PUBLIC eos_fzp ! called by traadv_cen2 and sbcice_... modules
74	PUBLIC eos_pen ! used for pe diagnostics in trdpen module
75	PUBLIC eos_init ! called by istate module
76
77	! !! Namelist nameos
78	LOGICAL , PUBLIC :: ln_TEOS10
79	LOGICAL , PUBLIC :: ln_EOS80
80	LOGICAL , PUBLIC :: ln_SEOS
81
82	! Parameters
83	LOGICAL , PUBLIC :: l_useCT ! =T in ln_TEOS10=T (i.e. use eos_pt_from_ct to compute sst_m), =F otherwise
84	INTEGER , PUBLIC :: neos ! Identifier for equation of state used
85
86	INTEGER , PARAMETER :: np_teos10 = -1 ! parameter for using TEOS10
87	INTEGER , PARAMETER :: np_eos80 = 0 ! parameter for using EOS80
88	INTEGER , PARAMETER :: np_seos = 1 ! parameter for using Simplified Equation of state
89
90	! !!! simplified eos coefficients (default value: Vallis 2006)
91	REAL(wp) :: rn_a0 = 1.6550e-1_wp ! thermal expansion coeff.
92	REAL(wp) :: rn_b0 = 7.6554e-1_wp ! saline expansion coeff.
93	REAL(wp) :: rn_lambda1 = 5.9520e-2_wp ! cabbeling coeff. in T^2
94	REAL(wp) :: rn_lambda2 = 5.4914e-4_wp ! cabbeling coeff. in S^2
95	REAL(wp) :: rn_mu1 = 1.4970e-4_wp ! thermobaric coeff. in T
96	REAL(wp) :: rn_mu2 = 1.1090e-5_wp ! thermobaric coeff. in S
97	REAL(wp) :: rn_nu = 2.4341e-3_wp ! cabbeling coeff. in theta*salt
98
99	! TEOS10/EOS80 parameters
100	REAL(wp) :: r1_S0, r1_T0, r1_Z0, rdeltaS
101
102	! EOS parameters
103	REAL(wp) :: EOS000 , EOS100 , EOS200 , EOS300 , EOS400 , EOS500 , EOS600
104	REAL(wp) :: EOS010 , EOS110 , EOS210 , EOS310 , EOS410 , EOS510
105	REAL(wp) :: EOS020 , EOS120 , EOS220 , EOS320 , EOS420
106	REAL(wp) :: EOS030 , EOS130 , EOS230 , EOS330
107	REAL(wp) :: EOS040 , EOS140 , EOS240
108	REAL(wp) :: EOS050 , EOS150
109	REAL(wp) :: EOS060
110	REAL(wp) :: EOS001 , EOS101 , EOS201 , EOS301 , EOS401
111	REAL(wp) :: EOS011 , EOS111 , EOS211 , EOS311
112	REAL(wp) :: EOS021 , EOS121 , EOS221
113	REAL(wp) :: EOS031 , EOS131
114	REAL(wp) :: EOS041
115	REAL(wp) :: EOS002 , EOS102 , EOS202
116	REAL(wp) :: EOS012 , EOS112
117	REAL(wp) :: EOS022
118	REAL(wp) :: EOS003 , EOS103
119	REAL(wp) :: EOS013
120
121	! ALPHA parameters
122	REAL(wp) :: ALP000 , ALP100 , ALP200 , ALP300 , ALP400 , ALP500
123	REAL(wp) :: ALP010 , ALP110 , ALP210 , ALP310 , ALP410
124	REAL(wp) :: ALP020 , ALP120 , ALP220 , ALP320
125	REAL(wp) :: ALP030 , ALP130 , ALP230
126	REAL(wp) :: ALP040 , ALP140
127	REAL(wp) :: ALP050
128	REAL(wp) :: ALP001 , ALP101 , ALP201 , ALP301
129	REAL(wp) :: ALP011 , ALP111 , ALP211
130	REAL(wp) :: ALP021 , ALP121
131	REAL(wp) :: ALP031
132	REAL(wp) :: ALP002 , ALP102
133	REAL(wp) :: ALP012
134	REAL(wp) :: ALP003
135
136	! BETA parameters
137	REAL(wp) :: BET000 , BET100 , BET200 , BET300 , BET400 , BET500
138	REAL(wp) :: BET010 , BET110 , BET210 , BET310 , BET410
139	REAL(wp) :: BET020 , BET120 , BET220 , BET320
140	REAL(wp) :: BET030 , BET130 , BET230
141	REAL(wp) :: BET040 , BET140
142	REAL(wp) :: BET050
143	REAL(wp) :: BET001 , BET101 , BET201 , BET301
144	REAL(wp) :: BET011 , BET111 , BET211
145	REAL(wp) :: BET021 , BET121
146	REAL(wp) :: BET031
147	REAL(wp) :: BET002 , BET102
148	REAL(wp) :: BET012
149	REAL(wp) :: BET003
150
151	! PEN parameters
152	REAL(wp) :: PEN000 , PEN100 , PEN200 , PEN300 , PEN400
153	REAL(wp) :: PEN010 , PEN110 , PEN210 , PEN310
154	REAL(wp) :: PEN020 , PEN120 , PEN220
155	REAL(wp) :: PEN030 , PEN130
156	REAL(wp) :: PEN040
157	REAL(wp) :: PEN001 , PEN101 , PEN201
158	REAL(wp) :: PEN011 , PEN111
159	REAL(wp) :: PEN021
160	REAL(wp) :: PEN002 , PEN102
161	REAL(wp) :: PEN012
162
163	! ALPHA_PEN parameters
164	REAL(wp) :: APE000 , APE100 , APE200 , APE300
165	REAL(wp) :: APE010 , APE110 , APE210
166	REAL(wp) :: APE020 , APE120
167	REAL(wp) :: APE030
168	REAL(wp) :: APE001 , APE101
169	REAL(wp) :: APE011
170	REAL(wp) :: APE002
171
172	! BETA_PEN parameters
173	REAL(wp) :: BPE000 , BPE100 , BPE200 , BPE300
174	REAL(wp) :: BPE010 , BPE110 , BPE210
175	REAL(wp) :: BPE020 , BPE120
176	REAL(wp) :: BPE030
177	REAL(wp) :: BPE001 , BPE101
178	REAL(wp) :: BPE011
179	REAL(wp) :: BPE002
180
181	!! * Substitutions
182	# include "vectopt_loop_substitute.h90"
183	!!----------------------------------------------------------------------
184	!! NEMO/OCE 4.0 , NEMO Consortium (2018)
185	!! $Id$
186	!! Software governed by the CeCILL license (see ./LICENSE)
187	!!----------------------------------------------------------------------
188	CONTAINS
189
190	SUBROUTINE eos_insitu( pts, prd, pdep )
191	!!----------------------------------------------------------------------
192	!! * ROUTINE eos_insitu *
193	!!
194	!! ** Purpose : Compute the in situ density (ratio rho/rau0) from
195	!! potential temperature and salinity using an equation of state
196	!! selected in the nameos namelist
197	!!
198	!! ** Method : prd(t,s,z) = ( rho(t,s,z) - rau0 ) / rau0
199	!! with prd in situ density anomaly no units
200	!! t TEOS10: CT or EOS80: PT Celsius
201	!! s TEOS10: SA or EOS80: SP TEOS10: g/kg or EOS80: psu
202	!! z depth meters
203	!! rho in situ density kg/m^3
204	!! rau0 reference density kg/m^3
205	!!
206	!! ln_teos10 : polynomial TEOS-10 equation of state is used for rho(t,s,z).
207	!! Check value: rho = 1028.21993233072 kg/m^3 for z=3000 dbar, ct=3 Celsius, sa=35.5 g/kg
208	!!
209	!! ln_eos80 : polynomial EOS-80 equation of state is used for rho(t,s,z).
210	!! Check value: rho = 1028.35011066567 kg/m^3 for z=3000 dbar, pt=3 Celsius, sp=35.5 psu
211	!!
212	!! ln_seos : simplified equation of state
213	!! prd(t,s,z) = ( -a0(1+lambda/2(T-T0)+muz+nu(S-S0))(T-T0) + b0(S-S0) ) / rau0
214	!! linear case function of T only: rn_alpha<>0, other coefficients = 0
215	!! linear eos function of T and S: rn_alpha and rn_beta<>0, other coefficients=0
216	!! Vallis like equation: use default values of coefficients
217	!!
218	!! ** Action : compute prd , the in situ density (no units)
219	!!
220	!! References : Roquet et al, Ocean Modelling, in preparation (2014)
221	!! Vallis, Atmospheric and Oceanic Fluid Dynamics, 2006
222	!! TEOS-10 Manual, 2010
223	!!----------------------------------------------------------------------
224	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT(in ) :: pts ! 1 : potential temperature [Celsius]
225	! ! 2 : salinity [psu]
226	REAL(wp), DIMENSION(jpi,jpj,jpk ), INTENT( out) :: prd ! in situ density [-]
227	REAL(wp), DIMENSION(jpi,jpj,jpk ), INTENT(in ) :: pdep ! depth [m]
228	!
229	INTEGER :: ji, jj, jk ! dummy loop indices
230	REAL(wp) :: zt , zh , zs , ztm ! local scalars
231	REAL(wp) :: zn , zn0, zn1, zn2, zn3 ! - -
232	!!----------------------------------------------------------------------
233	!
234	IF( ln_timing ) CALL timing_start('eos-insitu')
235	!
236	SELECT CASE( neos )
237	!
238	CASE( np_teos10, np_eos80 ) !== polynomial TEOS-10 / EOS-80 ==!
239	!
240	DO jk = 1, jpkm1
241	DO jj = 1, jpj
242	DO ji = 1, jpi
243	!
244	zh = pdep(ji,jj,jk) * r1_Z0 ! depth
245	zt = pts (ji,jj,jk,jp_tem) * r1_T0 ! temperature
246	zs = SQRT( ABS( pts(ji,jj,jk,jp_sal) + rdeltaS ) * r1_S0 ) ! square root salinity
247	ztm = tmask(ji,jj,jk) ! tmask
248	!
249	zn3 = EOS013*zt &
250	& + EOS103*zs+EOS003
251	!
252	zn2 = (EOS022*zt &
253	& + EOS112zs+EOS012)zt &
254	& + (EOS202zs+EOS102)zs+EOS002
255	!
256	zn1 = (((EOS041*zt &
257	& + EOS131zs+EOS031)zt &
258	& + (EOS221zs+EOS121)zs+EOS021)*zt &
259	& + ((EOS311zs+EOS211)zs+EOS111)zs+EOS011)zt &
260	& + (((EOS401zs+EOS301)zs+EOS201)zs+EOS101)zs+EOS001
261	!
262	zn0 = (((((EOS060*zt &
263	& + EOS150zs+EOS050)zt &
264	& + (EOS240zs+EOS140)zs+EOS040)*zt &
265	& + ((EOS330zs+EOS230)zs+EOS130)zs+EOS030)zt &
266	& + (((EOS420zs+EOS320)zs+EOS220)zs+EOS120)zs+EOS020)*zt &
267	& + ((((EOS510zs+EOS410)zs+EOS310)zs+EOS210)zs+EOS110)zs+EOS010)zt &
268	& + (((((EOS600zs+EOS500)zs+EOS400)zs+EOS300)zs+EOS200)zs+EOS100)zs+EOS000
269	!
270	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
271	!
272	prd(ji,jj,jk) = ( zn * r1_rau0 - 1._wp ) * ztm ! density anomaly (masked)
273	!
274	END DO
275	END DO
276	END DO
277	!
278	CASE( np_seos ) !== simplified EOS ==!
279	!
280	DO jk = 1, jpkm1
281	DO jj = 1, jpj
282	DO ji = 1, jpi
283	zt = pts (ji,jj,jk,jp_tem) - 10._wp
284	zs = pts (ji,jj,jk,jp_sal) - 35._wp
285	zh = pdep (ji,jj,jk)
286	ztm = tmask(ji,jj,jk)
287	!
288	zn = - rn_a0 * ( 1._wp + 0.5_wprn_lambda1zt + rn_mu1zh ) zt &
289	& + rn_b0 * ( 1._wp - 0.5_wprn_lambda2zs - rn_mu2zh ) zs &
290	& - rn_nu * zt * zs
291	!
292	prd(ji,jj,jk) = zn * r1_rau0 * ztm ! density anomaly (masked)
293	END DO
294	END DO
295	END DO
296	!
297	END SELECT
298	!
299	IF(ln_ctl) CALL prt_ctl( tab3d_1=prd, clinfo1=' eos-insitu : ', kdim=jpk )
300	!
301	IF( ln_timing ) CALL timing_stop('eos-insitu')
302	!
303	END SUBROUTINE eos_insitu
304
305
306	SUBROUTINE eos_insitu_pot( pts, prd, prhop, pdep )
307	!!----------------------------------------------------------------------
308	!! * ROUTINE eos_insitu_pot *
309	!!
310	!! ** Purpose : Compute the in situ density (ratio rho/rau0) and the
311	!! potential volumic mass (Kg/m3) from potential temperature and
312	!! salinity fields using an equation of state selected in the
313	!! namelist.
314	!!
315	!! ** Action : - prd , the in situ density (no units)
316	!! - prhop, the potential volumic mass (Kg/m3)
317	!!
318	!!----------------------------------------------------------------------
319	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT(in ) :: pts ! 1 : potential temperature [Celsius]
320	! ! 2 : salinity [psu]
321	REAL(wp), DIMENSION(jpi,jpj,jpk ), INTENT( out) :: prd ! in situ density [-]
322	REAL(wp), DIMENSION(jpi,jpj,jpk ), INTENT( out) :: prhop ! potential density (surface referenced)
323	REAL(wp), DIMENSION(jpi,jpj,jpk ), INTENT(in ) :: pdep ! depth [m]
324	!
325	INTEGER :: ji, jj, jk, jsmp ! dummy loop indices
326	INTEGER :: jdof
327	REAL(wp) :: zt , zh , zstemp, zs , ztm ! local scalars
328	REAL(wp) :: zn , zn0, zn1, zn2, zn3 ! - -
329	REAL(wp), DIMENSION(:), ALLOCATABLE :: zn0_sto, zn_sto, zsign ! local vectors
330	!!----------------------------------------------------------------------
331	!
332	IF( ln_timing ) CALL timing_start('eos-pot')
333	!
334	SELECT CASE ( neos )
335	!
336	CASE( np_teos10, np_eos80 ) !== polynomial TEOS-10 / EOS-80 ==!
337	!
338	! Stochastic equation of state
339	IF ( ln_sto_eos ) THEN
340	ALLOCATE(zn0_sto(1:2*nn_sto_eos))
341	ALLOCATE(zn_sto(1:2*nn_sto_eos))
342	ALLOCATE(zsign(1:2*nn_sto_eos))
343	DO jsmp = 1, 2*nn_sto_eos, 2
344	zsign(jsmp) = 1._wp
345	zsign(jsmp+1) = -1._wp
346	END DO
347	!
348	DO jk = 1, jpkm1
349	DO jj = 1, jpj
350	DO ji = 1, jpi
351	!
352	! compute density (2*nn_sto_eos) times:
353	! (1) for t+dt, s+ds (with the random TS fluctutation computed in sto_pts)
354	! (2) for t-dt, s-ds (with the opposite fluctuation)
355	DO jsmp = 1, nn_sto_eos*2
356	jdof = (jsmp + 1) / 2
357	zh = pdep(ji,jj,jk) * r1_Z0 ! depth
358	zt = (pts (ji,jj,jk,jp_tem) + pts_ran(ji,jj,jk,jp_tem,jdof) * zsign(jsmp)) * r1_T0 ! temperature
359	zstemp = pts (ji,jj,jk,jp_sal) + pts_ran(ji,jj,jk,jp_sal,jdof) * zsign(jsmp)
360	zs = SQRT( ABS( zstemp + rdeltaS ) * r1_S0 ) ! square root salinity
361	ztm = tmask(ji,jj,jk) ! tmask
362	!
363	zn3 = EOS013*zt &
364	& + EOS103*zs+EOS003
365	!
366	zn2 = (EOS022*zt &
367	& + EOS112zs+EOS012)zt &
368	& + (EOS202zs+EOS102)zs+EOS002
369	!
370	zn1 = (((EOS041*zt &
371	& + EOS131zs+EOS031)zt &
372	& + (EOS221zs+EOS121)zs+EOS021)*zt &
373	& + ((EOS311zs+EOS211)zs+EOS111)zs+EOS011)zt &
374	& + (((EOS401zs+EOS301)zs+EOS201)zs+EOS101)zs+EOS001
375	!
376	zn0_sto(jsmp) = (((((EOS060*zt &
377	& + EOS150zs+EOS050)zt &
378	& + (EOS240zs+EOS140)zs+EOS040)*zt &
379	& + ((EOS330zs+EOS230)zs+EOS130)zs+EOS030)zt &
380	& + (((EOS420zs+EOS320)zs+EOS220)zs+EOS120)zs+EOS020)*zt &
381	& + ((((EOS510zs+EOS410)zs+EOS310)zs+EOS210)zs+EOS110)zs+EOS010)zt &
382	& + (((((EOS600zs+EOS500)zs+EOS400)zs+EOS300)zs+EOS200)zs+EOS100)zs+EOS000
383	!
384	zn_sto(jsmp) = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0_sto(jsmp)
385	END DO
386	!
387	! compute stochastic density as the mean of the (2*nn_sto_eos) densities
388	prhop(ji,jj,jk) = 0._wp ; prd(ji,jj,jk) = 0._wp
389	DO jsmp = 1, nn_sto_eos*2
390	prhop(ji,jj,jk) = prhop(ji,jj,jk) + zn0_sto(jsmp) ! potential density referenced at the surface
391	!
392	prd(ji,jj,jk) = prd(ji,jj,jk) + ( zn_sto(jsmp) * r1_rau0 - 1._wp ) ! density anomaly (masked)
393	END DO
394	prhop(ji,jj,jk) = 0.5_wp * prhop(ji,jj,jk) * ztm / nn_sto_eos
395	prd (ji,jj,jk) = 0.5_wp * prd (ji,jj,jk) * ztm / nn_sto_eos
396	END DO
397	END DO
398	END DO
399	DEALLOCATE(zn0_sto,zn_sto,zsign)
400	! Non-stochastic equation of state
401	ELSE
402	DO jk = 1, jpkm1
403	DO jj = 1, jpj
404	DO ji = 1, jpi
405	!
406	zh = pdep(ji,jj,jk) * r1_Z0 ! depth
407	zt = pts (ji,jj,jk,jp_tem) * r1_T0 ! temperature
408	zs = SQRT( ABS( pts(ji,jj,jk,jp_sal) + rdeltaS ) * r1_S0 ) ! square root salinity
409	ztm = tmask(ji,jj,jk) ! tmask
410	!
411	zn3 = EOS013*zt &
412	& + EOS103*zs+EOS003
413	!
414	zn2 = (EOS022*zt &
415	& + EOS112zs+EOS012)zt &
416	& + (EOS202zs+EOS102)zs+EOS002
417	!
418	zn1 = (((EOS041*zt &
419	& + EOS131zs+EOS031)zt &
420	& + (EOS221zs+EOS121)zs+EOS021)*zt &
421	& + ((EOS311zs+EOS211)zs+EOS111)zs+EOS011)zt &
422	& + (((EOS401zs+EOS301)zs+EOS201)zs+EOS101)zs+EOS001
423	!
424	zn0 = (((((EOS060*zt &
425	& + EOS150zs+EOS050)zt &
426	& + (EOS240zs+EOS140)zs+EOS040)*zt &
427	& + ((EOS330zs+EOS230)zs+EOS130)zs+EOS030)zt &
428	& + (((EOS420zs+EOS320)zs+EOS220)zs+EOS120)zs+EOS020)*zt &
429	& + ((((EOS510zs+EOS410)zs+EOS310)zs+EOS210)zs+EOS110)zs+EOS010)zt &
430	& + (((((EOS600zs+EOS500)zs+EOS400)zs+EOS300)zs+EOS200)zs+EOS100)zs+EOS000
431	!
432	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
433	!
434	prhop(ji,jj,jk) = zn0 * ztm ! potential density referenced at the surface
435	!
436	prd(ji,jj,jk) = ( zn * r1_rau0 - 1._wp ) * ztm ! density anomaly (masked)
437	END DO
438	END DO
439	END DO
440	ENDIF
441
442	CASE( np_seos ) !== simplified EOS ==!
443	!
444	DO jk = 1, jpkm1
445	DO jj = 1, jpj
446	DO ji = 1, jpi
447	zt = pts (ji,jj,jk,jp_tem) - 10._wp
448	zs = pts (ji,jj,jk,jp_sal) - 35._wp
449	zh = pdep (ji,jj,jk)
450	ztm = tmask(ji,jj,jk)
451	! ! potential density referenced at the surface
452	zn = - rn_a0 * ( 1._wp + 0.5_wprn_lambda1zt ) * zt &
453	& + rn_b0 * ( 1._wp - 0.5_wprn_lambda2zs ) * zs &
454	& - rn_nu * zt * zs
455	prhop(ji,jj,jk) = ( rau0 + zn ) * ztm
456	! ! density anomaly (masked)
457	zn = zn - ( rn_a0 * rn_mu1 * zt + rn_b0 * rn_mu2 * zs ) * zh
458	prd(ji,jj,jk) = zn * r1_rau0 * ztm
459	!
460	END DO
461	END DO
462	END DO
463	!
464	END SELECT
465	!
466	IF(ln_ctl) CALL prt_ctl( tab3d_1=prd, clinfo1=' eos-pot: ', tab3d_2=prhop, clinfo2=' pot : ', kdim=jpk )
467	!
468	IF( ln_timing ) CALL timing_stop('eos-pot')
469	!
470	END SUBROUTINE eos_insitu_pot
471
472
473	SUBROUTINE eos_insitu_2d( pts, pdep, prd )
474	!!----------------------------------------------------------------------
475	!! * ROUTINE eos_insitu_2d *
476	!!
477	!! ** Purpose : Compute the in situ density (ratio rho/rau0) from
478	!! potential temperature and salinity using an equation of state
479	!! selected in the nameos namelist. * 2D field case
480	!!
481	!! ** Action : - prd , the in situ density (no units) (unmasked)
482	!!
483	!!----------------------------------------------------------------------
484	REAL(wp), DIMENSION(jpi,jpj,jpts), INTENT(in ) :: pts ! 1 : potential temperature [Celsius]
485	! ! 2 : salinity [psu]
486	REAL(wp), DIMENSION(jpi,jpj) , INTENT(in ) :: pdep ! depth [m]
487	REAL(wp), DIMENSION(jpi,jpj) , INTENT( out) :: prd ! in situ density
488	!
489	INTEGER :: ji, jj, jk ! dummy loop indices
490	REAL(wp) :: zt , zh , zs ! local scalars
491	REAL(wp) :: zn , zn0, zn1, zn2, zn3 ! - -
492	!!----------------------------------------------------------------------
493	!
494	IF( ln_timing ) CALL timing_start('eos2d')
495	!
496	prd(:,:) = 0._wp
497	!
498	SELECT CASE( neos )
499	!
500	CASE( np_teos10, np_eos80 ) !== polynomial TEOS-10 / EOS-80 ==!
501	!
502	DO jj = 1, jpjm1
503	DO ji = 1, fs_jpim1 ! vector opt.
504	!
505	zh = pdep(ji,jj) * r1_Z0 ! depth
506	zt = pts (ji,jj,jp_tem) * r1_T0 ! temperature
507	zs = SQRT( ABS( pts(ji,jj,jp_sal) + rdeltaS ) * r1_S0 ) ! square root salinity
508	!
509	zn3 = EOS013*zt &
510	& + EOS103*zs+EOS003
511	!
512	zn2 = (EOS022*zt &
513	& + EOS112zs+EOS012)zt &
514	& + (EOS202zs+EOS102)zs+EOS002
515	!
516	zn1 = (((EOS041*zt &
517	& + EOS131zs+EOS031)zt &
518	& + (EOS221zs+EOS121)zs+EOS021)*zt &
519	& + ((EOS311zs+EOS211)zs+EOS111)zs+EOS011)zt &
520	& + (((EOS401zs+EOS301)zs+EOS201)zs+EOS101)zs+EOS001
521	!
522	zn0 = (((((EOS060*zt &
523	& + EOS150zs+EOS050)zt &
524	& + (EOS240zs+EOS140)zs+EOS040)*zt &
525	& + ((EOS330zs+EOS230)zs+EOS130)zs+EOS030)zt &
526	& + (((EOS420zs+EOS320)zs+EOS220)zs+EOS120)zs+EOS020)*zt &
527	& + ((((EOS510zs+EOS410)zs+EOS310)zs+EOS210)zs+EOS110)zs+EOS010)zt &
528	& + (((((EOS600zs+EOS500)zs+EOS400)zs+EOS300)zs+EOS200)zs+EOS100)zs+EOS000
529	!
530	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
531	!
532	prd(ji,jj) = zn * r1_rau0 - 1._wp ! unmasked in situ density anomaly
533	!
534	END DO
535	END DO
536	!
537	CALL lbc_lnk( 'eosbn2', prd, 'T', 1. ) ! Lateral boundary conditions
538	!
539	CASE( np_seos ) !== simplified EOS ==!
540	!
541	DO jj = 1, jpjm1
542	DO ji = 1, fs_jpim1 ! vector opt.
543	!
544	zt = pts (ji,jj,jp_tem) - 10._wp
545	zs = pts (ji,jj,jp_sal) - 35._wp
546	zh = pdep (ji,jj) ! depth at the partial step level
547	!
548	zn = - rn_a0 * ( 1._wp + 0.5_wprn_lambda1zt + rn_mu1zh ) zt &
549	& + rn_b0 * ( 1._wp - 0.5_wprn_lambda2zs - rn_mu2zh ) zs &
550	& - rn_nu * zt * zs
551	!
552	prd(ji,jj) = zn * r1_rau0 ! unmasked in situ density anomaly
553	!
554	END DO
555	END DO
556	!
557	CALL lbc_lnk( 'eosbn2', prd, 'T', 1. ) ! Lateral boundary conditions
558	!
559	END SELECT
560	!
561	IF(ln_ctl) CALL prt_ctl( tab2d_1=prd, clinfo1=' eos2d: ' )
562	!
563	IF( ln_timing ) CALL timing_stop('eos2d')
564	!
565	END SUBROUTINE eos_insitu_2d
566
567
568	SUBROUTINE rab_3d( pts, pab, Kmm )
569	!!----------------------------------------------------------------------
570	!! * ROUTINE rab_3d *
571	!!
572	!! ** Purpose : Calculates thermal/haline expansion ratio at T-points
573	!!
574	!! ** Method : calculates alpha / beta at T-points
575	!!
576	!! ** Action : - pab : thermal/haline expansion ratio at T-points
577	!!----------------------------------------------------------------------
578	INTEGER , INTENT(in ) :: Kmm ! time level index
579	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT(in ) :: pts ! pot. temperature & salinity
580	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT( out) :: pab ! thermal/haline expansion ratio
581	!
582	INTEGER :: ji, jj, jk ! dummy loop indices
583	REAL(wp) :: zt , zh , zs , ztm ! local scalars
584	REAL(wp) :: zn , zn0, zn1, zn2, zn3 ! - -
585	!!----------------------------------------------------------------------
586	!
587	IF( ln_timing ) CALL timing_start('rab_3d')
588	!
589	SELECT CASE ( neos )
590	!
591	CASE( np_teos10, np_eos80 ) !== polynomial TEOS-10 / EOS-80 ==!
592	!
593	DO jk = 1, jpkm1
594	DO jj = 1, jpj
595	DO ji = 1, jpi
596	!
597	zh = gdept(ji,jj,jk,Kmm) * r1_Z0 ! depth
598	zt = pts (ji,jj,jk,jp_tem) * r1_T0 ! temperature
599	zs = SQRT( ABS( pts(ji,jj,jk,jp_sal) + rdeltaS ) * r1_S0 ) ! square root salinity
600	ztm = tmask(ji,jj,jk) ! tmask
601	!
602	! alpha
603	zn3 = ALP003
604	!
605	zn2 = ALP012zt + ALP102zs+ALP002
606	!
607	zn1 = ((ALP031*zt &
608	& + ALP121zs+ALP021)zt &
609	& + (ALP211zs+ALP111)zs+ALP011)*zt &
610	& + ((ALP301zs+ALP201)zs+ALP101)*zs+ALP001
611	!
612	zn0 = ((((ALP050*zt &
613	& + ALP140zs+ALP040)zt &
614	& + (ALP230zs+ALP130)zs+ALP030)*zt &
615	& + ((ALP320zs+ALP220)zs+ALP120)zs+ALP020)zt &
616	& + (((ALP410zs+ALP310)zs+ALP210)zs+ALP110)zs+ALP010)*zt &
617	& + ((((ALP500zs+ALP400)zs+ALP300)zs+ALP200)zs+ALP100)*zs+ALP000
618	!
619	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
620	!
621	pab(ji,jj,jk,jp_tem) = zn * r1_rau0 * ztm
622	!
623	! beta
624	zn3 = BET003
625	!
626	zn2 = BET012zt + BET102zs+BET002
627	!
628	zn1 = ((BET031*zt &
629	& + BET121zs+BET021)zt &
630	& + (BET211zs+BET111)zs+BET011)*zt &
631	& + ((BET301zs+BET201)zs+BET101)*zs+BET001
632	!
633	zn0 = ((((BET050*zt &
634	& + BET140zs+BET040)zt &
635	& + (BET230zs+BET130)zs+BET030)*zt &
636	& + ((BET320zs+BET220)zs+BET120)zs+BET020)zt &
637	& + (((BET410zs+BET310)zs+BET210)zs+BET110)zs+BET010)*zt &
638	& + ((((BET500zs+BET400)zs+BET300)zs+BET200)zs+BET100)*zs+BET000
639	!
640	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
641	!
642	pab(ji,jj,jk,jp_sal) = zn / zs * r1_rau0 * ztm
643	!
644	END DO
645	END DO
646	END DO
647	!
648	CASE( np_seos ) !== simplified EOS ==!
649	!
650	DO jk = 1, jpkm1
651	DO jj = 1, jpj
652	DO ji = 1, jpi
653	zt = pts (ji,jj,jk,jp_tem) - 10._wp ! pot. temperature anomaly (t-T0)
654	zs = pts (ji,jj,jk,jp_sal) - 35._wp ! abs. salinity anomaly (s-S0)
655	zh = gdept(ji,jj,jk,Kmm) ! depth in meters at t-point
656	ztm = tmask(ji,jj,jk) ! land/sea bottom mask = surf. mask
657	!
658	zn = rn_a0 * ( 1._wp + rn_lambda1zt + rn_mu1zh ) + rn_nu*zs
659	pab(ji,jj,jk,jp_tem) = zn * r1_rau0 * ztm ! alpha
660	!
661	zn = rn_b0 * ( 1._wp - rn_lambda2zs - rn_mu2zh ) - rn_nu*zt
662	pab(ji,jj,jk,jp_sal) = zn * r1_rau0 * ztm ! beta
663	!
664	END DO
665	END DO
666	END DO
667	!
668	CASE DEFAULT
669	WRITE(ctmp1,*) ' bad flag value for neos = ', neos
670	CALL ctl_stop( 'rab_3d:', ctmp1 )
671	!
672	END SELECT
673	!
674	IF(ln_ctl) CALL prt_ctl( tab3d_1=pab(:,:,:,jp_tem), clinfo1=' rab_3d_t: ', &
675	& tab3d_2=pab(:,:,:,jp_sal), clinfo2=' rab_3d_s : ', kdim=jpk )
676	!
677	IF( ln_timing ) CALL timing_stop('rab_3d')
678	!
679	END SUBROUTINE rab_3d
680
681
682	SUBROUTINE rab_2d( pts, pdep, pab, Kmm )
683	!!----------------------------------------------------------------------
684	!! * ROUTINE rab_2d *
685	!!
686	!! ** Purpose : Calculates thermal/haline expansion ratio for a 2d field (unmasked)
687	!!
688	!! ** Action : - pab : thermal/haline expansion ratio at T-points
689	!!----------------------------------------------------------------------
690	INTEGER , INTENT(in ) :: Kmm ! time level index
691	REAL(wp), DIMENSION(jpi,jpj,jpts) , INTENT(in ) :: pts ! pot. temperature & salinity
692	REAL(wp), DIMENSION(jpi,jpj) , INTENT(in ) :: pdep ! depth [m]
693	REAL(wp), DIMENSION(jpi,jpj,jpts) , INTENT( out) :: pab ! thermal/haline expansion ratio
694	!
695	INTEGER :: ji, jj, jk ! dummy loop indices
696	REAL(wp) :: zt , zh , zs ! local scalars
697	REAL(wp) :: zn , zn0, zn1, zn2, zn3 ! - -
698	!!----------------------------------------------------------------------
699	!
700	IF( ln_timing ) CALL timing_start('rab_2d')
701	!
702	pab(:,:,:) = 0._wp
703	!
704	SELECT CASE ( neos )
705	!
706	CASE( np_teos10, np_eos80 ) !== polynomial TEOS-10 / EOS-80 ==!
707	!
708	DO jj = 1, jpjm1
709	DO ji = 1, fs_jpim1 ! vector opt.
710	!
711	zh = pdep(ji,jj) * r1_Z0 ! depth
712	zt = pts (ji,jj,jp_tem) * r1_T0 ! temperature
713	zs = SQRT( ABS( pts(ji,jj,jp_sal) + rdeltaS ) * r1_S0 ) ! square root salinity
714	!
715	! alpha
716	zn3 = ALP003
717	!
718	zn2 = ALP012zt + ALP102zs+ALP002
719	!
720	zn1 = ((ALP031*zt &
721	& + ALP121zs+ALP021)zt &
722	& + (ALP211zs+ALP111)zs+ALP011)*zt &
723	& + ((ALP301zs+ALP201)zs+ALP101)*zs+ALP001
724	!
725	zn0 = ((((ALP050*zt &
726	& + ALP140zs+ALP040)zt &
727	& + (ALP230zs+ALP130)zs+ALP030)*zt &
728	& + ((ALP320zs+ALP220)zs+ALP120)zs+ALP020)zt &
729	& + (((ALP410zs+ALP310)zs+ALP210)zs+ALP110)zs+ALP010)*zt &
730	& + ((((ALP500zs+ALP400)zs+ALP300)zs+ALP200)zs+ALP100)*zs+ALP000
731	!
732	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
733	!
734	pab(ji,jj,jp_tem) = zn * r1_rau0
735	!
736	! beta
737	zn3 = BET003
738	!
739	zn2 = BET012zt + BET102zs+BET002
740	!
741	zn1 = ((BET031*zt &
742	& + BET121zs+BET021)zt &
743	& + (BET211zs+BET111)zs+BET011)*zt &
744	& + ((BET301zs+BET201)zs+BET101)*zs+BET001
745	!
746	zn0 = ((((BET050*zt &
747	& + BET140zs+BET040)zt &
748	& + (BET230zs+BET130)zs+BET030)*zt &
749	& + ((BET320zs+BET220)zs+BET120)zs+BET020)zt &
750	& + (((BET410zs+BET310)zs+BET210)zs+BET110)zs+BET010)*zt &
751	& + ((((BET500zs+BET400)zs+BET300)zs+BET200)zs+BET100)*zs+BET000
752	!
753	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
754	!
755	pab(ji,jj,jp_sal) = zn / zs * r1_rau0
756	!
757	!
758	END DO
759	END DO
760	! ! Lateral boundary conditions
761	CALL lbc_lnk_multi( 'eosbn2', pab(:,:,jp_tem), 'T', 1. , pab(:,:,jp_sal), 'T', 1. )
762	!
763	CASE( np_seos ) !== simplified EOS ==!
764	!
765	DO jj = 1, jpjm1
766	DO ji = 1, fs_jpim1 ! vector opt.
767	!
768	zt = pts (ji,jj,jp_tem) - 10._wp ! pot. temperature anomaly (t-T0)
769	zs = pts (ji,jj,jp_sal) - 35._wp ! abs. salinity anomaly (s-S0)
770	zh = pdep (ji,jj) ! depth at the partial step level
771	!
772	zn = rn_a0 * ( 1._wp + rn_lambda1zt + rn_mu1zh ) + rn_nu*zs
773	pab(ji,jj,jp_tem) = zn * r1_rau0 ! alpha
774	!
775	zn = rn_b0 * ( 1._wp - rn_lambda2zs - rn_mu2zh ) - rn_nu*zt
776	pab(ji,jj,jp_sal) = zn * r1_rau0 ! beta
777	!
778	END DO
779	END DO
780	! ! Lateral boundary conditions
781	CALL lbc_lnk_multi( 'eosbn2', pab(:,:,jp_tem), 'T', 1. , pab(:,:,jp_sal), 'T', 1. )
782	!
783	CASE DEFAULT
784	WRITE(ctmp1,*) ' bad flag value for neos = ', neos
785	CALL ctl_stop( 'rab_2d:', ctmp1 )
786	!
787	END SELECT
788	!
789	IF(ln_ctl) CALL prt_ctl( tab2d_1=pab(:,:,jp_tem), clinfo1=' rab_2d_t: ', &
790	& tab2d_2=pab(:,:,jp_sal), clinfo2=' rab_2d_s : ' )
791	!
792	IF( ln_timing ) CALL timing_stop('rab_2d')
793	!
794	END SUBROUTINE rab_2d
795
796
797	SUBROUTINE rab_0d( pts, pdep, pab, Kmm )
798	!!----------------------------------------------------------------------
799	!! * ROUTINE rab_0d *
800	!!
801	!! ** Purpose : Calculates thermal/haline expansion ratio for a 2d field (unmasked)
802	!!
803	!! ** Action : - pab : thermal/haline expansion ratio at T-points
804	!!----------------------------------------------------------------------
805	INTEGER , INTENT(in ) :: Kmm ! time level index
806	REAL(wp), DIMENSION(jpts) , INTENT(in ) :: pts ! pot. temperature & salinity
807	REAL(wp), INTENT(in ) :: pdep ! depth [m]
808	REAL(wp), DIMENSION(jpts) , INTENT( out) :: pab ! thermal/haline expansion ratio
809	!
810	REAL(wp) :: zt , zh , zs ! local scalars
811	REAL(wp) :: zn , zn0, zn1, zn2, zn3 ! - -
812	!!----------------------------------------------------------------------
813	!
814	IF( ln_timing ) CALL timing_start('rab_0d')
815	!
816	pab(:) = 0._wp
817	!
818	SELECT CASE ( neos )
819	!
820	CASE( np_teos10, np_eos80 ) !== polynomial TEOS-10 / EOS-80 ==!
821	!
822	!
823	zh = pdep * r1_Z0 ! depth
824	zt = pts (jp_tem) * r1_T0 ! temperature
825	zs = SQRT( ABS( pts(jp_sal) + rdeltaS ) * r1_S0 ) ! square root salinity
826	!
827	! alpha
828	zn3 = ALP003
829	!
830	zn2 = ALP012zt + ALP102zs+ALP002
831	!
832	zn1 = ((ALP031*zt &
833	& + ALP121zs+ALP021)zt &
834	& + (ALP211zs+ALP111)zs+ALP011)*zt &
835	& + ((ALP301zs+ALP201)zs+ALP101)*zs+ALP001
836	!
837	zn0 = ((((ALP050*zt &
838	& + ALP140zs+ALP040)zt &
839	& + (ALP230zs+ALP130)zs+ALP030)*zt &
840	& + ((ALP320zs+ALP220)zs+ALP120)zs+ALP020)zt &
841	& + (((ALP410zs+ALP310)zs+ALP210)zs+ALP110)zs+ALP010)*zt &
842	& + ((((ALP500zs+ALP400)zs+ALP300)zs+ALP200)zs+ALP100)*zs+ALP000
843	!
844	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
845	!
846	pab(jp_tem) = zn * r1_rau0
847	!
848	! beta
849	zn3 = BET003
850	!
851	zn2 = BET012zt + BET102zs+BET002
852	!
853	zn1 = ((BET031*zt &
854	& + BET121zs+BET021)zt &
855	& + (BET211zs+BET111)zs+BET011)*zt &
856	& + ((BET301zs+BET201)zs+BET101)*zs+BET001
857	!
858	zn0 = ((((BET050*zt &
859	& + BET140zs+BET040)zt &
860	& + (BET230zs+BET130)zs+BET030)*zt &
861	& + ((BET320zs+BET220)zs+BET120)zs+BET020)zt &
862	& + (((BET410zs+BET310)zs+BET210)zs+BET110)zs+BET010)*zt &
863	& + ((((BET500zs+BET400)zs+BET300)zs+BET200)zs+BET100)*zs+BET000
864	!
865	zn = ( ( zn3 * zh + zn2 ) * zh + zn1 ) * zh + zn0
866	!
867	pab(jp_sal) = zn / zs * r1_rau0
868	!
869	!
870	!
871	CASE( np_seos ) !== simplified EOS ==!
872	!
873	zt = pts(jp_tem) - 10._wp ! pot. temperature anomaly (t-T0)
874	zs = pts(jp_sal) - 35._wp ! abs. salinity anomaly (s-S0)
875	zh = pdep ! depth at the partial step level
876	!
877	zn = rn_a0 * ( 1._wp + rn_lambda1zt + rn_mu1zh ) + rn_nu*zs
878	pab(jp_tem) = zn * r1_rau0 ! alpha
879	!
880	zn = rn_b0 * ( 1._wp - rn_lambda2zs - rn_mu2zh ) - rn_nu*zt
881	pab(jp_sal) = zn * r1_rau0 ! beta
882	!
883	CASE DEFAULT
884	WRITE(ctmp1,*) ' bad flag value for neos = ', neos
885	CALL ctl_stop( 'rab_0d:', ctmp1 )
886	!
887	END SELECT
888	!
889	IF( ln_timing ) CALL timing_stop('rab_0d')
890	!
891	END SUBROUTINE rab_0d
892
893
894	SUBROUTINE bn2( pts, pab, pn2, Kmm )
895	!!----------------------------------------------------------------------
896	!! * ROUTINE bn2 *
897	!!
898	!! ** Purpose : Compute the local Brunt-Vaisala frequency at the
899	!! time-step of the input arguments
900	!!
901	!! ** Method : pn2 = grav * (alpha dk[T] + beta dk[S] ) / e3w
902	!! where alpha and beta are given in pab, and computed on T-points.
903	!! N.B. N^2 is set one for all to zero at jk=1 in istate module.
904	!!
905	!! ** Action : pn2 : square of the brunt-vaisala frequency at w-point
906	!!
907	!!----------------------------------------------------------------------
908	INTEGER , INTENT(in ) :: Kmm ! time level index
909	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT(in ) :: pts ! pot. temperature and salinity [Celsius,psu]
910	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT(in ) :: pab ! thermal/haline expansion coef. [Celsius-1,psu-1]
911	REAL(wp), DIMENSION(jpi,jpj,jpk ), INTENT( out) :: pn2 ! Brunt-Vaisala frequency squared [1/s^2]
912	!
913	INTEGER :: ji, jj, jk ! dummy loop indices
914	REAL(wp) :: zaw, zbw, zrw ! local scalars
915	!!----------------------------------------------------------------------
916	!
917	IF( ln_timing ) CALL timing_start('bn2')
918	!
919	DO jk = 2, jpkm1 ! interior points only (2=< jk =< jpkm1 )
920	DO jj = 1, jpj ! surface and bottom value set to zero one for all in istate.F90
921	DO ji = 1, jpi
922	zrw = ( gdepw(ji,jj,jk ,Kmm) - gdept(ji,jj,jk,Kmm) ) &
923	& / ( gdept(ji,jj,jk-1,Kmm) - gdept(ji,jj,jk,Kmm) )
924	!
925	zaw = pab(ji,jj,jk,jp_tem) * (1. - zrw) + pab(ji,jj,jk-1,jp_tem) * zrw
926	zbw = pab(ji,jj,jk,jp_sal) * (1. - zrw) + pab(ji,jj,jk-1,jp_sal) * zrw
927	!
928	pn2(ji,jj,jk) = grav * ( zaw * ( pts(ji,jj,jk-1,jp_tem) - pts(ji,jj,jk,jp_tem) ) &
929	& - zbw * ( pts(ji,jj,jk-1,jp_sal) - pts(ji,jj,jk,jp_sal) ) ) &
930	& / e3w(ji,jj,jk,Kmm) * wmask(ji,jj,jk)
931	END DO
932	END DO
933	END DO
934	!
935	IF(ln_ctl) CALL prt_ctl( tab3d_1=pn2, clinfo1=' bn2 : ', kdim=jpk )
936	!
937	IF( ln_timing ) CALL timing_stop('bn2')
938	!
939	END SUBROUTINE bn2
940
941
942	FUNCTION eos_pt_from_ct( ctmp, psal ) RESULT( ptmp )
943	!!----------------------------------------------------------------------
944	!! * ROUTINE eos_pt_from_ct *
945	!!
946	!! ** Purpose : Compute pot.temp. from cons. temp. [Celsius]
947	!!
948	!! ** Method : rational approximation (5/3th order) of TEOS-10 algorithm
949	!! checkvalue: pt=20.02391895 Celsius for sa=35.7g/kg, ct=20degC
950	!!
951	!! Reference : TEOS-10, UNESCO
952	!! Rational approximation to TEOS10 algorithm (rms error on WOA13 values: 4.0e-5 degC)
953	!!----------------------------------------------------------------------
954	REAL(wp), DIMENSION(jpi,jpj), INTENT(in ) :: ctmp ! Cons. Temp [Celsius]
955	REAL(wp), DIMENSION(jpi,jpj), INTENT(in ) :: psal ! salinity [psu]
956	! Leave result array automatic rather than making explicitly allocated
957	REAL(wp), DIMENSION(jpi,jpj) :: ptmp ! potential temperature [Celsius]
958	!
959	INTEGER :: ji, jj ! dummy loop indices
960	REAL(wp) :: zt , zs , ztm ! local scalars
961	REAL(wp) :: zn , zd ! local scalars
962	REAL(wp) :: zdeltaS , z1_S0 , z1_T0
963	!!----------------------------------------------------------------------
964	!
965	IF( ln_timing ) CALL timing_start('eos_pt_from_ct')
966	!
967	zdeltaS = 5._wp
968	z1_S0 = 0.875_wp/35.16504_wp
969	z1_T0 = 1._wp/40._wp
970	!
971	DO jj = 1, jpj
972	DO ji = 1, jpi
973	!
974	zt = ctmp (ji,jj) * z1_T0
975	zs = SQRT( ABS( psal(ji,jj) + zdeltaS ) * r1_S0 )
976	ztm = tmask(ji,jj,1)
977	!
978	zn = ((((-2.1385727895e-01_wp*zt &
979	& - 2.7674419971e-01_wpzs+1.0728094330_wp)zt &
980	& + (2.6366564313_wpzs+3.3546960647_wp)zs-7.8012209473_wp)*zt &
981	& + ((1.8835586562_wpzs+7.3949191679_wp)zs-3.3937395875_wp)zs-5.6414948432_wp)zt &
982	& + (((3.5737370589_wpzs-1.5512427389e+01_wp)zs+2.4625741105e+01_wp)*zs &
983	& +1.9912291000e+01_wp)zs-3.2191146312e+01_wp)zt &
984	& + ((((5.7153204649e-01_wpzs-3.0943149543_wp)zs+9.3052495181_wp)*zs &
985	& -9.4528934807_wp)zs+3.1066408996_wp)zs-4.3504021262e-01_wp
986	!
987	zd = (2.0035003456_wp*zt &
988	& -3.4570358592e-01_wpzs+5.6471810638_wp)zt &
989	& + (1.5393993508_wpzs-6.9394762624_wp)zs+1.2750522650e+01_wp
990	!
991	ptmp(ji,jj) = ( zt / z1_T0 + zn / zd ) * ztm
992	!
993	END DO
994	END DO
995	!
996	IF( ln_timing ) CALL timing_stop('eos_pt_from_ct')
997	!
998	END FUNCTION eos_pt_from_ct
999
1000
1001	SUBROUTINE eos_fzp_2d( psal, ptf, pdep )
1002	!!----------------------------------------------------------------------
1003	!! * ROUTINE eos_fzp *
1004	!!
1005	!! ** Purpose : Compute the freezing point temperature [Celsius]
1006	!!
1007	!! ** Method : UNESCO freezing point (ptf) in Celsius is given by
1008	!! ptf(t,z) = (-.0575+1.710523e-3sqrt(abs(s))-2.154996e-4s)s - 7.53e-4z
1009	!! checkvalue: tf=-2.588567 Celsius for s=40psu, z=500m
1010	!!
1011	!! Reference : UNESCO tech. papers in the marine science no. 28. 1978
1012	!!----------------------------------------------------------------------
1013	REAL(wp), DIMENSION(jpi,jpj), INTENT(in ) :: psal ! salinity [psu]
1014	REAL(wp), DIMENSION(jpi,jpj), INTENT(in ), OPTIONAL :: pdep ! depth [m]
1015	REAL(wp), DIMENSION(jpi,jpj), INTENT(out ) :: ptf ! freezing temperature [Celsius]
1016	!
1017	INTEGER :: ji, jj ! dummy loop indices
1018	REAL(wp) :: zt, zs, z1_S0 ! local scalars
1019	!!----------------------------------------------------------------------
1020	!
1021	SELECT CASE ( neos )
1022	!
1023	CASE ( np_teos10, np_seos ) !== CT,SA (TEOS-10 and S-EOS formulations) ==!
1024	!
1025	z1_S0 = 1._wp / 35.16504_wp
1026	DO jj = 1, jpj
1027	DO ji = 1, jpi
1028	zs= SQRT( ABS( psal(ji,jj) ) * z1_S0 ) ! square root salinity
1029	ptf(ji,jj) = ((((1.46873e-03_wpzs-9.64972e-03_wp)zs+2.28348e-02_wp)*zs &
1030	& - 3.12775e-02_wp)zs+2.07679e-02_wp)zs-5.87701e-02_wp
1031	END DO
1032	END DO
1033	ptf(:,:) = ptf(:,:) * psal(:,:)
1034	!
1035	IF( PRESENT( pdep ) ) ptf(:,:) = ptf(:,:) - 7.53e-4 * pdep(:,:)
1036	!
1037	CASE ( np_eos80 ) !== PT,SP (UNESCO formulation) ==!
1038	!
1039	ptf(:,:) = ( - 0.0575_wp + 1.710523e-3_wp * SQRT( psal(:,:) ) &
1040	& - 2.154996e-4_wp * psal(:,:) ) * psal(:,:)
1041	!
1042	IF( PRESENT( pdep ) ) ptf(:,:) = ptf(:,:) - 7.53e-4 * pdep(:,:)
1043	!
1044	CASE DEFAULT
1045	WRITE(ctmp1,*) ' bad flag value for neos = ', neos
1046	CALL ctl_stop( 'eos_fzp_2d:', ctmp1 )
1047	!
1048	END SELECT
1049	!
1050	END SUBROUTINE eos_fzp_2d
1051
1052
1053	SUBROUTINE eos_fzp_0d( psal, ptf, pdep )
1054	!!----------------------------------------------------------------------
1055	!! * ROUTINE eos_fzp *
1056	!!
1057	!! ** Purpose : Compute the freezing point temperature [Celsius]
1058	!!
1059	!! ** Method : UNESCO freezing point (ptf) in Celsius is given by
1060	!! ptf(t,z) = (-.0575+1.710523e-3sqrt(abs(s))-2.154996e-4s)s - 7.53e-4z
1061	!! checkvalue: tf=-2.588567 Celsius for s=40psu, z=500m
1062	!!
1063	!! Reference : UNESCO tech. papers in the marine science no. 28. 1978
1064	!!----------------------------------------------------------------------
1065	REAL(wp), INTENT(in ) :: psal ! salinity [psu]
1066	REAL(wp), INTENT(in ), OPTIONAL :: pdep ! depth [m]
1067	REAL(wp), INTENT(out) :: ptf ! freezing temperature [Celsius]
1068	!
1069	REAL(wp) :: zs ! local scalars
1070	!!----------------------------------------------------------------------
1071	!
1072	SELECT CASE ( neos )
1073	!
1074	CASE ( np_teos10, np_seos ) !== CT,SA (TEOS-10 and S-EOS formulations) ==!
1075	!
1076	zs = SQRT( ABS( psal ) / 35.16504_wp ) ! square root salinity
1077	ptf = ((((1.46873e-03_wpzs-9.64972e-03_wp)zs+2.28348e-02_wp)*zs &
1078	& - 3.12775e-02_wp)zs+2.07679e-02_wp)zs-5.87701e-02_wp
1079	ptf = ptf * psal
1080	!
1081	IF( PRESENT( pdep ) ) ptf = ptf - 7.53e-4 * pdep
1082	!
1083	CASE ( np_eos80 ) !== PT,SP (UNESCO formulation) ==!
1084	!
1085	ptf = ( - 0.0575_wp + 1.710523e-3_wp * SQRT( psal ) &
1086	& - 2.154996e-4_wp * psal ) * psal
1087	!
1088	IF( PRESENT( pdep ) ) ptf = ptf - 7.53e-4 * pdep
1089	!
1090	CASE DEFAULT
1091	WRITE(ctmp1,*) ' bad flag value for neos = ', neos
1092	CALL ctl_stop( 'eos_fzp_0d:', ctmp1 )
1093	!
1094	END SELECT
1095	!
1096	END SUBROUTINE eos_fzp_0d
1097
1098
1099	SUBROUTINE eos_pen( pts, pab_pe, ppen, Kmm )
1100	!!----------------------------------------------------------------------
1101	!! * ROUTINE eos_pen *
1102	!!
1103	!! ** Purpose : Calculates nonlinear anomalies of alpha_PE, beta_PE and PE at T-points
1104	!!
1105	!! ** Method : PE is defined analytically as the vertical
1106	!! primitive of EOS times -g integrated between 0 and z>0.
1107	!! pen is the nonlinear bsq-PE anomaly: pen = ( PE - rau0 gz ) / rau0 gz - rd
1108	!! = 1/z * /int_0^z rd dz - rd
1109	!! where rd is the density anomaly (see eos_rhd function)
1110	!! ab_pe are partial derivatives of PE anomaly with respect to T and S:
1111	!! ab_pe(1) = - 1/(rau0 gz) * dPE/dT + drd/dT = - d(pen)/dT
1112	!! ab_pe(2) = 1/(rau0 gz) * dPE/dS + drd/dS = d(pen)/dS
1113	!!
1114	!! ** Action : - pen : PE anomaly given at T-points
1115	!! : - pab_pe : given at T-points
1116	!! pab_pe(:,:,:,jp_tem) is alpha_pe
1117	!! pab_pe(:,:,:,jp_sal) is beta_pe
1118	!!----------------------------------------------------------------------
1119	INTEGER , INTENT(in ) :: Kmm ! time level index
1120	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT(in ) :: pts ! pot. temperature & salinity
1121	REAL(wp), DIMENSION(jpi,jpj,jpk,jpts), INTENT( out) :: pab_pe ! alpha_pe and beta_pe
1122	REAL(wp), DIMENSION(jpi,jpj,jpk) , INTENT( out) :: ppen ! potential energy anomaly
1123	!
1124	INTEGER :: ji, jj, jk ! dummy loop indices
1125	REAL(wp) :: zt , zh , zs , ztm ! local scalars
1126	REAL(wp) :: zn , zn0, zn1, zn2 ! - -
1127	!!----------------------------------------------------------------------
1128	!
1129	IF( ln_timing ) CALL timing_start('eos_pen')
1130	!
1131	SELECT CASE ( neos )
1132	!
1133	CASE( np_teos10, np_eos80 ) !== polynomial TEOS-10 / EOS-80 ==!
1134	!
1135	DO jk = 1, jpkm1
1136	DO jj = 1, jpj
1137	DO ji = 1, jpi
1138	!
1139	zh = gdept(ji,jj,jk,Kmm) * r1_Z0 ! depth
1140	zt = pts (ji,jj,jk,jp_tem) * r1_T0 ! temperature
1141	zs = SQRT( ABS( pts(ji,jj,jk,jp_sal) + rdeltaS ) * r1_S0 ) ! square root salinity
1142	ztm = tmask(ji,jj,jk) ! tmask
1143	!
1144	! potential energy non-linear anomaly
1145	zn2 = (PEN012)*zt &
1146	& + PEN102*zs+PEN002
1147	!
1148	zn1 = ((PEN021)*zt &
1149	& + PEN111zs+PEN011)zt &
1150	& + (PEN201zs+PEN101)zs+PEN001
1151	!
1152	zn0 = ((((PEN040)*zt &
1153	& + PEN130zs+PEN030)zt &
1154	& + (PEN220zs+PEN120)zs+PEN020)*zt &
1155	& + ((PEN310zs+PEN210)zs+PEN110)zs+PEN010)zt &
1156	& + (((PEN400zs+PEN300)zs+PEN200)zs+PEN100)zs+PEN000
1157	!
1158	zn = ( zn2 * zh + zn1 ) * zh + zn0
1159	!
1160	ppen(ji,jj,jk) = zn * zh * r1_rau0 * ztm
1161	!
1162	! alphaPE non-linear anomaly
1163	zn2 = APE002
1164	!
1165	zn1 = (APE011)*zt &
1166	& + APE101*zs+APE001
1167	!
1168	zn0 = (((APE030)*zt &
1169	& + APE120zs+APE020)zt &
1170	& + (APE210zs+APE110)zs+APE010)*zt &
1171	& + ((APE300zs+APE200)zs+APE100)*zs+APE000
1172	!
1173	zn = ( zn2 * zh + zn1 ) * zh + zn0
1174	!
1175	pab_pe(ji,jj,jk,jp_tem) = zn * zh * r1_rau0 * ztm
1176	!
1177	! betaPE non-linear anomaly
1178	zn2 = BPE002
1179	!
1180	zn1 = (BPE011)*zt &
1181	& + BPE101*zs+BPE001
1182	!
1183	zn0 = (((BPE030)*zt &
1184	& + BPE120zs+BPE020)zt &
1185	& + (BPE210zs+BPE110)zs+BPE010)*zt &
1186	& + ((BPE300zs+BPE200)zs+BPE100)*zs+BPE000
1187	!
1188	zn = ( zn2 * zh + zn1 ) * zh + zn0
1189	!
1190	pab_pe(ji,jj,jk,jp_sal) = zn / zs * zh * r1_rau0 * ztm
1191	!
1192	END DO
1193	END DO
1194	END DO
1195	!
1196	CASE( np_seos ) !== Vallis (2006) simplified EOS ==!
1197	!
1198	DO jk = 1, jpkm1
1199	DO jj = 1, jpj
1200	DO ji = 1, jpi
1201	zt = pts(ji,jj,jk,jp_tem) - 10._wp ! temperature anomaly (t-T0)
1202	zs = pts (ji,jj,jk,jp_sal) - 35._wp ! abs. salinity anomaly (s-S0)
1203	zh = gdept(ji,jj,jk,Kmm) ! depth in meters at t-point
1204	ztm = tmask(ji,jj,jk) ! tmask
1205	zn = 0.5_wp * zh * r1_rau0 * ztm
1206	! ! Potential Energy
1207	ppen(ji,jj,jk) = ( rn_a0 * rn_mu1 * zt + rn_b0 * rn_mu2 * zs ) * zn
1208	! ! alphaPE
1209	pab_pe(ji,jj,jk,jp_tem) = - rn_a0 * rn_mu1 * zn
1210	pab_pe(ji,jj,jk,jp_sal) = rn_b0 * rn_mu2 * zn
1211	!
1212	END DO
1213	END DO
1214	END DO
1215	!
1216	CASE DEFAULT
1217	WRITE(ctmp1,*) ' bad flag value for neos = ', neos
1218	CALL ctl_stop( 'eos_pen:', ctmp1 )
1219	!
1220	END SELECT
1221	!
1222	IF( ln_timing ) CALL timing_stop('eos_pen')
1223	!
1224	END SUBROUTINE eos_pen
1225
1226
1227	SUBROUTINE eos_init
1228	!!----------------------------------------------------------------------
1229	!! * ROUTINE eos_init *
1230	!!
1231	!! ** Purpose : initializations for the equation of state
1232	!!
1233	!! ** Method : Read the namelist nameos and control the parameters
1234	!!----------------------------------------------------------------------
1235	INTEGER :: ios ! local integer
1236	INTEGER :: ioptio ! local integer
1237	!!
1238	NAMELIST/nameos/ ln_TEOS10, ln_EOS80, ln_SEOS, rn_a0, rn_b0, rn_lambda1, rn_mu1, &
1239	& rn_lambda2, rn_mu2, rn_nu
1240	!!----------------------------------------------------------------------
1241	!
1242	REWIND( numnam_ref ) ! Namelist nameos in reference namelist : equation of state
1243	READ ( numnam_ref, nameos, IOSTAT = ios, ERR = 901 )
1244	901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'nameos in reference namelist' )
1245	!
1246	REWIND( numnam_cfg ) ! Namelist nameos in configuration namelist : equation of state
1247	READ ( numnam_cfg, nameos, IOSTAT = ios, ERR = 902 )
1248	902 IF( ios > 0 ) CALL ctl_nam ( ios , 'nameos in configuration namelist' )
1249	IF(lwm) WRITE( numond, nameos )
1250	!
1251	rau0 = 1026._wp !: volumic mass of reference [kg/m3]
1252	rcp = 3991.86795711963_wp !: heat capacity [J/K]
1253	!
1254	IF(lwp) THEN ! Control print
1255	WRITE(numout,*)
1256	WRITE(numout,*) 'eos_init : equation of state'
1257	WRITE(numout,*) '~~~~~~~~'
1258	WRITE(numout,*) ' Namelist nameos : Chosen the Equation Of Seawater (EOS)'
1259	WRITE(numout,*) ' TEOS-10 : rho=F(Conservative Temperature, Absolute Salinity, depth) ln_TEOS10 = ', ln_TEOS10
1260	WRITE(numout,*) ' EOS-80 : rho=F(Potential Temperature, Practical Salinity, depth) ln_EOS80 = ', ln_EOS80
1261	WRITE(numout,*) ' S-EOS : rho=F(Conservative Temperature, Absolute Salinity, depth) ln_SEOS = ', ln_SEOS
1262	ENDIF
1263
1264	! Check options for equation of state & set neos based on logical flags
1265	ioptio = 0
1266	IF( ln_TEOS10 ) THEN ; ioptio = ioptio+1 ; neos = np_teos10 ; ENDIF
1267	IF( ln_EOS80 ) THEN ; ioptio = ioptio+1 ; neos = np_eos80 ; ENDIF
1268	IF( ln_SEOS ) THEN ; ioptio = ioptio+1 ; neos = np_seos ; ENDIF
1269	IF( ioptio /= 1 ) CALL ctl_stop("Exactly one equation of state option must be selected")
1270	!
1271	SELECT CASE( neos ) ! check option
1272	!
1273	CASE( np_teos10 ) !== polynomial TEOS-10 ==!
1274	IF(lwp) WRITE(numout,*)
1275	IF(lwp) WRITE(numout,*) ' ==>>> use of TEOS-10 equation of state (cons. temp. and abs. salinity)'
1276	!
1277	l_useCT = .TRUE. ! model temperature is Conservative temperature
1278	!
1279	rdeltaS = 32._wp
1280	r1_S0 = 0.875_wp/35.16504_wp
1281	r1_T0 = 1._wp/40._wp
1282	r1_Z0 = 1.e-4_wp
1283	!
1284	EOS000 = 8.0189615746e+02_wp
1285	EOS100 = 8.6672408165e+02_wp
1286	EOS200 = -1.7864682637e+03_wp
1287	EOS300 = 2.0375295546e+03_wp
1288	EOS400 = -1.2849161071e+03_wp
1289	EOS500 = 4.3227585684e+02_wp
1290	EOS600 = -6.0579916612e+01_wp
1291	EOS010 = 2.6010145068e+01_wp
1292	EOS110 = -6.5281885265e+01_wp
1293	EOS210 = 8.1770425108e+01_wp
1294	EOS310 = -5.6888046321e+01_wp
1295	EOS410 = 1.7681814114e+01_wp
1296	EOS510 = -1.9193502195_wp
1297	EOS020 = -3.7074170417e+01_wp
1298	EOS120 = 6.1548258127e+01_wp
1299	EOS220 = -6.0362551501e+01_wp
1300	EOS320 = 2.9130021253e+01_wp
1301	EOS420 = -5.4723692739_wp
1302	EOS030 = 2.1661789529e+01_wp
1303	EOS130 = -3.3449108469e+01_wp
1304	EOS230 = 1.9717078466e+01_wp
1305	EOS330 = -3.1742946532_wp
1306	EOS040 = -8.3627885467_wp
1307	EOS140 = 1.1311538584e+01_wp
1308	EOS240 = -5.3563304045_wp
1309	EOS050 = 5.4048723791e-01_wp
1310	EOS150 = 4.8169980163e-01_wp
1311	EOS060 = -1.9083568888e-01_wp
1312	EOS001 = 1.9681925209e+01_wp
1313	EOS101 = -4.2549998214e+01_wp
1314	EOS201 = 5.0774768218e+01_wp
1315	EOS301 = -3.0938076334e+01_wp
1316	EOS401 = 6.6051753097_wp
1317	EOS011 = -1.3336301113e+01_wp
1318	EOS111 = -4.4870114575_wp
1319	EOS211 = 5.0042598061_wp
1320	EOS311 = -6.5399043664e-01_wp
1321	EOS021 = 6.7080479603_wp
1322	EOS121 = 3.5063081279_wp
1323	EOS221 = -1.8795372996_wp
1324	EOS031 = -2.4649669534_wp
1325	EOS131 = -5.5077101279e-01_wp
1326	EOS041 = 5.5927935970e-01_wp
1327	EOS002 = 2.0660924175_wp
1328	EOS102 = -4.9527603989_wp
1329	EOS202 = 2.5019633244_wp
1330	EOS012 = 2.0564311499_wp
1331	EOS112 = -2.1311365518e-01_wp
1332	EOS022 = -1.2419983026_wp
1333	EOS003 = -2.3342758797e-02_wp
1334	EOS103 = -1.8507636718e-02_wp
1335	EOS013 = 3.7969820455e-01_wp
1336	!
1337	ALP000 = -6.5025362670e-01_wp
1338	ALP100 = 1.6320471316_wp
1339	ALP200 = -2.0442606277_wp
1340	ALP300 = 1.4222011580_wp
1341	ALP400 = -4.4204535284e-01_wp
1342	ALP500 = 4.7983755487e-02_wp
1343	ALP010 = 1.8537085209_wp
1344	ALP110 = -3.0774129064_wp
1345	ALP210 = 3.0181275751_wp
1346	ALP310 = -1.4565010626_wp
1347	ALP410 = 2.7361846370e-01_wp
1348	ALP020 = -1.6246342147_wp
1349	ALP120 = 2.5086831352_wp
1350	ALP220 = -1.4787808849_wp
1351	ALP320 = 2.3807209899e-01_wp
1352	ALP030 = 8.3627885467e-01_wp
1353	ALP130 = -1.1311538584_wp
1354	ALP230 = 5.3563304045e-01_wp
1355	ALP040 = -6.7560904739e-02_wp
1356	ALP140 = -6.0212475204e-02_wp
1357	ALP050 = 2.8625353333e-02_wp
1358	ALP001 = 3.3340752782e-01_wp
1359	ALP101 = 1.1217528644e-01_wp
1360	ALP201 = -1.2510649515e-01_wp
1361	ALP301 = 1.6349760916e-02_wp
1362	ALP011 = -3.3540239802e-01_wp
1363	ALP111 = -1.7531540640e-01_wp
1364	ALP211 = 9.3976864981e-02_wp
1365	ALP021 = 1.8487252150e-01_wp
1366	ALP121 = 4.1307825959e-02_wp
1367	ALP031 = -5.5927935970e-02_wp
1368	ALP002 = -5.1410778748e-02_wp
1369	ALP102 = 5.3278413794e-03_wp
1370	ALP012 = 6.2099915132e-02_wp
1371	ALP003 = -9.4924551138e-03_wp
1372	!
1373	BET000 = 1.0783203594e+01_wp
1374	BET100 = -4.4452095908e+01_wp
1375	BET200 = 7.6048755820e+01_wp
1376	BET300 = -6.3944280668e+01_wp
1377	BET400 = 2.6890441098e+01_wp
1378	BET500 = -4.5221697773_wp
1379	BET010 = -8.1219372432e-01_wp
1380	BET110 = 2.0346663041_wp
1381	BET210 = -2.1232895170_wp
1382	BET310 = 8.7994140485e-01_wp
1383	BET410 = -1.1939638360e-01_wp
1384	BET020 = 7.6574242289e-01_wp
1385	BET120 = -1.5019813020_wp
1386	BET220 = 1.0872489522_wp
1387	BET320 = -2.7233429080e-01_wp
1388	BET030 = -4.1615152308e-01_wp
1389	BET130 = 4.9061350869e-01_wp
1390	BET230 = -1.1847737788e-01_wp
1391	BET040 = 1.4073062708e-01_wp
1392	BET140 = -1.3327978879e-01_wp
1393	BET050 = 5.9929880134e-03_wp
1394	BET001 = -5.2937873009e-01_wp
1395	BET101 = 1.2634116779_wp
1396	BET201 = -1.1547328025_wp
1397	BET301 = 3.2870876279e-01_wp
1398	BET011 = -5.5824407214e-02_wp
1399	BET111 = 1.2451933313e-01_wp
1400	BET211 = -2.4409539932e-02_wp
1401	BET021 = 4.3623149752e-02_wp
1402	BET121 = -4.6767901790e-02_wp
1403	BET031 = -6.8523260060e-03_wp
1404	BET002 = -6.1618945251e-02_wp
1405	BET102 = 6.2255521644e-02_wp
1406	BET012 = -2.6514181169e-03_wp
1407	BET003 = -2.3025968587e-04_wp
1408	!
1409	PEN000 = -9.8409626043_wp
1410	PEN100 = 2.1274999107e+01_wp
1411	PEN200 = -2.5387384109e+01_wp
1412	PEN300 = 1.5469038167e+01_wp
1413	PEN400 = -3.3025876549_wp
1414	PEN010 = 6.6681505563_wp
1415	PEN110 = 2.2435057288_wp
1416	PEN210 = -2.5021299030_wp
1417	PEN310 = 3.2699521832e-01_wp
1418	PEN020 = -3.3540239802_wp
1419	PEN120 = -1.7531540640_wp
1420	PEN220 = 9.3976864981e-01_wp
1421	PEN030 = 1.2324834767_wp
1422	PEN130 = 2.7538550639e-01_wp
1423	PEN040 = -2.7963967985e-01_wp
1424	PEN001 = -1.3773949450_wp
1425	PEN101 = 3.3018402659_wp
1426	PEN201 = -1.6679755496_wp
1427	PEN011 = -1.3709540999_wp
1428	PEN111 = 1.4207577012e-01_wp
1429	PEN021 = 8.2799886843e-01_wp
1430	PEN002 = 1.7507069098e-02_wp
1431	PEN102 = 1.3880727538e-02_wp
1432	PEN012 = -2.8477365341e-01_wp
1433	!
1434	APE000 = -1.6670376391e-01_wp
1435	APE100 = -5.6087643219e-02_wp
1436	APE200 = 6.2553247576e-02_wp
1437	APE300 = -8.1748804580e-03_wp
1438	APE010 = 1.6770119901e-01_wp
1439	APE110 = 8.7657703198e-02_wp
1440	APE210 = -4.6988432490e-02_wp
1441	APE020 = -9.2436260751e-02_wp
1442	APE120 = -2.0653912979e-02_wp
1443	APE030 = 2.7963967985e-02_wp
1444	APE001 = 3.4273852498e-02_wp
1445	APE101 = -3.5518942529e-03_wp
1446	APE011 = -4.1399943421e-02_wp
1447	APE002 = 7.1193413354e-03_wp
1448	!
1449	BPE000 = 2.6468936504e-01_wp
1450	BPE100 = -6.3170583896e-01_wp
1451	BPE200 = 5.7736640125e-01_wp
1452	BPE300 = -1.6435438140e-01_wp
1453	BPE010 = 2.7912203607e-02_wp
1454	BPE110 = -6.2259666565e-02_wp
1455	BPE210 = 1.2204769966e-02_wp
1456	BPE020 = -2.1811574876e-02_wp
1457	BPE120 = 2.3383950895e-02_wp
1458	BPE030 = 3.4261630030e-03_wp
1459	BPE001 = 4.1079296834e-02_wp
1460	BPE101 = -4.1503681096e-02_wp
1461	BPE011 = 1.7676120780e-03_wp
1462	BPE002 = 1.7269476440e-04_wp
1463	!
1464	CASE( np_eos80 ) !== polynomial EOS-80 formulation ==!
1465	!
1466	IF(lwp) WRITE(numout,*)
1467	IF(lwp) WRITE(numout,*) ' ==>>> use of EOS-80 equation of state (pot. temp. and pract. salinity)'
1468	!
1469	l_useCT = .FALSE. ! model temperature is Potential temperature
1470	rdeltaS = 20._wp
1471	r1_S0 = 1._wp/40._wp
1472	r1_T0 = 1._wp/40._wp
1473	r1_Z0 = 1.e-4_wp
1474	!
1475	EOS000 = 9.5356891948e+02_wp
1476	EOS100 = 1.7136499189e+02_wp
1477	EOS200 = -3.7501039454e+02_wp
1478	EOS300 = 5.1856810420e+02_wp
1479	EOS400 = -3.7264470465e+02_wp
1480	EOS500 = 1.4302533998e+02_wp
1481	EOS600 = -2.2856621162e+01_wp
1482	EOS010 = 1.0087518651e+01_wp
1483	EOS110 = -1.3647741861e+01_wp
1484	EOS210 = 8.8478359933_wp
1485	EOS310 = -7.2329388377_wp
1486	EOS410 = 1.4774410611_wp
1487	EOS510 = 2.0036720553e-01_wp
1488	EOS020 = -2.5579830599e+01_wp
1489	EOS120 = 2.4043512327e+01_wp
1490	EOS220 = -1.6807503990e+01_wp
1491	EOS320 = 8.3811577084_wp
1492	EOS420 = -1.9771060192_wp
1493	EOS030 = 1.6846451198e+01_wp
1494	EOS130 = -2.1482926901e+01_wp
1495	EOS230 = 1.0108954054e+01_wp
1496	EOS330 = -6.2675951440e-01_wp
1497	EOS040 = -8.0812310102_wp
1498	EOS140 = 1.0102374985e+01_wp
1499	EOS240 = -4.8340368631_wp
1500	EOS050 = 1.2079167803_wp
1501	EOS150 = 1.1515380987e-01_wp
1502	EOS060 = -2.4520288837e-01_wp
1503	EOS001 = 1.0748601068e+01_wp
1504	EOS101 = -1.7817043500e+01_wp
1505	EOS201 = 2.2181366768e+01_wp
1506	EOS301 = -1.6750916338e+01_wp
1507	EOS401 = 4.1202230403_wp
1508	EOS011 = -1.5852644587e+01_wp
1509	EOS111 = -7.6639383522e-01_wp
1510	EOS211 = 4.1144627302_wp
1511	EOS311 = -6.6955877448e-01_wp
1512	EOS021 = 9.9994861860_wp
1513	EOS121 = -1.9467067787e-01_wp
1514	EOS221 = -1.2177554330_wp
1515	EOS031 = -3.4866102017_wp
1516	EOS131 = 2.2229155620e-01_wp
1517	EOS041 = 5.9503008642e-01_wp
1518	EOS002 = 1.0375676547_wp
1519	EOS102 = -3.4249470629_wp
1520	EOS202 = 2.0542026429_wp
1521	EOS012 = 2.1836324814_wp
1522	EOS112 = -3.4453674320e-01_wp
1523	EOS022 = -1.2548163097_wp
1524	EOS003 = 1.8729078427e-02_wp
1525	EOS103 = -5.7238495240e-02_wp
1526	EOS013 = 3.8306136687e-01_wp
1527	!
1528	ALP000 = -2.5218796628e-01_wp
1529	ALP100 = 3.4119354654e-01_wp
1530	ALP200 = -2.2119589983e-01_wp
1531	ALP300 = 1.8082347094e-01_wp
1532	ALP400 = -3.6936026529e-02_wp
1533	ALP500 = -5.0091801383e-03_wp
1534	ALP010 = 1.2789915300_wp
1535	ALP110 = -1.2021756164_wp
1536	ALP210 = 8.4037519952e-01_wp
1537	ALP310 = -4.1905788542e-01_wp
1538	ALP410 = 9.8855300959e-02_wp
1539	ALP020 = -1.2634838399_wp
1540	ALP120 = 1.6112195176_wp
1541	ALP220 = -7.5817155402e-01_wp
1542	ALP320 = 4.7006963580e-02_wp
1543	ALP030 = 8.0812310102e-01_wp
1544	ALP130 = -1.0102374985_wp
1545	ALP230 = 4.8340368631e-01_wp
1546	ALP040 = -1.5098959754e-01_wp
1547	ALP140 = -1.4394226233e-02_wp
1548	ALP050 = 3.6780433255e-02_wp
1549	ALP001 = 3.9631611467e-01_wp
1550	ALP101 = 1.9159845880e-02_wp
1551	ALP201 = -1.0286156825e-01_wp
1552	ALP301 = 1.6738969362e-02_wp
1553	ALP011 = -4.9997430930e-01_wp
1554	ALP111 = 9.7335338937e-03_wp
1555	ALP211 = 6.0887771651e-02_wp
1556	ALP021 = 2.6149576513e-01_wp
1557	ALP121 = -1.6671866715e-02_wp
1558	ALP031 = -5.9503008642e-02_wp
1559	ALP002 = -5.4590812035e-02_wp
1560	ALP102 = 8.6134185799e-03_wp
1561	ALP012 = 6.2740815484e-02_wp
1562	ALP003 = -9.5765341718e-03_wp
1563	!
1564	BET000 = 2.1420623987_wp
1565	BET100 = -9.3752598635_wp
1566	BET200 = 1.9446303907e+01_wp
1567	BET300 = -1.8632235232e+01_wp
1568	BET400 = 8.9390837485_wp
1569	BET500 = -1.7142465871_wp
1570	BET010 = -1.7059677327e-01_wp
1571	BET110 = 2.2119589983e-01_wp
1572	BET210 = -2.7123520642e-01_wp
1573	BET310 = 7.3872053057e-02_wp
1574	BET410 = 1.2522950346e-02_wp
1575	BET020 = 3.0054390409e-01_wp
1576	BET120 = -4.2018759976e-01_wp
1577	BET220 = 3.1429341406e-01_wp
1578	BET320 = -9.8855300959e-02_wp
1579	BET030 = -2.6853658626e-01_wp
1580	BET130 = 2.5272385134e-01_wp
1581	BET230 = -2.3503481790e-02_wp
1582	BET040 = 1.2627968731e-01_wp
1583	BET140 = -1.2085092158e-01_wp
1584	BET050 = 1.4394226233e-03_wp
1585	BET001 = -2.2271304375e-01_wp
1586	BET101 = 5.5453416919e-01_wp
1587	BET201 = -6.2815936268e-01_wp
1588	BET301 = 2.0601115202e-01_wp
1589	BET011 = -9.5799229402e-03_wp
1590	BET111 = 1.0286156825e-01_wp
1591	BET211 = -2.5108454043e-02_wp
1592	BET021 = -2.4333834734e-03_wp
1593	BET121 = -3.0443885826e-02_wp
1594	BET031 = 2.7786444526e-03_wp
1595	BET002 = -4.2811838287e-02_wp
1596	BET102 = 5.1355066072e-02_wp
1597	BET012 = -4.3067092900e-03_wp
1598	BET003 = -7.1548119050e-04_wp
1599	!
1600	PEN000 = -5.3743005340_wp
1601	PEN100 = 8.9085217499_wp
1602	PEN200 = -1.1090683384e+01_wp
1603	PEN300 = 8.3754581690_wp
1604	PEN400 = -2.0601115202_wp
1605	PEN010 = 7.9263222935_wp
1606	PEN110 = 3.8319691761e-01_wp
1607	PEN210 = -2.0572313651_wp
1608	PEN310 = 3.3477938724e-01_wp
1609	PEN020 = -4.9997430930_wp
1610	PEN120 = 9.7335338937e-02_wp
1611	PEN220 = 6.0887771651e-01_wp
1612	PEN030 = 1.7433051009_wp
1613	PEN130 = -1.1114577810e-01_wp
1614	PEN040 = -2.9751504321e-01_wp
1615	PEN001 = -6.9171176978e-01_wp
1616	PEN101 = 2.2832980419_wp
1617	PEN201 = -1.3694684286_wp
1618	PEN011 = -1.4557549876_wp
1619	PEN111 = 2.2969116213e-01_wp
1620	PEN021 = 8.3654420645e-01_wp
1621	PEN002 = -1.4046808820e-02_wp
1622	PEN102 = 4.2928871430e-02_wp
1623	PEN012 = -2.8729602515e-01_wp
1624	!
1625	APE000 = -1.9815805734e-01_wp
1626	APE100 = -9.5799229402e-03_wp
1627	APE200 = 5.1430784127e-02_wp
1628	APE300 = -8.3694846809e-03_wp
1629	APE010 = 2.4998715465e-01_wp
1630	APE110 = -4.8667669469e-03_wp
1631	APE210 = -3.0443885826e-02_wp
1632	APE020 = -1.3074788257e-01_wp
1633	APE120 = 8.3359333577e-03_wp
1634	APE030 = 2.9751504321e-02_wp
1635	APE001 = 3.6393874690e-02_wp
1636	APE101 = -5.7422790533e-03_wp
1637	APE011 = -4.1827210323e-02_wp
1638	APE002 = 7.1824006288e-03_wp
1639	!
1640	BPE000 = 1.1135652187e-01_wp
1641	BPE100 = -2.7726708459e-01_wp
1642	BPE200 = 3.1407968134e-01_wp
1643	BPE300 = -1.0300557601e-01_wp
1644	BPE010 = 4.7899614701e-03_wp
1645	BPE110 = -5.1430784127e-02_wp
1646	BPE210 = 1.2554227021e-02_wp
1647	BPE020 = 1.2166917367e-03_wp
1648	BPE120 = 1.5221942913e-02_wp
1649	BPE030 = -1.3893222263e-03_wp
1650	BPE001 = 2.8541225524e-02_wp
1651	BPE101 = -3.4236710714e-02_wp
1652	BPE011 = 2.8711395266e-03_wp
1653	BPE002 = 5.3661089288e-04_wp
1654	!
1655	CASE( np_seos ) !== Simplified EOS ==!
1656
1657	r1_S0 = 0.875_wp/35.16504_wp ! Used to convert CT in potential temperature when using bulk formulae (eos_pt_from_ct)
1658
1659	IF(lwp) THEN
1660	WRITE(numout,*)
1661	WRITE(numout,*) ' ==>>> use of simplified eos: '
1662	WRITE(numout,) ' rhd(dT=T-10,dS=S-35,Z) = [-a0(1+lambda1/2dT+mu1Z)*dT '
1663	WRITE(numout,) ' + b0(1+lambda2/2dT+mu2Z)dS - nudT*dS] / rau0'
1664	WRITE(numout,*) ' with the following coefficients :'
1665	WRITE(numout,*) ' thermal exp. coef. rn_a0 = ', rn_a0
1666	WRITE(numout,*) ' saline cont. coef. rn_b0 = ', rn_b0
1667	WRITE(numout,*) ' cabbeling coef. rn_lambda1 = ', rn_lambda1
1668	WRITE(numout,*) ' cabbeling coef. rn_lambda2 = ', rn_lambda2
1669	WRITE(numout,*) ' thermobar. coef. rn_mu1 = ', rn_mu1
1670	WRITE(numout,*) ' thermobar. coef. rn_mu2 = ', rn_mu2
1671	WRITE(numout,*) ' 2nd cabbel. coef. rn_nu = ', rn_nu
1672	WRITE(numout,*) ' Caution: rn_beta0=0 incompatible with ddm parameterization '
1673	ENDIF
1674	l_useCT = .TRUE. ! Use conservative temperature
1675	!
1676	CASE DEFAULT !== ERROR in neos ==!
1677	WRITE(ctmp1,*) ' bad flag value for neos = ', neos, '. You should never see this error'
1678	CALL ctl_stop( ctmp1 )
1679	!
1680	END SELECT
1681	!
1682	rau0_rcp = rau0 * rcp
1683	r1_rau0 = 1._wp / rau0
1684	r1_rcp = 1._wp / rcp
1685	r1_rau0_rcp = 1._wp / rau0_rcp
1686	!
1687	IF(lwp) THEN
1688	IF( l_useCT ) THEN
1689	WRITE(numout,*)
1690	WRITE(numout,*) ' ==>>> model uses Conservative Temperature'
1691	WRITE(numout,*) ' Important: model must be initialized with CT and SA fields'
1692	ELSE
1693	WRITE(numout,*)
1694	WRITE(numout,*) ' ==>>> model does not use Conservative Temperature'
1695	ENDIF
1696	ENDIF
1697	!
1698	IF(lwp) WRITE(numout,*)
1699	IF(lwp) WRITE(numout,*) ' Associated physical constant'
1700	IF(lwp) WRITE(numout,*) ' volumic mass of reference rau0 = ', rau0 , ' kg/m^3'
1701	IF(lwp) WRITE(numout,*) ' 1. / rau0 r1_rau0 = ', r1_rau0, ' m^3/kg'
1702	IF(lwp) WRITE(numout,*) ' ocean specific heat rcp = ', rcp , ' J/Kelvin'
1703	IF(lwp) WRITE(numout,) ' rau0 rcp rau0_rcp = ', rau0_rcp
1704	IF(lwp) WRITE(numout,) ' 1. / ( rau0 rcp ) r1_rau0_rcp = ', r1_rau0_rcp
1705	!
1706	END SUBROUTINE eos_init
1707
1708	!!======================================================================
1709	END MODULE eosbn2

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