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p4zsink.F90 in branches/2012/dev_r3385_NOCS04_HAMF/NEMOGCM/NEMO/TOP_SRC/PISCES – NEMO

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source: branches/2012/dev_r3385_NOCS04_HAMF/NEMOGCM/NEMO/TOP_SRC/PISCES/p4zsink.F90 @ 3524

Last change on this file since 3524 was 3524, checked in by gm, 11 years ago
Branch: dev_r3385_NOCS04_HAMF; #665. add USE lib_fortran when SIGN is used (TOP,OPA,LIM2&3) ; salt flux names start with sfx_ in LIM3
Property svn:keywords set to `Id`
File size: 33.1 KB

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1	MODULE p4zsink
2	!!======================================================================
3	!! * MODULE p4zsink *
4	!! TOP : PISCES vertical flux of particulate matter due to gravitational sinking
5	!!======================================================================
6	!! History : 1.0 ! 2004 (O. Aumont) Original code
7	!! 2.0 ! 2007-12 (C. Ethe, G. Madec) F90
8	!! 3.4 ! 2011-06 (O. Aumont, C. Ethe) Change aggregation formula
9	!!----------------------------------------------------------------------
10	#if defined key_pisces
11	!!----------------------------------------------------------------------
12	!! p4z_sink : Compute vertical flux of particulate matter due to gravitational sinking
13	!! p4z_sink_init : Unitialisation of sinking speed parameters
14	!! p4z_sink_alloc : Allocate sinking speed variables
15	!!----------------------------------------------------------------------
16	USE oce_trc ! shared variables between ocean and passive tracers
17	USE trc ! passive tracers common variables
18	USE sms_pisces ! PISCES Source Minus Sink variables
19	USE prtctl_trc ! print control for debugging
20	USE iom ! I/O manager
21	USE lib_fortran ! Fortran utilities (allows no signed zero when 'key_nosignedzero' defined)
22
23	IMPLICIT NONE
24	PRIVATE
25
26	PUBLIC p4z_sink ! called in p4zbio.F90
27	PUBLIC p4z_sink_init ! called in trcsms_pisces.F90
28	PUBLIC p4z_sink_alloc
29
30	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: wsbio3 !: POC sinking speed
31	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: wsbio4 !: GOC sinking speed
32	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: wscal !: Calcite and BSi sinking speeds
33
34	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: sinking, sinking2 !: POC sinking fluxes
35	! ! (different meanings depending on the parameterization)
36	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: sinkcal, sinksil !: CaCO3 and BSi sinking fluxes
37	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: sinkfer !: Small BFe sinking fluxes
38	#if ! defined key_kriest
39	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: sinkfer2 !: Big iron sinking fluxes
40	#endif
41
42	INTEGER :: iksed = 10
43
44	#if defined key_kriest
45	REAL(wp) :: xkr_sfact = 250. !: Sinking factor
46	REAL(wp) :: xkr_stick = 0.2 !: Stickiness
47	REAL(wp) :: xkr_nnano = 2.337 !: Nbr of cell in nano size class
48	REAL(wp) :: xkr_ndiat = 3.718 !: Nbr of cell in diatoms size class
49	REAL(wp) :: xkr_nmeso = 7.147 !: Nbr of cell in mesozoo size class
50	REAL(wp) :: xkr_naggr = 9.877 !: Nbr of cell in aggregates size class
51
52	REAL(wp) :: xkr_frac
53
54	REAL(wp), PUBLIC :: xkr_dnano !: Size of particles in nano pool
55	REAL(wp), PUBLIC :: xkr_ddiat !: Size of particles in diatoms pool
56	REAL(wp), PUBLIC :: xkr_dmeso !: Size of particles in mesozoo pool
57	REAL(wp), PUBLIC :: xkr_daggr !: Size of particles in aggregates pool
58	REAL(wp), PUBLIC :: xkr_wsbio_min !: min vertical particle speed
59	REAL(wp), PUBLIC :: xkr_wsbio_max !: max vertical particle speed
60
61	REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:) :: xnumm !: maximum number of particles in aggregates
62	#endif
63
64	!!* Substitution
65	# include "top_substitute.h90"
66	!!----------------------------------------------------------------------
67	!! NEMO/TOP 3.3 , NEMO Consortium (2010)
68	!! $Id$
69	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
70	!!----------------------------------------------------------------------
71	CONTAINS
72
73	#if defined key_kriest
74	!!----------------------------------------------------------------------
75	!! 'key_kriest' ???
76	!!----------------------------------------------------------------------
77
78	SUBROUTINE p4z_sink ( kt, jnt )
79	!!---------------------------------------------------------------------
80	!! * ROUTINE p4z_sink *
81	!!
82	!! ** Purpose : Compute vertical flux of particulate matter due to
83	!! gravitational sinking - Kriest parameterization
84	!!
85	!! ** Method : - ???
86	!!---------------------------------------------------------------------
87	!
88	INTEGER, INTENT(in) :: kt, jnt
89	!
90	INTEGER :: ji, jj, jk
91	REAL(wp) :: zagg1, zagg2, zagg3, zagg4, zagg5, zaggsi, zaggsh
92	REAL(wp) :: zagg , zaggdoc, znumdoc
93	REAL(wp) :: znum , zeps, zfm, zgm, zsm
94	REAL(wp) :: zdiv , zdiv1, zdiv2, zdiv3, zdiv4, zdiv5
95	REAL(wp) :: zval1, zval2, zval3, zval4
96	REAL(wp) :: zrfact2
97	INTEGER :: ik1
98	CHARACTER (len=25) :: charout
99	REAL(wp), POINTER, DIMENSION(:,:,:) :: znum3d
100	!!---------------------------------------------------------------------
101	!
102	IF( nn_timing == 1 ) CALL timing_start('p4z_sink')
103	!
104	CALL wrk_alloc( jpi, jpj, jpk, znum3d )
105	!
106	! Initialisation of variables used to compute Sinking Speed
107	! ---------------------------------------------------------
108
109	znum3d(:,:,:) = 0.e0
110	zval1 = 1. + xkr_zeta
111	zval2 = 1. + xkr_zeta + xkr_eta
112	zval3 = 1. + xkr_eta
113
114	! Computation of the vertical sinking speed : Kriest et Evans, 2000
115	! -----------------------------------------------------------------
116
117	DO jk = 1, jpkm1
118	DO jj = 1, jpj
119	DO ji = 1, jpi
120	IF( tmask(ji,jj,jk) /= 0.e0 ) THEN
121	znum = trn(ji,jj,jk,jppoc) / ( trn(ji,jj,jk,jpnum) + rtrn ) / xkr_massp
122	! -------------- To avoid sinking speed over 50 m/day -------
123	znum = MIN( xnumm(jk), znum )
124	znum = MAX( 1.1 , znum )
125	znum3d(ji,jj,jk) = znum
126	!------------------------------------------------------------
127	zeps = ( zval1 * znum - 1. )/ ( znum - 1. )
128	zfm = xkr_frac**( 1. - zeps )
129	zgm = xkr_frac**( zval1 - zeps )
130	zdiv = MAX( 1.e-4, ABS( zeps - zval2 ) ) * SIGN( 1., ( zeps - zval2 ) )
131	zdiv1 = zeps - zval3
132	wsbio3(ji,jj,jk) = xkr_wsbio_min * ( zeps - zval1 ) / zdiv &
133	& - xkr_wsbio_max * zgm * xkr_eta / zdiv
134	wsbio4(ji,jj,jk) = xkr_wsbio_min * ( zeps-1. ) / zdiv1 &
135	& - xkr_wsbio_max * zfm * xkr_eta / zdiv1
136	IF( znum == 1.1) wsbio3(ji,jj,jk) = wsbio4(ji,jj,jk)
137	ENDIF
138	END DO
139	END DO
140	END DO
141
142	wscal(:,:,:) = MAX( wsbio3(:,:,:), 50._wp )
143
144	! INITIALIZE TO ZERO ALL THE SINKING ARRAYS
145	! -----------------------------------------
146
147	sinking (:,:,:) = 0.e0
148	sinking2(:,:,:) = 0.e0
149	sinkcal (:,:,:) = 0.e0
150	sinkfer (:,:,:) = 0.e0
151	sinksil (:,:,:) = 0.e0
152
153	! Compute the sedimentation term using p4zsink2 for all the sinking particles
154	! -----------------------------------------------------
155
156	CALL p4z_sink2( wsbio3, sinking , jppoc )
157	CALL p4z_sink2( wsbio4, sinking2, jpnum )
158	CALL p4z_sink2( wsbio3, sinkfer , jpsfe )
159	CALL p4z_sink2( wscal , sinksil , jpgsi )
160	CALL p4z_sink2( wscal , sinkcal , jpcal )
161
162	! Exchange between organic matter compartments due to coagulation/disaggregation
163	! ---------------------------------------------------
164
165	zval1 = 1. + xkr_zeta
166	zval2 = 1. + xkr_eta
167	zval3 = 3. + xkr_eta
168	zval4 = 4. + xkr_eta
169
170	DO jk = 1,jpkm1
171	DO jj = 1,jpj
172	DO ji = 1,jpi
173	IF( tmask(ji,jj,jk) /= 0.e0 ) THEN
174
175	znum = trn(ji,jj,jk,jppoc)/(trn(ji,jj,jk,jpnum)+rtrn) / xkr_massp
176	!-------------- To avoid sinking speed over 50 m/day -------
177	znum = min(xnumm(jk),znum)
178	znum = MAX( 1.1,znum)
179	!------------------------------------------------------------
180	zeps = ( zval1 * znum - 1.) / ( znum - 1.)
181	zdiv = MAX( 1.e-4, ABS( zeps - zval3) ) * SIGN( 1., zeps - zval3 )
182	zdiv1 = MAX( 1.e-4, ABS( zeps - 4. ) ) * SIGN( 1., zeps - 4. )
183	zdiv2 = zeps - 2.
184	zdiv3 = zeps - 3.
185	zdiv4 = zeps - zval2
186	zdiv5 = 2.* zeps - zval4
187	zfm = xkr_frac**( 1.- zeps )
188	zsm = xkr_frac**xkr_eta
189
190	! Part I : Coagulation dependant on turbulence
191	! ----------------------------------------------
192
193	zagg1 = ( 0.163 * trn(ji,jj,jk,jpnum)**2 &
194	& * 2.( (zfm-1.)(zfmxkr_mass_max3-xkr_mass_min*3) &
195	& * (zeps-1)/zdiv1 + 3.(zfmxkr_mass_max-xkr_mass_min) &
196	& * (zfmxkr_mass_max2-xkr_mass_min*2) &
197	& * (zeps-1.)*2/(zdiv2zdiv3))
198	zagg2 = 20.163trn(ji,jj,jk,jpnum)*2zfm* &
199	& ((xkr_mass_max*3+3.(xkr_mass_max**2 &
200	& xkr_mass_min(zeps-1.)/zdiv2 &
201	& +xkr_mass_maxxkr_mass_min2(zeps-1.)/zdiv3) &
202	& +xkr_mass_min*3(zeps-1)/zdiv1) &
203	& -zfmxkr_mass_max3(1.+3.*((zeps-1.)/ &
204	& (zeps-2.)+(zeps-1.)/zdiv3)+(zeps-1.)/zdiv1))
205
206	zagg3 = 0.163trn(ji,jj,jk,jpnum)2zfm*28. * xkr_mass_max**3
207
208	! Aggregation of small into large particles
209	! Part II : Differential settling
210	! ----------------------------------------------
211
212	zagg4 = 2.3.1410.125trn(ji,jj,jk,jpnum)2 &
213	& xkr_wsbio_min(zeps-1.)*2 &
214	& (xkr_mass_min2((1.-zsmzfm)/(zdiv3zdiv4) &
215	& -(1.-zfm)/(zdiv*(zeps-1.)))- &
216	& ((zfmzfmxkr_mass_max*2zsm-xkr_mass_min**2) &
217	& xkr_eta)/(zdivzdiv3*zdiv5) )
218
219	zagg5 = 2.3.1410.125trn(ji,jj,jk,jpnum)*2 &
220	& (zeps-1.)zfm*xkr_wsbio_min &
221	& (zsm(xkr_mass_min*2-zfmxkr_mass_max**2) &
222	& /zdiv3-(xkr_mass_min*2-zfmzsmxkr_mass_max*2) &
223	& /zdiv)
224	zaggsi = ( zagg4 + zagg5 ) * xstep / 10.
225
226	zagg = 0.5 * xkr_stick * ( zaggsh + zaggsi )
227
228	! Aggregation of DOC to small particles
229	! --------------------------------------
230
231	zaggdoc = ( 0.4 * trn(ji,jj,jk,jpdoc) &
232	& + 1018. * trn(ji,jj,jk,jppoc) ) * xstep &
233	& * xdiss(ji,jj,jk) * trn(ji,jj,jk,jpdoc)
234
235	# if defined key_degrad
236	zagg1 = zagg1 * facvol(ji,jj,jk)
237	zagg2 = zagg2 * facvol(ji,jj,jk)
238	zagg3 = zagg3 * facvol(ji,jj,jk)
239	zagg4 = zagg4 * facvol(ji,jj,jk)
240	zagg5 = zagg5 * facvol(ji,jj,jk)
241	zaggdoc = zaggdoc * facvol(ji,jj,jk)
242	# endif
243	zaggsh = ( zagg1 + zagg2 + zagg3 ) * rfact2 * xdiss(ji,jj,jk) / 1000.
244	zaggsi = ( zagg4 + zagg5 ) * xstep / 10.
245	zagg = 0.5 * xkr_stick * ( zaggsh + zaggsi )
246	!
247	znumdoc = trn(ji,jj,jk,jpnum) / ( trn(ji,jj,jk,jppoc) + rtrn )
248	tra(ji,jj,jk,jppoc) = tra(ji,jj,jk,jppoc) + zaggdoc
249	tra(ji,jj,jk,jpnum) = tra(ji,jj,jk,jpnum) + zaggdoc * znumdoc - zagg
250	tra(ji,jj,jk,jpdoc) = tra(ji,jj,jk,jpdoc) - zaggdoc
251
252	ENDIF
253	END DO
254	END DO
255	END DO
256
257	IF( ln_diatrc ) THEN
258	!
259	ik1 = iksed + 1
260	zrfact2 = 1.e3 * rfact2r
261	IF( jnt == nrdttrc ) THEN
262	CALL iom_put( "POCFlx" , sinking (:,:,:) * zrfact2 * tmask(:,:,:) ) ! POC export
263	CALL iom_put( "NumFlx" , sinking2 (:,:,:) * zrfact2 * tmask(:,:,:) ) ! Num export
264	CALL iom_put( "SiFlx" , sinksil (:,:,:) * zrfact2 * tmask(:,:,:) ) ! Silica export
265	CALL iom_put( "CaCO3Flx", sinkcal (:,:,:) * zrfact2 * tmask(:,:,:) ) ! Calcite export
266	CALL iom_put( "xnum" , znum3d (:,:,:) * tmask(:,:,:) ) ! Number of particles in aggregats
267	CALL iom_put( "W1" , wsbio3 (:,:,:) * tmask(:,:,:) ) ! sinking speed of POC
268	CALL iom_put( "W2" , wsbio4 (:,:,:) * tmask(:,:,:) ) ! sinking speed of aggregats
269	CALL iom_put( "PMO" , sinking (:,:,ik1) * zrfact2 * tmask(:,:,1) ) ! POC export at 100m
270	CALL iom_put( "PMO2" , sinking2(:,:,ik1) * zrfact2 * tmask(:,:,1) ) ! Num export at 100m
271	CALL iom_put( "ExpFe1" , sinkfer (:,:,ik1) * zrfact2 * tmask(:,:,1) ) ! Export of iron at 100m
272	CALL iom_put( "ExpSi" , sinksil (:,:,ik1) * zrfact2 * tmask(:,:,1) ) ! export of silica at 100m
273	CALL iom_put( "ExpCaCO3", sinkcal (:,:,ik1) * zrfact2 * tmask(:,:,1) ) ! export of calcite at 100m
274	ENDIF
275	# if ! defined key_iomput
276	trc2d(:,: ,jp_pcs0_2d + 4) = sinking (:,:,ik1) * zrfact2 * tmask(:,:,1)
277	trc2d(:,: ,jp_pcs0_2d + 5) = sinking2(:,:,ik1) * zrfact2 * tmask(:,:,1)
278	trc2d(:,: ,jp_pcs0_2d + 6) = sinkfer (:,:,ik1) * zrfact2 * tmask(:,:,1)
279	trc2d(:,: ,jp_pcs0_2d + 7) = sinksil (:,:,ik1) * zrfact2 * tmask(:,:,1)
280	trc2d(:,: ,jp_pcs0_2d + 8) = sinkcal (:,:,ik1) * zrfact2 * tmask(:,:,1)
281	trc3d(:,:,:,jp_pcs0_3d + 11) = sinking (:,:,:) * zrfact2 * tmask(:,:,:)
282	trc3d(:,:,:,jp_pcs0_3d + 12) = sinking2(:,:,:) * zrfact2 * tmask(:,:,:)
283	trc3d(:,:,:,jp_pcs0_3d + 13) = sinksil (:,:,:) * zrfact2 * tmask(:,:,:)
284	trc3d(:,:,:,jp_pcs0_3d + 14) = sinkcal (:,:,:) * zrfact2 * tmask(:,:,:)
285	trc3d(:,:,:,jp_pcs0_3d + 15) = znum3d (:,:,:) * tmask(:,:,:)
286	trc3d(:,:,:,jp_pcs0_3d + 16) = wsbio3 (:,:,:) * tmask(:,:,:)
287	trc3d(:,:,:,jp_pcs0_3d + 17) = wsbio4 (:,:,:) * tmask(:,:,:)
288	# endif
289	!
290	ENDIF
291	!
292	IF(ln_ctl) THEN ! print mean trends (used for debugging)
293	WRITE(charout, FMT="('sink')")
294	CALL prt_ctl_trc_info(charout)
295	CALL prt_ctl_trc(tab4d=tra, mask=tmask, clinfo=ctrcnm)
296	ENDIF
297	!
298	CALL wrk_alloc( jpi, jpj, jpk, znum3d )
299	!
300	IF( nn_timing == 1 ) CALL timing_stop('p4z_sink')
301	!
302	END SUBROUTINE p4z_sink
303
304
305	SUBROUTINE p4z_sink_init
306	!!----------------------------------------------------------------------
307	!! * ROUTINE p4z_sink_init *
308	!!
309	!! ** Purpose : Initialization of sinking parameters
310	!! Kriest parameterization only
311	!!
312	!! ** Method : Read the nampiskrs namelist and check the parameters
313	!! called at the first timestep
314	!!
315	!! ** input : Namelist nampiskrs
316	!!----------------------------------------------------------------------
317	INTEGER :: jk, jn, kiter
318	REAL(wp) :: znum, zdiv
319	REAL(wp) :: zws, zwr, zwl,wmax, znummax
320	REAL(wp) :: zmin, zmax, zl, zr, xacc
321	!
322	NAMELIST/nampiskrs/ xkr_sfact, xkr_stick , &
323	& xkr_nnano, xkr_ndiat, xkr_nmeso, xkr_naggr
324	!!----------------------------------------------------------------------
325	!
326	IF( nn_timing == 1 ) CALL timing_start('p4z_sink_init')
327	!
328	REWIND( numnatp ) ! read nampiskrs
329	READ ( numnatp, nampiskrs )
330
331	IF(lwp) THEN
332	WRITE(numout,*)
333	WRITE(numout,*) ' Namelist : nampiskrs'
334	WRITE(numout,*) ' Sinking factor xkr_sfact = ', xkr_sfact
335	WRITE(numout,*) ' Stickiness xkr_stick = ', xkr_stick
336	WRITE(numout,*) ' Nbr of cell in nano size class xkr_nnano = ', xkr_nnano
337	WRITE(numout,*) ' Nbr of cell in diatoms size class xkr_ndiat = ', xkr_ndiat
338	WRITE(numout,*) ' Nbr of cell in mesozoo size class xkr_nmeso = ', xkr_nmeso
339	WRITE(numout,*) ' Nbr of cell in aggregates size class xkr_naggr = ', xkr_naggr
340	ENDIF
341
342
343	! max and min vertical particle speed
344	xkr_wsbio_min = xkr_sfact * xkr_mass_min**xkr_eta
345	xkr_wsbio_max = xkr_sfact * xkr_mass_max**xkr_eta
346	WRITE(numout,*) ' max and min vertical particle speed ', xkr_wsbio_min, xkr_wsbio_max
347
348	!
349	! effect of the sizes of the different living pools on particle numbers
350	! nano = 2um-20um -> mean size=6.32 um -> ws=2.596 -> xnum=xnnano=2.337
351	! diat and microzoo = 10um-200um -> 44.7 -> 8.732 -> xnum=xndiat=3.718
352	! mesozoo = 200um-2mm -> 632.45 -> 45.14 -> xnum=xnmeso=7.147
353	! aggregates = 200um-10mm -> 1414 -> 74.34 -> xnum=xnaggr=9.877
354	! doc aggregates = 1um
355	! ----------------------------------------------------------
356
357	xkr_dnano = 1. / ( xkr_massp * xkr_nnano )
358	xkr_ddiat = 1. / ( xkr_massp * xkr_ndiat )
359	xkr_dmeso = 1. / ( xkr_massp * xkr_nmeso )
360	xkr_daggr = 1. / ( xkr_massp * xkr_naggr )
361
362	!!---------------------------------------------------------------------
363	!! 'key_kriest' ???
364	!!---------------------------------------------------------------------
365	! COMPUTATION OF THE VERTICAL PROFILE OF MAXIMUM SINKING SPEED
366	! Search of the maximum number of particles in aggregates for each k-level.
367	! Bissection Method
368	!--------------------------------------------------------------------
369	WRITE(numout,*)
370	WRITE(numout,*)' kriest : Compute maximum number of particles in aggregates'
371
372	xacc = 0.001_wp
373	kiter = 50
374	zmin = 1.10_wp
375	zmax = xkr_mass_max / xkr_mass_min
376	xkr_frac = zmax
377
378	DO jk = 1,jpk
379	zl = zmin
380	zr = zmax
381	wmax = 0.5 * fse3t(1,1,jk) * rday / rfact2
382	zdiv = xkr_zeta + xkr_eta - xkr_eta * zl
383	znum = zl - 1.
384	zwl = xkr_wsbio_min * xkr_zeta / zdiv &
385	& - ( xkr_wsbio_max * xkr_eta * znum * &
386	& xkr_frac**( -xkr_zeta / znum ) / zdiv ) &
387	& - wmax
388
389	zdiv = xkr_zeta + xkr_eta - xkr_eta * zr
390	znum = zr - 1.
391	zwr = xkr_wsbio_min * xkr_zeta / zdiv &
392	& - ( xkr_wsbio_max * xkr_eta * znum * &
393	& xkr_frac**( -xkr_zeta / znum ) / zdiv ) &
394	& - wmax
395	iflag: DO jn = 1, kiter
396	IF ( zwl == 0._wp ) THEN ; znummax = zl
397	ELSEIF( zwr == 0._wp ) THEN ; znummax = zr
398	ELSE
399	znummax = ( zr + zl ) / 2.
400	zdiv = xkr_zeta + xkr_eta - xkr_eta * znummax
401	znum = znummax - 1.
402	zws = xkr_wsbio_min * xkr_zeta / zdiv &
403	& - ( xkr_wsbio_max * xkr_eta * znum * &
404	& xkr_frac**( -xkr_zeta / znum ) / zdiv ) &
405	& - wmax
406	IF( zws * zwl < 0. ) THEN ; zr = znummax
407	ELSE ; zl = znummax
408	ENDIF
409	zdiv = xkr_zeta + xkr_eta - xkr_eta * zl
410	znum = zl - 1.
411	zwl = xkr_wsbio_min * xkr_zeta / zdiv &
412	& - ( xkr_wsbio_max * xkr_eta * znum * &
413	& xkr_frac**( -xkr_zeta / znum ) / zdiv ) &
414	& - wmax
415
416	zdiv = xkr_zeta + xkr_eta - xkr_eta * zr
417	znum = zr - 1.
418	zwr = xkr_wsbio_min * xkr_zeta / zdiv &
419	& - ( xkr_wsbio_max * xkr_eta * znum * &
420	& xkr_frac**( -xkr_zeta / znum ) / zdiv ) &
421	& - wmax
422	!
423	IF ( ABS ( zws ) <= xacc ) EXIT iflag
424	!
425	ENDIF
426	!
427	END DO iflag
428
429	xnumm(jk) = znummax
430	WRITE(numout,*) ' jk = ', jk, ' wmax = ', wmax,' xnum max = ', xnumm(jk)
431	!
432	END DO
433	!
434	IF( nn_timing == 1 ) CALL timing_stop('p4z_sink_init')
435	!
436	END SUBROUTINE p4z_sink_init
437
438	#else
439
440	SUBROUTINE p4z_sink ( kt, jnt )
441	!!---------------------------------------------------------------------
442	!! * ROUTINE p4z_sink *
443	!!
444	!! ** Purpose : Compute vertical flux of particulate matter due to
445	!! gravitational sinking
446	!!
447	!! ** Method : - ???
448	!!---------------------------------------------------------------------
449	INTEGER, INTENT(in) :: kt, jnt
450	INTEGER :: ji, jj, jk
451	REAL(wp) :: zagg1, zagg2, zagg3, zagg4
452	REAL(wp) :: zagg , zaggfe, zaggdoc, zaggdoc2, zaggdoc3
453	REAL(wp) :: zfact, zwsmax, zmax, zstep
454	REAL(wp) :: zrfact2
455	INTEGER :: ik1
456	CHARACTER (len=25) :: charout
457	!!---------------------------------------------------------------------
458	!
459	IF( nn_timing == 1 ) CALL timing_start('p4z_sink')
460	!
461	! Sinking speeds of detritus is increased with depth as shown
462	! by data and from the coagulation theory
463	! -----------------------------------------------------------
464	DO jk = 1, jpkm1
465	DO jj = 1, jpj
466	DO ji = 1,jpi
467	! zmax = MAX( heup(ji,jj), hmld(ji,jj) )
468	! zfact = MAX( 0., fsdepw(ji,jj,jk+1) - zmax ) / 5000._wp
469	zmax = hmld(ji,jj)
470	zfact = MAX( 0., fsdepw(ji,jj,jk+1) - zmax ) / 4000._wp
471	wsbio4(ji,jj,jk) = wsbio2 + ( 200.- wsbio2 ) * zfact
472	END DO
473	END DO
474	END DO
475
476	! limit the values of the sinking speeds to avoid numerical instabilities
477	wsbio3(:,:,:) = wsbio
478	!
479	! OA Below, this is garbage. the ideal would be to find a time-splitting
480	! OA algorithm that does not increase the computing cost by too much
481	! OA In ROMS, I have included a time-splitting procedure. But it is
482	! OA too expensive as the loop is computed globally. Thus, a small e3t
483	! OA at one place determines the number of subtimesteps globally
484	! OA AWFULLY EXPENSIVE !! Not able to find a better approach. Damned !!
485
486	DO jk = 1,jpkm1
487	DO jj = 1, jpj
488	DO ji = 1, jpi
489	zwsmax = 0.8 * fse3t(ji,jj,jk) / xstep
490	wsbio4(ji,jj,jk) = MIN( wsbio4(ji,jj,jk), zwsmax )
491	wsbio3(ji,jj,jk) = MIN( wsbio3(ji,jj,jk), zwsmax )
492	END DO
493	END DO
494	END DO
495
496	wscal(:,:,:) = wsbio4(:,:,:)
497
498	! Initializa to zero all the sinking arrays
499	! -----------------------------------------
500
501	sinking (:,:,:) = 0.e0
502	sinking2(:,:,:) = 0.e0
503	sinkcal (:,:,:) = 0.e0
504	sinkfer (:,:,:) = 0.e0
505	sinksil (:,:,:) = 0.e0
506	sinkfer2(:,:,:) = 0.e0
507
508	! Compute the sedimentation term using p4zsink2 for all the sinking particles
509	! -----------------------------------------------------
510
511	CALL p4z_sink2( wsbio3, sinking , jppoc )
512	CALL p4z_sink2( wsbio3, sinkfer , jpsfe )
513	CALL p4z_sink2( wsbio4, sinking2, jpgoc )
514	CALL p4z_sink2( wsbio4, sinkfer2, jpbfe )
515	CALL p4z_sink2( wsbio4, sinksil , jpgsi )
516	CALL p4z_sink2( wscal , sinkcal , jpcal )
517
518	! Exchange between organic matter compartments due to coagulation/disaggregation
519	! ---------------------------------------------------
520
521	DO jk = 1, jpkm1
522	DO jj = 1, jpj
523	DO ji = 1, jpi
524	!
525	zstep = xstep
526	# if defined key_degrad
527	zstep = zstep * facvol(ji,jj,jk)
528	# endif
529	zfact = zstep * xdiss(ji,jj,jk)
530	! Part I : Coagulation dependent on turbulence
531	zagg1 = 354. * zfact * trn(ji,jj,jk,jppoc) * trn(ji,jj,jk,jppoc)
532	zagg2 = 4452. * zfact * trn(ji,jj,jk,jppoc) * trn(ji,jj,jk,jpgoc)
533
534	! Part II : Differential settling
535
536	! Aggregation of small into large particles
537	zagg3 = 4.7 * zstep * trn(ji,jj,jk,jppoc) * trn(ji,jj,jk,jpgoc)
538	zagg4 = 0.4 * zstep * trn(ji,jj,jk,jppoc) * trn(ji,jj,jk,jppoc)
539
540	zagg = zagg1 + zagg2 + zagg3 + zagg4
541	zaggfe = zagg * trn(ji,jj,jk,jpsfe) / ( trn(ji,jj,jk,jppoc) + rtrn )
542
543	! Aggregation of DOC to small particles
544	zaggdoc = ( 0.83 * trn(ji,jj,jk,jpdoc) + 271. * trn(ji,jj,jk,jppoc) ) * zfact * trn(ji,jj,jk,jpdoc)
545	zaggdoc2 = 1.07e4 * zfact * trn(ji,jj,jk,jpgoc) * trn(ji,jj,jk,jpdoc)
546	zaggdoc3 = 0.02 * ( 16706. * trn(ji,jj,jk,jppoc) + 231. * trn(ji,jj,jk,jpdoc) ) * zstep * trn(ji,jj,jk,jpdoc)
547
548	! Update the trends
549	tra(ji,jj,jk,jppoc) = tra(ji,jj,jk,jppoc) - zagg + zaggdoc + zaggdoc3
550	tra(ji,jj,jk,jpgoc) = tra(ji,jj,jk,jpgoc) + zagg + zaggdoc2
551	tra(ji,jj,jk,jpsfe) = tra(ji,jj,jk,jpsfe) - zaggfe
552	tra(ji,jj,jk,jpbfe) = tra(ji,jj,jk,jpbfe) + zaggfe
553	tra(ji,jj,jk,jpdoc) = tra(ji,jj,jk,jpdoc) - zaggdoc - zaggdoc2 - zaggdoc3
554	!
555	END DO
556	END DO
557	END DO
558
559	IF( ln_diatrc ) THEN
560	zrfact2 = 1.e3 * rfact2r
561	ik1 = iksed + 1
562	IF( lk_iomput ) THEN
563	IF( jnt == nrdttrc ) THEN
564	CALL iom_put( "EPC100" , ( sinking(:,:,ik1) + sinking2(:,:,ik1) ) * zrfact2 * tmask(:,:,1) ) ! Export of carbon at 100m
565	CALL iom_put( "EPFE100" , ( sinkfer(:,:,ik1) + sinkfer2(:,:,ik1) ) * zrfact2 * tmask(:,:,1) ) ! Export of iron at 100m
566	CALL iom_put( "EPCAL100", sinkcal(:,:,ik1) * zrfact2 * tmask(:,:,1) ) ! Export of calcite at 100m
567	CALL iom_put( "EPSI100" , sinksil(:,:,ik1) * zrfact2 * tmask(:,:,1) ) ! Export of biogenic silica at 100m
568	ENDIF
569	ELSE
570	trc2d(:,:,jp_pcs0_2d + 4) = sinking (:,:,ik1) * zrfact2 * tmask(:,:,1)
571	trc2d(:,:,jp_pcs0_2d + 5) = sinking2(:,:,ik1) * zrfact2 * tmask(:,:,1)
572	trc2d(:,:,jp_pcs0_2d + 6) = sinkfer (:,:,ik1) * zrfact2 * tmask(:,:,1)
573	trc2d(:,:,jp_pcs0_2d + 7) = sinkfer2(:,:,ik1) * zrfact2 * tmask(:,:,1)
574	trc2d(:,:,jp_pcs0_2d + 8) = sinksil (:,:,ik1) * zrfact2 * tmask(:,:,1)
575	trc2d(:,:,jp_pcs0_2d + 9) = sinkcal (:,:,ik1) * zrfact2 * tmask(:,:,1)
576	ENDIF
577	ENDIF
578	!
579	IF(ln_ctl) THEN ! print mean trends (used for debugging)
580	WRITE(charout, FMT="('sink')")
581	CALL prt_ctl_trc_info(charout)
582	CALL prt_ctl_trc(tab4d=tra, mask=tmask, clinfo=ctrcnm)
583	ENDIF
584	!
585	IF( nn_timing == 1 ) CALL timing_stop('p4z_sink')
586	!
587	END SUBROUTINE p4z_sink
588
589	SUBROUTINE p4z_sink_init
590	!!----------------------------------------------------------------------
591	!! * ROUTINE p4z_sink_init *
592	!!----------------------------------------------------------------------
593	END SUBROUTINE p4z_sink_init
594
595	#endif
596
597
598
599	SUBROUTINE p4z_sink2( pwsink, psinkflx, jp_tra )
600	!!---------------------------------------------------------------------
601	!! * ROUTINE p4z_sink2 *
602	!!
603	!! ** Purpose : Compute the sedimentation terms for the various sinking
604	!! particles. The scheme used to compute the trends is based
605	!! on MUSCL.
606	!!
607	!! ** Method : - this ROUTINE compute not exactly the advection but the
608	!! transport term, i.e. div(u*tra).
609	!!---------------------------------------------------------------------
610	!
611	INTEGER , INTENT(in ) :: jp_tra ! tracer index index
612	REAL(wp), INTENT(in ), DIMENSION(jpi,jpj,jpk) :: pwsink ! sinking speed
613	REAL(wp), INTENT(inout), DIMENSION(jpi,jpj,jpk) :: psinkflx ! sinking fluxe
614	!!
615	INTEGER :: ji, jj, jk, jn
616	REAL(wp) :: zigma,zew,zign, zflx, zstep
617	REAL(wp), POINTER, DIMENSION(:,:,:) :: ztraz, zakz, zwsink2
618	!!---------------------------------------------------------------------
619	!
620	IF( nn_timing == 1 ) CALL timing_start('p4z_sink2')
621	!
622	! Allocate temporary workspace
623	CALL wrk_alloc( jpi, jpj, jpk, ztraz, zakz, zwsink2 )
624
625	zstep = rfact2 / 2.
626
627	ztraz(:,:,:) = 0.e0
628	zakz (:,:,:) = 0.e0
629
630	DO jk = 1, jpkm1
631	zwsink2(:,:,jk+1) = -pwsink(:,:,jk) / rday * tmask(:,:,jk+1)
632	END DO
633	zwsink2(:,:,1) = 0.e0
634	IF( lk_degrad ) THEN
635	zwsink2(:,:,:) = zwsink2(:,:,:) * facvol(:,:,:)
636	ENDIF
637
638
639	! Vertical advective flux
640	DO jn = 1, 2
641	! first guess of the slopes interior values
642	DO jk = 2, jpkm1
643	ztraz(:,:,jk) = ( trn(:,:,jk-1,jp_tra) - trn(:,:,jk,jp_tra) ) * tmask(:,:,jk)
644	END DO
645	ztraz(:,:,1 ) = 0.0
646	ztraz(:,:,jpk) = 0.0
647
648	! slopes
649	DO jk = 2, jpkm1
650	DO jj = 1,jpj
651	DO ji = 1, jpi
652	zign = 0.25 + SIGN( 0.25, ztraz(ji,jj,jk) * ztraz(ji,jj,jk+1) )
653	zakz(ji,jj,jk) = ( ztraz(ji,jj,jk) + ztraz(ji,jj,jk+1) ) * zign
654	END DO
655	END DO
656	END DO
657
658	! Slopes limitation
659	DO jk = 2, jpkm1
660	DO jj = 1, jpj
661	DO ji = 1, jpi
662	zakz(ji,jj,jk) = SIGN( 1., zakz(ji,jj,jk) ) * &
663	& MIN( ABS( zakz(ji,jj,jk) ), 2. * ABS(ztraz(ji,jj,jk+1)), 2. * ABS(ztraz(ji,jj,jk) ) )
664	END DO
665	END DO
666	END DO
667
668	! vertical advective flux
669	DO jk = 1, jpkm1
670	DO jj = 1, jpj
671	DO ji = 1, jpi
672	zigma = zwsink2(ji,jj,jk+1) * zstep / fse3w(ji,jj,jk+1)
673	zew = zwsink2(ji,jj,jk+1)
674	psinkflx(ji,jj,jk+1) = -zew * ( trn(ji,jj,jk,jp_tra) - 0.5 * ( 1 + zigma ) * zakz(ji,jj,jk) ) * zstep
675	END DO
676	END DO
677	END DO
678	!
679	! Boundary conditions
680	psinkflx(:,:,1 ) = 0.e0
681	psinkflx(:,:,jpk) = 0.e0
682
683	DO jk=1,jpkm1
684	DO jj = 1,jpj
685	DO ji = 1, jpi
686	zflx = ( psinkflx(ji,jj,jk) - psinkflx(ji,jj,jk+1) ) / fse3t(ji,jj,jk)
687	trn(ji,jj,jk,jp_tra) = trn(ji,jj,jk,jp_tra) + zflx
688	END DO
689	END DO
690	END DO
691
692	ENDDO
693
694	DO jk=1,jpkm1
695	DO jj = 1,jpj
696	DO ji = 1, jpi
697	zflx = ( psinkflx(ji,jj,jk) - psinkflx(ji,jj,jk+1) ) / fse3t(ji,jj,jk)
698	trb(ji,jj,jk,jp_tra) = trb(ji,jj,jk,jp_tra) + 2. * zflx
699	END DO
700	END DO
701	END DO
702
703	trn (:,:,:,jp_tra) = trb(:,:,:,jp_tra)
704	psinkflx(:,:,:) = 2. * psinkflx(:,:,:)
705	!
706	CALL wrk_dealloc( jpi, jpj, jpk, ztraz, zakz, zwsink2 )
707	!
708	IF( nn_timing == 1 ) CALL timing_stop('p4z_sink2')
709	!
710	END SUBROUTINE p4z_sink2
711
712
713	INTEGER FUNCTION p4z_sink_alloc()
714	!!----------------------------------------------------------------------
715	!! * ROUTINE p4z_sink_alloc *
716	!!----------------------------------------------------------------------
717	ALLOCATE( wsbio3 (jpi,jpj,jpk) , wsbio4 (jpi,jpj,jpk) , wscal(jpi,jpj,jpk) , &
718	& sinking(jpi,jpj,jpk) , sinking2(jpi,jpj,jpk) , &
719	& sinkcal(jpi,jpj,jpk) , sinksil (jpi,jpj,jpk) , &
720	#if defined key_kriest
721	& xnumm(jpk) , &
722	#else
723	& sinkfer2(jpi,jpj,jpk) , &
724	#endif
725	& sinkfer(jpi,jpj,jpk) , STAT=p4z_sink_alloc )
726	!
727	IF( p4z_sink_alloc /= 0 ) CALL ctl_warn('p4z_sink_alloc : failed to allocate arrays.')
728	!
729	END FUNCTION p4z_sink_alloc
730
731	#else
732	!!======================================================================
733	!! Dummy module : No PISCES bio-model
734	!!======================================================================
735	CONTAINS
736	SUBROUTINE p4z_sink ! Empty routine
737	END SUBROUTINE p4z_sink
738	#endif
739
740	!!======================================================================
741	END MODULE p4zsink

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