New URL for NEMO forge! http://forge.nemo-ocean.eu

Since March 2022 along with NEMO 4.2 release, the code development moved to a self-hosted GitLab.
This present forge is now archived and remained online for history.

sbcabl.F90 in NEMO/branches/2019/dev_ASINTER-01-05_merged/src/ABL – NEMO

Context Navigation

source: NEMO/branches/2019/dev_ASINTER-01-05_merged/src/ABL/sbcabl.F90 @ 12063

Last change on this file since 12063 was 12063, checked in by gsamson, 4 years ago
dev_ASINTER-01-05_merged: update branch with dev_r11085_ASINTER-05_Brodeau_Advanced_Bulk@r12061 and trunk@r12055 + bugfix for agrif compatibility in sbcblk: sette tests with ref configs ok except ABL restartability (under investigation) (tickets #2159 and #2131)
File size: 20.5 KB

Line
1	MODULE sbcabl
2	!!======================================================================
3	!! * MODULE sbcabl *
4	!! Ocean forcing: momentum, heat and freshwater flux formulation
5	!! derived from an ABL model
6	!!=====================================================================
7	!! History : 4.0 ! 2019-03 (F. Lemarié & G. Samson) Original code
8	!!----------------------------------------------------------------------
9
10	!!----------------------------------------------------------------------
11	!! sbc_abl_init : Initialization of ABL model based on namelist options
12	!! sbc_abl : driver for the computation of momentum, heat and freshwater
13	!! fluxes over ocean via the ABL model
14	!!----------------------------------------------------------------------
15	USE abl ! ABL
16	USE par_abl ! abl parameters
17	USE ablmod
18	USE ablrst
19
20	USE phycst ! physical constants
21	USE fldread ! read input fields
22	USE sbc_oce ! Surface boundary condition: ocean fields
23	USE sbcblk ! Surface boundary condition: bulk formulae
24	USE sbcblk_phy ! Surface boundary condition: bulk formulae
25	USE dom_oce, ONLY : tmask
26	!
27	USE iom ! I/O manager library
28	USE in_out_manager ! I/O manager
29	USE lib_mpp ! distribued memory computing library
30	USE lib_fortran ! to use key_nosignedzero
31	USE timing ! Timing
32	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
33	USE prtctl ! Print control
34	#if defined key_si3
35	USE ice , ONLY : u_ice, v_ice, tm_su, ato_i ! ato_i = total open water fractional area
36	USE sbc_ice, ONLY : wndm_ice, utau_ice, vtau_ice
37	#endif
38	#if ! defined key_iomput
39	USE diawri , ONLY : dia_wri_alloc_abl
40	#endif
41	IMPLICIT NONE
42	PRIVATE
43
44	PUBLIC sbc_abl_init ! routine called in sbcmod module
45	PUBLIC sbc_abl ! routine called in sbcmod module
46
47	!! * Substitutions
48	# include "vectopt_loop_substitute.h90"
49	!!----------------------------------------------------------------------
50	!! NEMO/OPA 3.7 , NEMO-consortium (2014)
51	!! $Id: sbcabl.F90 6416 2016-04-01 12:22:17Z clem $
52	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
53	!!----------------------------------------------------------------------
54	CONTAINS
55
56	SUBROUTINE sbc_abl_init
57	!!---------------------------------------------------------------------
58	!! * ROUTINE sbc_abl_init *
59	!!
60	!! ** Purposes : - read namelist section namsbc_abl
61	!! - initialize and check parameter values
62	!! - initialize variables of ABL model
63	!!
64	!!----------------------------------------------------------------------
65	INTEGER :: ji, jj, jk, jbak, jbak_dta ! dummy loop indices
66	INTEGER :: ios, ierror, ioptio ! Local integer
67	INTEGER :: inum, indims, idimsz(4), id
68	CHARACTER(len=100) :: cn_dir, cn_dom ! Atmospheric grid directory
69	REAL(wp) :: zcff,zcff1
70	LOGICAL :: lluldl
71	NAMELIST/namsbc_abl/ cn_dir, cn_dom, cn_ablrst_in, cn_ablrst_out, &
72	& cn_ablrst_indir, cn_ablrst_outdir, &
73	& ln_hpgls_frc, ln_geos_winds, nn_dyn_restore, &
74	& rn_ldyn_min , rn_ldyn_max, rn_ltra_min, rn_ltra_max, &
75	& nn_amxl, rn_cm, rn_ct, rn_ce, rn_ceps, rn_Rod, rn_Ric, &
76	& ln_smth_pblh
77	!!---------------------------------------------------------------------
78
79	REWIND( numnam_ref ) ! Namelist namsbc_abl in reference namelist : ABL parameters
80	READ ( numnam_ref, namsbc_abl, IOSTAT = ios, ERR = 901 )
81	901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namsbc_abl in reference namelist' )
82	!
83	REWIND( numnam_cfg ) ! Namelist namsbc_abl in configuration namelist : ABL parameters
84	READ ( numnam_cfg, namsbc_abl, IOSTAT = ios, ERR = 902 )
85	902 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namsbc_abl in configuration namelist' )
86	!
87	IF(lwm) WRITE( numond, namsbc_abl )
88	!
89	! Check ABL mixing length option
90	IF( nn_amxl < 0 .OR. nn_amxl > 2 ) &
91	& CALL ctl_stop( 'abl_init : bad flag, nn_amxl must be 0, 1 or 2 ' )
92	!
93	! Check ABL dyn restore option
94	IF( nn_dyn_restore < 0 .OR. nn_dyn_restore > 2 ) &
95	& CALL ctl_stop( 'abl_init : bad flag, nn_dyn_restore must be 0, 1 or 2 ' )
96
97	!!---------------------------------------------------------------------
98	!! Control prints
99	!!---------------------------------------------------------------------
100	IF(lwp) THEN ! Control print (other namelist variable)
101	WRITE(numout,*)
102	WRITE(numout,*) ' ABL -- cn_dir = ', cn_dir
103	WRITE(numout,*) ' ABL -- cn_dom = ', cn_dom
104	IF( ln_hpgls_frc ) THEN
105	WRITE(numout,*) ' ABL -- winds forced by large-scale pressure gradient'
106	IF(ln_geos_winds) THEN
107	ln_geos_winds = .FALSE.
108	WRITE(numout,*) ' ABL -- geostrophic guide disabled (not compatible with ln_hpgls_frc = .T.)'
109	END IF
110	ELSE IF( ln_geos_winds ) THEN
111	WRITE(numout,*) ' ABL -- winds forced by geostrophic winds'
112	ELSE
113	WRITE(numout,*) ' ABL -- Geostrophic winds and large-scale pressure gradient are ignored'
114	END IF
115	!
116	SELECT CASE ( nn_dyn_restore )
117	CASE ( 0 )
118	WRITE(numout,*) ' ABL -- No restoring for ABL winds'
119	CASE ( 1 )
120	WRITE(numout,*) ' ABL -- Restoring of ABL winds only in the equatorial region '
121	CASE ( 2 )
122	WRITE(numout,*) ' ABL -- Restoring of ABL winds activated everywhere '
123	END SELECT
124	!
125	IF( ln_smth_pblh ) WRITE(numout,*) ' ABL -- Smoothing of PBL height is activated'
126	!
127	ENDIF
128
129	!!---------------------------------------------------------------------
130	!! Convert nudging coefficient from hours to 1/sec
131	!!---------------------------------------------------------------------
132	zcff = 1._wp / 3600._wp
133	rn_ldyn_min = zcff / rn_ldyn_min
134	rn_ldyn_max = zcff / rn_ldyn_max
135	rn_ltra_min = zcff / rn_ltra_min
136	rn_ltra_max = zcff / rn_ltra_max
137
138	!!---------------------------------------------------------------------
139	!! ABL grid initialization
140	!!---------------------------------------------------------------------
141	CALL iom_open( TRIM(cn_dir)//TRIM(cn_dom), inum )
142	id = iom_varid( inum, 'e3t_abl', kdimsz=idimsz, kndims=indims, lduld=lluldl )
143	jpka = idimsz(indims - COUNT( (/lluldl/) ) )
144	jpkam1 = jpka - 1
145
146	IF( abl_alloc() /= 0 ) CALL ctl_stop( 'STOP', 'abl_init : unable to allocate arrays' )
147	CALL iom_get( inum, jpdom_unknown, 'e3t_abl', e3t_abl(:) )
148	CALL iom_get( inum, jpdom_unknown, 'e3w_abl', e3w_abl(:) )
149	CALL iom_get( inum, jpdom_unknown, 'ght_abl', ght_abl(:) )
150	CALL iom_get( inum, jpdom_unknown, 'ghw_abl', ghw_abl(:) )
151	CALL iom_close( inum )
152
153	#if ! defined key_iomput
154	IF( dia_wri_alloc_abl() /= 0 ) CALL ctl_stop( 'STOP', 'abl_init : unable to allocate arrays' )
155	#endif
156
157	IF(lwp) THEN
158	WRITE(numout,*)
159	WRITE(numout,*) ' sbc_abl_init : ABL Reference vertical grid'
160	WRITE(numout,*) ' ~~~~~~~'
161	WRITE(numout, "(9x,' level ght_abl ghw_abl e3t_abl e3w_abl ')" )
162	WRITE(numout, "(10x, i4, 4f9.2)" ) ( jk, ght_abl(jk), ghw_abl(jk), e3t_abl(jk), e3w_abl(jk), jk = 1, jpka )
163	END IF
164
165	!!---------------------------------------------------------------------
166	!! Check TKE closure parameters
167	!!---------------------------------------------------------------------
168	rn_Sch = rn_ce / rn_cm
169	mxl_min = (avm_bak / rn_cm) / sqrt( tke_min )
170
171	IF(lwp) THEN
172	WRITE(numout,*)
173	WRITE(numout,*) ' abl_zdf_tke : ABL TKE turbulent closure'
174	WRITE(numout,*) ' ~~~~~~~~~~~'
175	IF(nn_amxl==0) WRITE(numout,*) 'Deardorff 80 length-scale '
176	IF(nn_amxl==1) WRITE(numout,*) 'length-scale based on the distance to the PBL height '
177	WRITE(numout,*) ' Minimum value of atmospheric TKE = ',tke_min,' m^2 s^-2'
178	WRITE(numout,*) ' Minimum value of atmospheric mixing length = ',mxl_min,' m'
179	WRITE(numout,*) ' Constant for turbulent viscosity = ',rn_Cm
180	WRITE(numout,*) ' Constant for turbulent diffusivity = ',rn_Ct
181	WRITE(numout,*) ' Constant for Schmidt number = ',rn_Sch
182	WRITE(numout,*) ' Constant for TKE dissipation = ',rn_Ceps
183	END IF
184
185	!!-------------------------------------------------------------------------------------------
186	!! Compute parameters to build the vertical profile for the nudging term (used in abl_stp())
187	!!-------------------------------------------------------------------------------------------
188	zcff1 = 1._wp / ( jp_bmax - jp_bmin )**3
189	! for active tracers
190	jp_alp3_tra = -2._wp * zcff1 * ( rn_ltra_max - rn_ltra_min )
191	jp_alp2_tra = 3._wp * zcff1 * (jp_bmax + jp_bmin) * ( rn_ltra_max - rn_ltra_min )
192	jp_alp1_tra = -6._wp * zcff1 * jp_bmax * jp_bmin * ( rn_ltra_max - rn_ltra_min )
193	jp_alp0_tra = zcff1 * ( rn_ltra_max * jp_bminjp_bmin (3._wp*jp_bmax - jp_bmin) &
194	& - rn_ltra_min * jp_bmaxjp_bmax (3._wp*jp_bmin - jp_bmax) )
195	! for dynamics
196	jp_alp3_dyn = -2._wp * zcff1 * ( rn_ldyn_max - rn_ldyn_min )
197	jp_alp2_dyn = 3._wp * zcff1 * (jp_bmax + jp_bmin) * ( rn_ldyn_max - rn_ldyn_min )
198	jp_alp1_dyn = -6._wp * zcff1 * jp_bmax * jp_bmin * ( rn_ldyn_max - rn_ldyn_min )
199	jp_alp0_dyn = zcff1 * ( rn_ldyn_max * jp_bminjp_bmin (3._wp*jp_bmax - jp_bmin) &
200	& - rn_ldyn_min * jp_bmaxjp_bmax (3._wp*jp_bmin - jp_bmax) )
201
202	jp_pblh_min = ghw_abl( 4) / jp_bmin !<-- at least 3 grid points at the bottom have value rn_ltra_min
203	jp_pblh_max = ghw_abl(jpka-3) / jp_bmax !<-- at least 3 grid points at the top have value rn_ltra_max
204
205	! ABL timestep
206	rdt_abl = nn_fsbc * rdt
207
208	! Check parameters for dynamics
209	zcff = ( jp_alp3_dyn * jp_bmin*3 + jp_alp2_dyn jp_bmin**2 &
210	& + jp_alp1_dyn * jp_bmin + jp_alp0_dyn ) * rdt_abl
211	zcff1 = ( jp_alp3_dyn * jp_bmax*3 + jp_alp2_dyn jp_bmax**2 &
212	& + jp_alp1_dyn * jp_bmax + jp_alp0_dyn ) * rdt_abl
213	IF(lwp) THEN
214	IF(nn_dyn_restore > 0) THEN
215	WRITE(numout,*) ' ABL Minimum value for dynamics restoring = ',zcff
216	WRITE(numout,*) ' ABL Maximum value for dynamics restoring = ',zcff1
217	! Check that restoring coefficients are between 0 and 1
218	IF( zcff1 - nn_fsbc > 0.001_wp .OR. zcff1 < 0._wp ) &
219	& CALL ctl_stop( 'abl_init : wrong value for rn_ldyn_max' )
220	IF( zcff - nn_fsbc > 0.001_wp .OR. zcff < 0._wp ) &
221	& CALL ctl_stop( 'abl_init : wrong value for rn_ldyn_min' )
222	IF( zcff > zcff1 ) &
223	& CALL ctl_stop( 'abl_init : rn_ldyn_max must be smaller than rn_ldyn_min' )
224	END IF
225	END IF
226
227	! Check parameters for active tracers
228	zcff = ( jp_alp3_tra * jp_bmin*3 + jp_alp2_tra jp_bmin**2 &
229	& + jp_alp1_tra * jp_bmin + jp_alp0_tra ) * rdt_abl
230	zcff1 = ( jp_alp3_tra * jp_bmax*3 + jp_alp2_tra jp_bmax**2 &
231	& + jp_alp1_tra * jp_bmax + jp_alp0_tra ) * rdt_abl
232	IF(lwp) THEN
233	WRITE(numout,*) ' ABL Minimum value for tracers restoring = ',zcff
234	WRITE(numout,*) ' ABL Maximum value for tracers restoring = ',zcff1
235	! Check that restoring coefficients are between 0 and 1
236	IF( zcff1 - nn_fsbc > 0.001_wp .OR. zcff1 < 0._wp ) &
237	& CALL ctl_stop( 'abl_init : wrong value for rn_ltra_max' )
238	IF( zcff - nn_fsbc > 0.001_wp .OR. zcff < 0._wp ) &
239	& CALL ctl_stop( 'abl_init : wrong value for rn_ltra_min' )
240	IF( zcff > zcff1 ) &
241	& CALL ctl_stop( 'abl_init : rn_ltra_max must be smaller than rn_ltra_min' )
242	END IF
243
244	!!-------------------------------------------------------------------------------------------
245	!! Initialize Coriolis frequency, equatorial restoring and land/sea mask
246	!!-------------------------------------------------------------------------------------------
247	fft_abl(:,:) = 2._wp * omega * SIN( rad * gphit(:,:) )
248
249	! Equatorial restoring
250	IF( nn_dyn_restore == 1 ) THEN
251	zcff = 2._wp * omega * SIN( rad * 90._wp ) !++ fmax
252	rest_eq(:,:) = SIN( 0.5_wprpi( (fft_abl(:,:) - zcff) / zcff ) )**8
253	!!GS: alternative shape
254	!rest_eq(:,:) = SIN( 0.5_wprpi(zcff - ABS(ff_t(:,:))) / (zcff - 3.e-5) )**8
255	!WHERE(ABS(ff_t(:,:)).LE.3.e-5) rest_eq(:,:) = 1._wp
256	ELSE
257	rest_eq(:,:) = 1._wp
258	END IF
259	! T-mask
260	msk_abl(:,:) = tmask(:,:,1)
261
262	!!-------------------------------------------------------------------------------------------
263
264	! initialize 2D bulk fields AND 3D abl data
265	CALL sbc_blk_init
266
267	! Initialize the time index for now time (nt_n) and after time (nt_a)
268	nt_n = 1 + MOD( nit000 , 2)
269	nt_a = 1 + MOD( nit000+1, 2)
270
271	! initialize ABL from data or restart
272	IF( ln_rstart ) THEN
273	CALL abl_rst_read
274	ELSE
275	CALL fld_read( nit000, nn_fsbc, sf ) ! input fields provided at the first time-step
276
277	u_abl(:,:,:,nt_n ) = sf(jp_wndi)%fnow(:,:,:)
278	v_abl(:,:,:,nt_n ) = sf(jp_wndj)%fnow(:,:,:)
279	tq_abl(:,:,:,nt_n,jp_ta) = sf(jp_tair)%fnow(:,:,:)
280	tq_abl(:,:,:,nt_n,jp_qa) = sf(jp_humi)%fnow(:,:,:)
281
282	tke_abl(:,:,:,nt_n ) = tke_min
283	avm_abl(:,:,: ) = avm_bak
284	avt_abl(:,:,: ) = avt_bak
285	mxl_abl(:,:,: ) = mxl_min
286	pblh (:,: ) = ghw_abl( 3 ) !<-- assume that the pbl contains 3 grid points
287	u_abl (:,:,:,nt_a ) = 0._wp
288	v_abl (:,:,:,nt_a ) = 0._wp
289	tq_abl (:,:,:,nt_a,: ) = 0._wp
290	tke_abl(:,:,:,nt_a ) = 0._wp
291	ENDIF
292
293	rhoa(:,:) = rho_air( tq_abl(:,:,2,nt_n,jp_ta), tq_abl(:,:,2,nt_n,jp_qa), sf(jp_slp)%fnow(:,:,1) ) !!GS: rhoa must be (re)computed here here to avoid division by zero in blk_ice_1 (TBI)
294
295	END SUBROUTINE sbc_abl_init
296
297
298	SUBROUTINE sbc_abl( kt )
299	!!---------------------------------------------------------------------
300	!! * ROUTINE sbc_abl *
301	!!
302	!! ** Purpose : provide the momentum, heat and freshwater fluxes at
303	!! the ocean surface from an ABL calculation at each oceanic time step
304	!!
305	!! ** Method :
306	!! - Pre-compute part of turbulent fluxes in blk_oce_1
307	!! - Perform 1 time-step of the ABL model
308	!! - Finalize flux computation in blk_oce_2
309	!!
310	!! ** Outputs : - utau : i-component of the stress at U-point (N/m2)
311	!! - vtau : j-component of the stress at V-point (N/m2)
312	!! - taum : Wind stress module at T-point (N/m2)
313	!! - wndm : Wind speed module at T-point (m/s)
314	!! - qsr : Solar heat flux over the ocean (W/m2)
315	!! - qns : Non Solar heat flux over the ocean (W/m2)
316	!! - emp : evaporation minus precipitation (kg/m2/s)
317	!!
318	!!---------------------------------------------------------------------
319	INTEGER , INTENT(in) :: kt ! ocean time step
320	!!
321	REAL(wp), DIMENSION(jpi,jpj) :: zssq, zcd_du, zsen, zevp
322	#if defined key_si3
323	REAL(wp), DIMENSION(jpi,jpj) :: zssqi, zcd_dui, zseni, zevpi
324	#endif
325	INTEGER :: jbak, jbak_dta, ji, jj
326	!!---------------------------------------------------------------------
327	!
328	!!-------------------------------------------------------------------------------------------
329	!! 1 - Read Atmospheric 3D data for large-scale forcing
330	!!-------------------------------------------------------------------------------------------
331
332	CALL fld_read( kt, nn_fsbc, sf ) ! input fields provided at the current time-step
333
334	!!-------------------------------------------------------------------------------------------
335	!! 2 - Compute Cd x \|\|U\|\|, Ch x \|\|U\|\|, Ce x \|\|U\|\|, and SSQ using now fields
336	!!-------------------------------------------------------------------------------------------
337
338	CALL blk_oce_1( kt, u_abl(:,:,2,nt_n ), v_abl(:,:,2,nt_n ), & ! <<= in
339	& tq_abl(:,:,2,nt_n,jp_ta), tq_abl(:,:,2,nt_n,jp_qa), & ! <<= in
340	& sf(jp_slp )%fnow(:,:,1) , sst_m, ssu_m, ssv_m , & ! <<= in
341	& sf(jp_qsr )%fnow(:,:,1) , sf(jp_qlw )%fnow(:,:,1) , & ! <<= in
342	& zssq, zcd_du, zsen, zevp ) ! =>> out
343
344	#if defined key_si3
345	CALL blk_ice_1( u_abl(:,:,2,nt_n ), v_abl(:,:,2,nt_n ), & ! <<= in
346	& tq_abl(:,:,2,nt_n,jp_ta), tq_abl(:,:,2,nt_n,jp_qa), & ! <<= in
347	& sf(jp_slp)%fnow(:,:,1) , u_ice, v_ice, tm_su , & ! <<= in
348	& pseni=zseni, pevpi=zevpi, pssqi=zssqi, pcd_dui=zcd_dui ) ! <<= out
349	#endif
350
351	!!-------------------------------------------------------------------------------------------
352	!! 3 - Advance ABL variables from now (n) to after (n+1)
353	!!-------------------------------------------------------------------------------------------
354
355	CALL abl_stp( kt, sst_m, ssu_m, ssv_m, zssq, & ! <<= in
356	& sf(jp_wndi)%fnow(:,:,:), sf(jp_wndj)%fnow(:,:,:), & ! <<= in
357	& sf(jp_tair)%fnow(:,:,:), sf(jp_humi)%fnow(:,:,:), & ! <<= in
358	& sf(jp_slp )%fnow(:,:,1), & ! <<= in
359	& sf(jp_hpgi)%fnow(:,:,:), sf(jp_hpgj)%fnow(:,:,:), & ! <<= in
360	& zcd_du, zsen, zevp, & ! <=> in/out
361	& wndm, utau, vtau, taum & ! =>> out
362	#if defined key_si3
363	& , tm_su, u_ice, v_ice, zssqi, zcd_dui & ! <<= in
364	& , zseni, zevpi, wndm_ice, ato_i & ! <<= in
365	& , utau_ice, vtau_ice & ! =>> out
366	#endif
367	& )
368	!!-------------------------------------------------------------------------------------------
369	!! 4 - Finalize flux computation using ABL variables at (n+1), nt_n corresponds to (n+1) since
370	!! time swap is done in abl_stp
371	!!-------------------------------------------------------------------------------------------
372
373	CALL blk_oce_2( tq_abl(:,:,2,nt_n,jp_ta), &
374	& sf(jp_qsr )%fnow(:,:,1) , sf(jp_qlw )%fnow(:,:,1), &
375	& sf(jp_prec)%fnow(:,:,1) , sf(jp_snow)%fnow(:,:,1), &
376	& sst_m, zsen, zevp )
377
378	CALL abl_rst_opn( kt ) ! Open abl restart file (if necessary)
379	IF( lrst_abl ) CALL abl_rst_write( kt ) ! -- abl restart file
380
381	#if defined key_si3
382	! Avoid a USE abl in icesbc module
383	sf(jp_tair)%fnow(:,:,1) = tq_abl(:,:,2,nt_n,jp_ta); sf(jp_humi)%fnow(:,:,1) = tq_abl(:,:,2,nt_n,jp_qa)
384	#endif
385
386	END SUBROUTINE sbc_abl
387
388	!!======================================================================
389	END MODULE sbcabl

Note: See TracBrowser for help on using the repository browser.

Download in other formats: