source: LMDZ6/branches/Amaury_dev/libf/phylmd/ecumev6_flux.F90 @ 5409

Last change on this file since 5409 was 5144, checked in by abarral, 5 months ago

Put YOMCST.h into modules

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1!SFX_LIC Copyright 1994-2014 CNRS, Meteo-France and Universite Paul Sabatier
2!SFX_LIC This is part of the SURFEX software governed by the CeCILL-C licence
3!SFX_LIC version 1. See LICENSE, CeCILL-C_V1-en.txt and CeCILL-C_V1-fr.txt 
4!SFX_LIC for details. version 1.
5!     #########
6SUBROUTINE ECUMEV6_FLUX(PZ0SEA, PTA, PSST, PQA, PQSAT, PVMOD, &
7        PZREF, PSSS, PUREF, PPS, PPA, OPRECIP, OPWEBB, &
8        PSFTH, PSFTQ, PUSTAR, PCD, PCDN, PCH, PCE, &
9        PRI, PRESA, PRAIN, PZ0HSEA, OPERTFLUX, coeffs)
10  !###############################################################################
11  !!
12  !!****  *ECUMEV6_FLUX*
13  !!
14  !!    PURPOSE
15  !!    -------
16  !       Calculate the surface turbulent fluxes of heat, moisture, and momentum
17  !       over sea surface + corrections due to rainfall & Webb effect.
18  !!
19  !!**  METHOD
20  !!    ------
21  !       The estimation of the transfer coefficients relies on the iterative
22  !       computation of the scaling parameters U*/Teta*/q*. The convergence is
23  !       supposed to be reached in NITERFL iterations maximum.
24  !       Neutral transfer coefficients for momentum/temperature/humidity
25  !       are computed as a function of the 10m-height neutral wind speed using
26  !       the ECUME_V6 formulation based on the multi-campaign (POMME,FETCH,CATCH,
27  !       SEMAPHORE,EQUALANT) ALBATROS dataset.
28  !!
29  !!    EXTERNAL
30  !!    --------
31  !!
32  !!    IMPLICIT ARGUMENTS
33  !!    ------------------
34  !!
35  !!    REFERENCE
36  !!    ---------
37  !!      Fairall et al (1996), JGR, 3747-3764
38  !!      Gosnell et al (1995), JGR, 437-442
39  !!      Fairall et al (1996), JGR, 1295-1308
40  !!
41  !!    AUTHOR
42  !!    ------
43  !!      C. Lebeaupin  *Météo-France* (adapted from S. Belamari's code)
44  !!
45  !!    MODIFICATIONS
46  !!    -------------
47  !!      Original     15/03/2005
48  !!      Modified        01/2006  C. Lebeaupin (adapted from  A. Pirani's code)
49  !!      Modified        08/2009  B. Decharme: limitation of Ri
50  !!      Modified        09/2012  B. Decharme: CD correction
51  !!      Modified        09/2012  B. Decharme: limitation of Ri in surface_ri.F90
52  !!      Modified        10/2012  P. Le Moigne: extra inputs for FLake use
53  !!      Modified        06/2013  B. Decharme: bug in z0 (output) computation
54  !!      Modified        12/2013  S. Belamari: ZRF computation updated:
55  !!                                1. ZP00/PPA in ZDWAT, ZLVA in ZDQSDT/ZBULB/ZRF
56  !!                                2. ZDWAT/ZDTMP in ZBULB/ZRF (Gosnell et al 95)
57  !!                                3. cool skin correction included
58  !!      Modified        01/2014  S. Belamari: salinity impact on latent heat of
59  !!                                vaporization of seawater included
60  !!      Modified        01/2014  S. Belamari: new formulation for pure water
61  !!                                specific heat (ZCPWA)
62  !!      Modified        01/2014  S. Belamari: 4 choices for PZ0SEA computation
63  !!      Modified        12/2015  S. Belamari: ECUME now provides parameterisations
64  !!                                for:  U10n*sqrt(CDN)          instead of CDN
65  !!                                      U10n*CHN/sqrt(CDN)         "       CHN
66  !!                                      U10n*CEN/sqrt(CDN)         "       CEN
67  !!      Modified        01/2016  S. Belamari: New ECUME formulation
68  !!
69  !!      To be done:
70  !!      include gustiness computation following Mondon & Redelsperger (1998)
71  !!!
72  !-------------------------------------------------------------------------------
73  !!
74  !!    MODIFICATIONS RELATED TO SST CORRECTION COMPUTATION
75  !!    ---------------------------------------------------
76  !!      Modified        09/2013  S. Belamari: use 0.98 for the ocean emissivity
77  !!                                following up to date satellite measurements in
78  !!                                the 8-14 μm range (obtained values range from
79  !!                                0.98 to 0.99).
80  !!!
81  !-------------------------------------------------------------------------------
82
83  !       0.   DECLARATIONS
84  !            ------------
85
86  USE dimphy
87  USE indice_sol_mod
88  USE MODD_CSTS, ONLY: XPI, XDAY, XKARMAN, XG, XP00, XSTEFAN, XRD, XRV, &
89          XCPD, XCPV, XCL, XTT, XLVTT
90  USE lmdz_clesphys
91  USE lmdz_yomcst
92
93
94  !USE MODD_SURF_PAR,         ONLY: XUNDEF
95  !USE MODD_SURF_ATM,         ONLY: XVCHRNK, XVZ0CM
96  !USE MODD_REPROD_OPER,      ONLY: CCHARNOCK
97
98  !USE MODE_THERMOS
99  !USE MODI_WIND_THRESHOLD
100  !USE MODI_SURFACE_RI
101
102  !USE YOMHOOK,   ONLY: LHOOK,   DR_HOOK
103  !USE PARKIND1,  ONLY: JPRB
104
105  !USE MODI_ABOR1_SFX
106
107  IMPLICIT NONE
108
109  !       0.1. Declarations of arguments
110
111  REAL, DIMENSION(klon), INTENT(IN) :: PVMOD      ! module of wind at atm level (m/s)
112  REAL, DIMENSION(klon), INTENT(IN) :: PTA        ! air temperature at atm level (K)
113  REAL, DIMENSION(klon), INTENT(IN) :: PQA        ! air spec. hum. at atm level (kg/kg)
114  REAL, DIMENSION(klon), INTENT(IN) :: PQSAT      ! sea surface spec. hum. (kg/kg)
115  REAL, DIMENSION(klon), INTENT(IN) :: PPA        ! air pressure at atm level (Pa)
116  !REAL, DIMENSION(:), INTENT(IN)    :: PRHOA      ! air density at atm level (kg/m3)
117  !REAL, DIMENSION(:), INTENT(IN)    :: PEXNA      ! Exner function at atm level
118  REAL, DIMENSION(klon), INTENT(IN) :: PUREF      ! atm level for wind (m)
119  REAL, DIMENSION(klon), INTENT(IN) :: PZREF      ! atm level for temp./hum. (m)
120  REAL, DIMENSION(klon), INTENT(IN) :: PSSS       ! Sea Surface Salinity (g/kg)
121  REAL, DIMENSION(klon), INTENT(IN) :: PPS        ! air pressure at sea surface (Pa)
122  !REAL, DIMENSION(:), INTENT(IN)    :: PEXNS      ! Exner function at sea surface
123  !REAL, DIMENSION(:), INTENT(IN)    :: PPERTFLUX  ! stochastic flux perturbation pattern
124  ! for correction
125  !REAL,               INTENT(IN)    :: PICHCE    !
126  LOGICAL, INTENT(IN) :: OPRECIP   !
127  LOGICAL, INTENT(IN) :: OPWEBB    !
128  LOGICAL, INTENT(IN) :: OPERTFLUX
129  REAL, DIMENSION(klon), INTENT(IN) :: PRAIN     ! precipitation rate (kg/s/m2)
130
131  !INTEGER,            INTENT(IN)    :: KZ0
132
133  REAL, DIMENSION(klon), INTENT(INOUT) :: PSST       ! Sea Surface Temperature (K)
134  REAL, DIMENSION(klon), INTENT(INOUT) :: PZ0SEA     ! roughness length over sea
135  REAL, DIMENSION(klon), INTENT(OUT) :: PZ0HSEA    ! heat roughness length over sea
136
137  ! surface fluxes : latent heat, sensible heat, friction fluxes
138  REAL, DIMENSION(klon), INTENT(OUT) :: PUSTAR     ! friction velocity (m/s)
139  REAL, DIMENSION(klon), INTENT(OUT) :: PSFTH      ! heat flux (W/m2)
140  REAL, DIMENSION(klon), INTENT(OUT) :: PSFTQ      ! water flux (kg/m2/s)
141
142  ! diagnostics
143  REAL, DIMENSION(klon), INTENT(OUT) :: PCD        ! transfer coef. for momentum
144  REAL, DIMENSION(klon), INTENT(OUT) :: PCH        ! transfer coef. for temperature
145  REAL, DIMENSION(klon), INTENT(OUT) :: PCE        ! transfer coef. for humidity
146  REAL, DIMENSION(klon), INTENT(OUT) :: PCDN       ! neutral coef. for momentum
147  REAL, DIMENSION(klon), INTENT(OUT) :: PRI        ! Richardson number
148  REAL, DIMENSION(klon), INTENT(OUT) :: PRESA      ! aerodynamical resistance
149  REAL, DIMENSION(3), INTENT(OUT) :: coeffs
150
151  !       0.2. Declarations of local variables
152
153  ! specif SB
154  INTEGER, DIMENSION(SIZE(PTA)) :: JCV        ! convergence index
155  INTEGER, DIMENSION(SIZE(PTA)) :: JITER      ! nb of iterations to converge
156  !rajout
157  REAL, DIMENSION(SIZE(PTA)) :: PEXNA      ! Exner function at atm level
158  REAL, DIMENSION(SIZE(PTA)) :: PEXNS      ! Exner function at atm level
159
160  REAL, DIMENSION(SIZE(PTA)) :: ZTAU       ! momentum flux (N/m2)
161  REAL, DIMENSION(SIZE(PTA)) :: ZHF        ! sensible heat flux (W/m2)
162  REAL, DIMENSION(SIZE(PTA)) :: ZEF        ! latent heat flux (W/m2)
163  REAL, DIMENSION(SIZE(PTA)) :: ZTAUR      ! momentum flx due to rain (N/m2)
164  REAL, DIMENSION(SIZE(PTA)) :: ZRF        ! sensible flx due to rain (W/m2)
165  REAL, DIMENSION(SIZE(PTA)) :: ZEFWEBB    ! Webb corr. on latent flx (W/m2)
166
167  REAL, DIMENSION(SIZE(PTA)) :: ZVMOD      ! wind intensity at atm level (m/s)
168  REAL, DIMENSION(SIZE(PTA)) :: ZQSATA     ! sat.spec.hum. at atm level (kg/kg)
169  REAL, DIMENSION(SIZE(PTA)) :: ZLVA       ! vap.heat of pure water at atm level (J/kg)
170  REAL, DIMENSION(SIZE(PTA)) :: ZLVS       ! vap.heat of seawater at sea surface (J/kg)
171  REAL, DIMENSION(SIZE(PTA)) :: ZCPA       ! specif.heat moist air (J/kg/K)
172  REAL, DIMENSION(SIZE(PTA)) :: ZVISA      ! kinemat.visc. of dry air (m2/s)
173  REAL, DIMENSION(SIZE(PTA)) :: ZDU        ! U   vert.grad. (real atm)
174  REAL, DIMENSION(SIZE(PTA)) :: ZDT, ZDQ    ! T,Q vert.grad. (real atm)
175  REAL, DIMENSION(SIZE(PTA)) :: ZDDU       ! U   vert.grad. (real atm + gust)
176  REAL, DIMENSION(SIZE(PTA)) :: ZDDT, ZDDQ  ! T,Q vert.grad. (real atm + WL/CS)
177  REAL, DIMENSION(SIZE(PTA)) :: ZUSR       ! velocity scaling param. (m/s)
178  ! =friction velocity
179  REAL, DIMENSION(SIZE(PTA)) :: ZTSR       ! temperature scaling param. (K)
180  REAL, DIMENSION(SIZE(PTA)) :: ZQSR       ! humidity scaling param. (kg/kg)
181  REAL, DIMENSION(SIZE(PTA)) :: ZDELTAU10N, ZDELTAT10N, ZDELTAQ10N
182  ! U,T,Q vert.grad. (10m, neutral atm)
183  REAL, DIMENSION(SIZE(PTA)) :: ZUSR0, ZTSR0, ZQSR0    ! ITERATIVE PROCESS
184  REAL, DIMENSION(SIZE(PTA)) :: ZDUSTO, ZDTSTO, ZDQSTO ! ITERATIVE PROCESS
185  REAL, DIMENSION(SIZE(PTA)) :: ZPSIU, ZPSIT! PSI funct for U, T/Q (Z0 comp)
186  REAL, DIMENSION(SIZE(PTA)) :: ZCHARN     ! Charnock parameter   (Z0 comp)
187
188  REAL, DIMENSION(SIZE(PTA)) :: ZUSTAR2    ! square of friction velocity
189  REAL, DIMENSION(SIZE(PTA)) :: ZAC        ! aerodynamical conductance
190  REAL, DIMENSION(SIZE(PTA)) :: ZDIRCOSZW  ! orography slope cosine
191  ! (=1 on water!)
192  REAL, DIMENSION(SIZE(PTA)) :: ZPARUN, ZPARTN, ZPARQN ! neutral parameter for U,T,Q
193
194  !-- rajout pour la pression saturante
195  REAL, DIMENSION(SIZE(PPA)) :: ZFOES                                 ! [OPWEBB]
196  REAL, DIMENSION(SIZE(PPA)) :: ZWORK1
197  REAL, DIMENSION(SIZE(PPA)) :: ZWORK2
198  REAL, DIMENSION(SIZE(PPS)) :: ZWORK1A
199  REAL, DIMENSION(SIZE(PPS)) :: ZWORK2A
200  !#####################
201
202  REAL, DIMENSION(0:5) :: ZCOEFU, ZCOEFT, ZCOEFQ
203
204  !--------- Modif Olive -----------------
205  REAL, DIMENSION(SIZE(PTA)) :: PRHOA
206  REAL, PARAMETER :: XUNDEF = 1.E+20
207
208  REAL :: XVCHRNK = 0.021
209  REAL :: XVZ0CM = 1.0E-5
210  !REAL       :: XRIMAX
211
212  CHARACTER :: CCHARNOCK = 'NEW'
213
214
215  !--------------------------------------
216
217
218  ! local constants
219  LOGICAL :: OPCVFLX              ! to force convergence
220  INTEGER :: NITERMAX             ! nb of iterations to get free convergence
221  INTEGER :: NITERSUP             ! nb of additional iterations if OPCVFLX=.TRUE.
222  INTEGER :: NITERFL              ! maximum number of iterations
223  REAL :: ZETV, ZRDSRV          ! thermodynamic constants
224  REAL :: ZSQR3
225  REAL :: ZLMOMIN, ZLMOMAX      ! min/max value of Obukhovs stability param. z/l
226  REAL :: ZBTA, ZGMA            ! parameters of the stability functions
227  REAL :: ZDUSR0, ZDTSR0, ZDQSR0 ! maximum gap for USR/TSR/QSR between 2 steps
228  REAL :: ZP00                 ! [OPRECIP] - water vap. diffusiv.ref.press.(Pa)
229  REAL :: ZUTU, ZUTT, ZUTQ       ! U10n threshold in ECUME parameterisation
230  REAL :: ZCDIRU, ZCDIRT, ZCDIRQ ! coef directeur pour fonction affine U,T,Q
231  REAL :: ZORDOU, ZORDOT, ZORDOQ ! ordonnee a l'origine pour fonction affine U,T,Q
232
233  INTEGER :: JJ                                   ! for ITERATIVE PROCESS
234  INTEGER :: JLON, JK
235  REAL :: ZLMOU, ZLMOT                          ! Obukhovs param. z/l for U, T/Q
236  REAL :: ZPSI_U, ZPSI_T                        ! PSI funct. for U, T/Q
237  REAL :: Z0TSEA, Z0QSEA                        ! roughness length for T, Q
238  REAL :: ZCHIC, ZCHIK, ZPSIC, ZPSIK, ZLOGUS10, ZLOGTS10
239  REAL :: ZTAC, ZCPWA, ZDQSDT, ZDWAT, ZDTMP, ZBULB  ! [OPRECIP]
240  REAL :: ZWW                                  ! [OPWEBB]
241
242  INTEGER :: PREF             ! reference pressure for exner function
243  REAL, DIMENSION(klon) :: PQSATA      ! sea surface spec. hum. (kg/kg)
244
245  REAL :: qsat_seawater2, qsat_seawater
246
247  !REAL(KIND=JPRB) :: ZHOOK_HANDLE
248
249  !-------------------------------------------------------------------------------
250  !----------------------- Modif Olive calcul de PRHOA ---------------------------
251
252  !WRITE(*,*) "PZ0SEA ",PZ0SEA
253  !WRITE(*,*) "PTA ",PTA
254  !WRITE(*,*) "PSST ",PSST
255  !WRITE(*,*) "PQA ",PQA
256  !WRITE(*,*) "PVMOD ",PVMOD
257  !WRITE(*,*) "PZREF ",PZREF
258  !WRITE(*,*) "PUREF ",PUREF
259  !WRITE(*,*) "PPS ",PPS
260  !WRITE(*,*) "PPA ",PPA
261  !WRITE(*,*) "OPRECIP ",OPRECIP
262  !WRITE(*,*) "PZ0HSEA ",PZ0HSEA
263  !WRITE(*,*) "PRAIN ",PRAIN
264
265  PRHOA(:) = PPS(:) / (287.1 * PTA(:) * (1. + .61 * PQA(:)))
266  !WRITE(*,*) "klon klon ",klon,PTA
267  !WRITE(*,*) "PRHOA ",SIZE(PRHOA),PRHOA
268
269  PREF = 100900.                    ! = 1000 hPa
270
271  !PEXNA = (PPA/PPS)**RKAPPA
272  !PEXNS = (PPS/PPS)**RKAPPA
273
274  PEXNA = (PPA / PREF)**(RD / RCPD)
275  PEXNS = (PPS / PREF)**(RD / RCPD)
276
277  !IF (LHOOK) CALL DR_HOOK('ECUMEV6_FLUX',0,ZHOOK_HANDLE)
278
279  ZDUSR0 = 1.E-06
280  ZDTSR0 = 1.E-06
281  ZDQSR0 = 1.E-09
282
283  NITERMAX = 5
284  NITERSUP = 5
285  OPCVFLX = .TRUE.
286
287  NITERFL = NITERMAX
288  IF (OPCVFLX) NITERFL = NITERMAX + NITERSUP
289
290  ZCOEFU = (/ 1.00E-03, 3.66E-02, -1.92E-03, 2.32E-04, -7.02E-06, 6.40E-08 /)
291  ZCOEFT = (/ 5.36E-03, 2.90E-02, -1.24E-03, 4.50E-04, -2.06E-05, 0.0 /)
292  ZCOEFQ = (/ 1.00E-03, 3.59E-02, -2.87E-04, 0.0, 0.0, 0.0 /)
293
294  ZUTU = 40.0
295  ZUTT = 14.4
296  ZUTQ = 10.0
297
298  ZCDIRU = ZCOEFU(1) + 2.0 * ZCOEFU(2) * ZUTU + 3.0 * ZCOEFU(3) * ZUTU**2   &
299          + 4.0 * ZCOEFU(4) * ZUTU**3 + 5.0 * ZCOEFU(5) * ZUTU**4
300  ZCDIRT = ZCOEFT(1) + 2.0 * ZCOEFT(2) * ZUTT + 3.0 * ZCOEFT(3) * ZUTT**2   &
301          + 4.0 * ZCOEFT(4) * ZUTT**3
302  ZCDIRQ = ZCOEFQ(1) + 2.0 * ZCOEFQ(2) * ZUTQ
303
304  ZORDOU = ZCOEFU(0) + ZCOEFU(1) * ZUTU + ZCOEFU(2) * ZUTU**2 + ZCOEFU(3) * ZUTU**3   &
305          + ZCOEFU(4) * ZUTU**4 + ZCOEFU(5) * ZUTU**5
306  ZORDOT = ZCOEFT(0) + ZCOEFT(1) * ZUTT + ZCOEFT(2) * ZUTT**2 + ZCOEFT(3) * ZUTT**3   &
307          + ZCOEFT(4) * ZUTT**4
308  ZORDOQ = ZCOEFQ(0) + ZCOEFQ(1) * ZUTQ + ZCOEFQ(2) * ZUTQ**2
309
310  !-------------------------------------------------------------------------------
311
312  !       1.   AUXILIARY CONSTANTS & ARRAY INITIALISATION BY UNDEFINED VALUES.
313  !       --------------------------------------------------------------------
314
315  ZDIRCOSZW(:) = 1.0
316
317  ZETV = XRV / XRD - 1.0   !~0.61 (cf Liu et al. 1979)
318  ZRDSRV = XRD / XRV       !~0.622
319  ZSQR3 = SQRT(3.0)
320  ZLMOMIN = -200.0
321  ZLMOMAX = 0.25
322  ZBTA = 16.0
323  ZGMA = 7.0           !initially =4.7, modified to 7.0 following G. Caniaux
324
325  ZP00 = 1013.25E+02
326
327  PCD = XUNDEF
328  PCH = XUNDEF
329  PCE = XUNDEF
330  PCDN = XUNDEF
331  ZUSR = XUNDEF
332  ZTSR = XUNDEF
333  ZQSR = XUNDEF
334  ZTAU = XUNDEF
335  ZHF = XUNDEF
336  ZEF = XUNDEF
337
338  PSFTH = XUNDEF
339  PSFTQ = XUNDEF
340  PUSTAR = XUNDEF
341  PRESA = XUNDEF
342  PRI = XUNDEF
343
344  ZTAUR = 0.0
345  ZRF = 0.0
346  ZEFWEBB = 0.0
347
348  !-------------------------------------------------------------------------------
349
350  !       2.   INITIALISATIONS BEFORE ITERATIVE LOOP.
351  !       -------------------------------------------
352
353  !ZVMOD(:) = WIND_THRESHOLD(PVMOD(:),PUREF(:))    !set a minimum value to wind
354  ZVMOD = MAX(PVMOD, 0.1 * MIN(10., PUREF))    !set a minimum value to wind
355
356  WRITE(*, *) "ZVMOD ", SIZE(ZVMOD)
357
358  !       2.0. Radiative fluxes - For warm layer & cool skin
359
360  !       2.0b. Warm Layer correction
361
362  !       2.1. Specific humidity at saturation
363
364  WHERE(PSSS(:)>0.0.AND.PSSS(:)/=XUNDEF)
365    PQSATA = QSAT_SEAWATER2 (PSST(:), PPS(:), PSSS(:))    !at sea surface
366  ELSEWHERE
367    PQSATA (:) = QSAT_SEAWATER (PSST(:), PPS(:))            !at sea surface
368  ENDWHERE
369
370  !ZQSATA(:) = QSAT(PTA(:),PPA(:))                         !at atm level
371
372  !### OLIVIER POUR PRESSION SATURANTE #####
373  !-------------------------------------------------------------------------------
374
375  ZFOES = 1 !PSAT(PT(:))
376  ZFOES = 0.98 * ZFOES
377
378  ZWORK1 = ZFOES / PPS
379  ZWORK2 = XRD / XRV
380
381  ZWORK1A = ZFOES / PPA
382  ZWORK2A = XRD / XRV
383
384  !WRITE(*,*) "ZFOES ",ZFOES
385  !WRITE(*,*) "PPS ",PPS
386  !WRITE(*,*) "ZWORK1 ",ZWORK1
387  !WRITE(*,*) "XRD ",XRD
388  !WRITE(*,*) "XRV ",XRV
389  !WRITE(*,*) "PPA ",PPA
390  !WRITE(*,*) "ZWORK1A ",ZWORK1A
391
392  WRITE(*, *) "PQSAT : ", PQSAT
393  WRITE(*, *) "PQSATA : ", PQSATA
394
395  !*       2.    COMPUTE SATURATION HUMIDITY
396  !              ---------------------------
397
398  !PQSAT  = ZWORK2*ZWORK1 / (1.+(ZWORK2-1.)*ZWORK1)
399  !ZQSATA = ZWORK2A*ZWORK1A / (1.+(ZWORK2A-1.)*ZWORK1A)
400  ZQSATA = QSAT_SEAWATER (PTA(:), PPA(:))            !at sea surface
401
402  !       2.2. Gradients at the air-sea interface
403
404  ZDU(:) = ZVMOD(:)               !one assumes u is measured / sea surface current
405  ZDT(:) = PTA(:) / PEXNA(:) - PSST(:) / PEXNS(:)
406  ZDQ(:) = PQA(:) - PQSATA(:)
407
408  WRITE(*, *) "PQA ", PQA(:)
409  WRITE(*, *) "PQSAT", PQSAT(:)
410  WRITE(*, *) "ZDQ", ZDQ(:)
411
412  !       2.3. Latent heat of vaporisation
413
414  ZLVA(:) = XLVTT + (XCPV - XCL) * (PTA (:) - XTT)                !of pure water at atm level
415  ZLVS(:) = XLVTT + (XCPV - XCL) * (PSST(:) - XTT)                !of pure water at sea surface
416
417  WRITE(*, *) "ZLVA ", ZLVA
418  WRITE(*, *) "ZLVS ", ZLVS
419
420  WHERE(PSSS(:)>0.0.AND.PSSS(:)/=XUNDEF)
421    ZLVS(:) = ZLVS(:) * (1.0 - 1.00472E-3 * PSSS(:))            !of seawater at sea surface
422  ENDWHERE
423
424  !       2.4. Specific heat of moist air (Businger 1982)
425
426  !ZCPA(:) = XCPD*(1.0+(XCPV/XCPD-1.0)*PQA(:))
427  ZCPA(:) = XCPD
428
429  !       2.4b Kinematic viscosity of dry air (Andreas 1989, CRREL Rep. 89-11)
430
431  ZVISA(:) = 1.326E-05 * (1.0 + 6.542E-03 * (PTA(:) - XTT) + 8.301E-06 * (PTA(:) - XTT)**2   &
432          - 4.84E-09 * (PTA(:) - XTT)**3)
433
434  !       2.4c Coefficients for warm layer and/or cool skin correction
435
436  !       2.5. Initial guess
437
438  ZDDU(:) = ZDU(:)
439  ZDDT(:) = ZDT(:)
440  ZDDQ(:) = ZDQ(:)
441  ZDDU(:) = SIGN(MAX(ABS(ZDDU(:)), 10.0 * ZDUSR0), ZDDU(:))
442  ZDDT(:) = SIGN(MAX(ABS(ZDDT(:)), 10.0 * ZDTSR0), ZDDT(:))
443  ZDDQ(:) = SIGN(MAX(ABS(ZDDQ(:)), 10.0 * ZDQSR0), ZDDQ(:))
444
445  WRITE(*, *) "ZDDU ", ZDDU
446  WRITE(*, *) "ZDDQ ", ZDDQ
447  WRITE(*, *) "ZDDT ", ZDDT
448
449  JCV (:) = -1
450  ZUSR(:) = 0.04 * ZDDU(:)
451  ZTSR(:) = 0.04 * ZDDT(:)
452  ZQSR(:) = 0.04 * ZDDQ(:)
453  ZDELTAU10N(:) = ZDDU(:)
454  ZDELTAT10N(:) = ZDDT(:)
455  ZDELTAQ10N(:) = ZDDQ(:)
456  JITER(:) = 99
457
458  ! In the following, we suppose that Richardson number PRI < XRIMAX
459  ! If not true, Monin-Obukhov theory can't (and therefore shouldn't) be applied !
460  !-------------------------------------------------------------------------------
461
462  !       3.   ITERATIVE LOOP TO COMPUTE U*, T*, Q*.
463  !       ------------------------------------------
464
465  DO JJ = 1, NITERFL
466    DO JLON = 1, SIZE(PTA)
467
468      IF (JCV(JLON) == -1) THEN
469        ZUSR0(JLON) = ZUSR(JLON)
470        ZTSR0(JLON) = ZTSR(JLON)
471        ZQSR0(JLON) = ZQSR(JLON)
472        IF (JJ == NITERMAX + 1 .OR. JJ == NITERMAX + NITERSUP) THEN
473          ZDELTAU10N(JLON) = 0.5 * (ZDUSTO(JLON) + ZDELTAU10N(JLON))    !forced convergence
474          ZDELTAT10N(JLON) = 0.5 * (ZDTSTO(JLON) + ZDELTAT10N(JLON))
475          ZDELTAQ10N(JLON) = 0.5 * (ZDQSTO(JLON) + ZDELTAQ10N(JLON))
476          IF (JJ == NITERMAX + NITERSUP) JCV(JLON) = 3
477        ENDIF
478        ZDUSTO(JLON) = ZDELTAU10N(JLON)
479        ZDTSTO(JLON) = ZDELTAT10N(JLON)
480        ZDQSTO(JLON) = ZDELTAQ10N(JLON)
481
482        !       3.1. Neutral parameter for wind speed (ECUME_V6 formulation)
483
484        IF (ZDELTAU10N(JLON) <= ZUTU) THEN
485          ZPARUN(JLON) = ZCOEFU(0) + ZCOEFU(1) * ZDELTAU10N(JLON)      &
486                  + ZCOEFU(2) * ZDELTAU10N(JLON)**2   &
487                  + ZCOEFU(3) * ZDELTAU10N(JLON)**3   &
488                  + ZCOEFU(4) * ZDELTAU10N(JLON)**4   &
489                  + ZCOEFU(5) * ZDELTAU10N(JLON)**5
490        ELSE
491          ZPARUN(JLON) = ZCDIRU * (ZDELTAU10N(JLON) - ZUTU) + ZORDOU
492        ENDIF
493        PCDN(JLON) = (ZPARUN(JLON) / ZDELTAU10N(JLON))**2
494
495        !       3.2. Neutral parameter for temperature (ECUME_V6 formulation)
496
497        IF (ZDELTAU10N(JLON) <= ZUTT) THEN
498          ZPARTN(JLON) = ZCOEFT(0) + ZCOEFT(1) * ZDELTAU10N(JLON)      &
499                  + ZCOEFT(2) * ZDELTAU10N(JLON)**2   &
500                  + ZCOEFT(3) * ZDELTAU10N(JLON)**3   &
501                  + ZCOEFT(4) * ZDELTAU10N(JLON)**4
502        ELSE
503          ZPARTN(JLON) = ZCDIRT * (ZDELTAU10N(JLON) - ZUTT) + ZORDOT
504        ENDIF
505
506        !       3.3. Neutral parameter for humidity (ECUME_V6 formulation)
507
508        IF (ZDELTAU10N(JLON) <= ZUTQ) THEN
509          ZPARQN(JLON) = ZCOEFQ(0) + ZCOEFQ(1) * ZDELTAU10N(JLON)      &
510                  + ZCOEFQ(2) * ZDELTAU10N(JLON)**2
511        ELSE
512          ZPARQN(JLON) = ZCDIRQ * (ZDELTAU10N(JLON) - ZUTQ) + ZORDOQ
513        ENDIF
514
515        !       3.4. Scaling parameters U*, T*, Q*
516
517        ZUSR(JLON) = ZPARUN(JLON)
518        ZTSR(JLON) = ZPARTN(JLON) * ZDELTAT10N(JLON) / ZDELTAU10N(JLON)
519        ZQSR(JLON) = ZPARQN(JLON) * ZDELTAQ10N(JLON) / ZDELTAU10N(JLON)
520
521        !       3.4b Gustiness factor (Deardorff 1970)
522
523        !       3.4c Cool skin correction
524
525        !       3.5. Obukhovs stability param. z/l following Liu et al. (JAS, 1979)
526
527        ! For U
528        ZLMOU = PUREF(JLON) * XG * XKARMAN * (ZTSR(JLON) / PTA(JLON)   &
529                + ZETV * ZQSR(JLON) / (1.0 + ZETV * PQA(JLON))) / ZUSR(JLON)**2
530        ! For T/Q
531        ZLMOT = ZLMOU * (PZREF(JLON) / PUREF(JLON))
532        ZLMOU = MAX(MIN(ZLMOU, ZLMOMAX), ZLMOMIN)
533        ZLMOT = MAX(MIN(ZLMOT, ZLMOMAX), ZLMOMIN)
534
535        !       3.6. Stability function psi (see Liu et al, 1979 ; Dyer and Hicks, 1970)
536        !            Modified to include convective form following Fairall (unpublished)
537
538        ! For U
539        IF (ZLMOU == 0.0) THEN
540          ZPSI_U = 0.0
541        ELSEIF (ZLMOU > 0.0) THEN
542          ZPSI_U = -ZGMA * ZLMOU
543        ELSE
544          ZCHIK = (1.0 - ZBTA * ZLMOU)**0.25
545          ZPSIK = 2.0 * LOG((1.0 + ZCHIK) / 2.0)  &
546                  + LOG((1.0 + ZCHIK**2) / 2.0) &
547                  - 2.0 * ATAN(ZCHIK) + 0.5 * XPI
548          ZCHIC = (1.0 - 12.87 * ZLMOU)**(1.0 / 3.0)       !for very unstable conditions
549          ZPSIC = 1.5 * LOG((ZCHIC**2 + ZCHIC + 1.0) / 3.0)   &
550                  - ZSQR3 * ATAN((2.0 * ZCHIC + 1.0) / ZSQR3) &
551                  + XPI / ZSQR3
552          ZPSI_U = ZPSIC + (ZPSIK - ZPSIC) / (1.0 + ZLMOU**2) !match Kansas & free-conv. forms
553        ENDIF
554        ZPSIU(JLON) = ZPSI_U
555        ! For T/Q
556        IF (ZLMOT == 0.0) THEN
557          ZPSI_T = 0.0
558        ELSEIF (ZLMOT > 0.0) THEN
559          ZPSI_T = -ZGMA * ZLMOT
560        ELSE
561          ZCHIK = (1.0 - ZBTA * ZLMOT)**0.25
562          ZPSIK = 2.0 * LOG((1.0 + ZCHIK**2) / 2.0)
563          ZCHIC = (1.0 - 12.87 * ZLMOT)**(1.0 / 3.0)       !for very unstable conditions
564          ZPSIC = 1.5 * LOG((ZCHIC**2 + ZCHIC + 1.0) / 3.0)   &
565                  - ZSQR3 * ATAN((2.0 * ZCHIC + 1.0) / ZSQR3) &
566                  + XPI / ZSQR3
567          ZPSI_T = ZPSIC + (ZPSIK - ZPSIC) / (1.0 + ZLMOT**2) !match Kansas & free-conv. forms
568        ENDIF
569        ZPSIT(JLON) = ZPSI_T
570
571        !       3.7. Update air-sea gradients
572
573        ZDDU(JLON) = ZDU(JLON)
574        ZDDT(JLON) = ZDT(JLON)
575        ZDDQ(JLON) = ZDQ(JLON)
576        ZDDU(JLON) = SIGN(MAX(ABS(ZDDU(JLON)), 10.0 * ZDUSR0), ZDDU(JLON))
577        ZDDT(JLON) = SIGN(MAX(ABS(ZDDT(JLON)), 10.0 * ZDTSR0), ZDDT(JLON))
578        ZDDQ(JLON) = SIGN(MAX(ABS(ZDDQ(JLON)), 10.0 * ZDQSR0), ZDDQ(JLON))
579        ZLOGUS10 = LOG(PUREF(JLON) / 10.0)
580        ZLOGTS10 = LOG(PZREF(JLON) / 10.0)
581        ZDELTAU10N(JLON) = ZDDU(JLON) - ZUSR(JLON) * (ZLOGUS10 - ZPSI_U) / XKARMAN
582        ZDELTAT10N(JLON) = ZDDT(JLON) - ZTSR(JLON) * (ZLOGTS10 - ZPSI_T) / XKARMAN
583        ZDELTAQ10N(JLON) = ZDDQ(JLON) - ZQSR(JLON) * (ZLOGTS10 - ZPSI_T) / XKARMAN
584        ZDELTAU10N(JLON) = SIGN(MAX(ABS(ZDELTAU10N(JLON)), 10.0 * ZDUSR0), &
585                ZDELTAU10N(JLON))
586        ZDELTAT10N(JLON) = SIGN(MAX(ABS(ZDELTAT10N(JLON)), 10.0 * ZDTSR0), &
587                ZDELTAT10N(JLON))
588        ZDELTAQ10N(JLON) = SIGN(MAX(ABS(ZDELTAQ10N(JLON)), 10.0 * ZDQSR0), &
589                ZDELTAQ10N(JLON))
590
591        !       3.8. Test convergence for U*, T*, Q*
592
593        IF (ABS(ZUSR(JLON) - ZUSR0(JLON)) < ZDUSR0 .AND.   &
594                ABS(ZTSR(JLON) - ZTSR0(JLON)) < ZDTSR0 .AND.   &
595                ABS(ZQSR(JLON) - ZQSR0(JLON)) < ZDQSR0) THEN
596          JCV(JLON) = 1                                     !free convergence
597          IF (JJ >= NITERMAX + 1) JCV(JLON) = 2               !leaded convergence
598        ENDIF
599        JITER(JLON) = JJ
600      ENDIF
601
602    ENDDO
603  ENDDO
604
605  !-------------------------------------------------------------------------------
606
607  !       4.   COMPUTATION OF TURBULENT FLUXES AND EXCHANGE COEFFICIENTS.
608  !       ---------------------------------------------------------------
609
610  DO JLON = 1, SIZE(PTA)
611
612    !       4.1. Surface turbulent fluxes
613    !            (ATM CONV.: ZTAU<<0 ; ZHF,ZEF<0 if atm looses heat)
614
615    ZTAU(JLON) = -PRHOA(JLON) * ZUSR(JLON)**2
616    ZHF(JLON) = -PRHOA(JLON) * ZCPA(JLON) * ZUSR(JLON) * ZTSR(JLON)
617    ZEF(JLON) = -PRHOA(JLON) * ZLVS(JLON) * ZUSR(JLON) * ZQSR(JLON)
618
619    WRITE(*, *) "ZTAU = ", ZTAU(JLON)
620    WRITE(*, *) "SENS = ", ZHF(JLON)
621    WRITE(*, *) "LAT = ", ZEF(JLON)
622
623    !       4.2. Exchange coefficients PCD, PCH, PCE
624
625    PCD(JLON) = (ZUSR(JLON) / ZDDU(JLON))**2
626    PCH(JLON) = (ZUSR(JLON) * ZTSR(JLON)) / (ZDDU(JLON) * ZDDT(JLON))
627    PCE(JLON) = (ZUSR(JLON) * ZQSR(JLON)) / (ZDDU(JLON) * ZDDQ(JLON))
628
629    WRITE(*, *) "ZUSR = ", ZUSR(JLON)
630    WRITE(*, *) "ZTSR = ", ZTSR(JLON)
631    WRITE(*, *) "ZQSR = ", ZQSR(JLON)
632
633    !       4.3. Stochastic perturbation of turbulent fluxes
634
635    !  IF( OPERTFLUX )THEN
636    !    ZTAU(JLON) = ZTAU(JLON)* ( 1. + PPERTFLUX(JLON) / 2. )
637    !    ZHF (JLON) = ZHF(JLON)*  ( 1. + PPERTFLUX(JLON) / 2. )
638    !    ZEF (JLON) = ZEF(JLON)*  ( 1. + PPERTFLUX(JLON) / 2. )
639    !  ENDIF
640
641  ENDDO
642
643  !-------------------------------------------------------------------------------
644
645  !       5.   COMPUTATION OF FLUX CORRECTIONS DUE TO RAINFALL.
646  !            (ATM conv: ZRF<0 if atm. looses heat, ZTAUR<<0)
647  !       -----------------------------------------------------
648
649  IF (OPRECIP) THEN
650    DO JLON = 1, SIZE(PTA)
651
652      !       5.1. Momentum flux due to rainfall (ZTAUR, N/m2)
653
654      ! See pp3752 in FBR96.
655      ZTAUR(JLON) = -0.85 * PRAIN(JLON) * PVMOD(JLON)
656
657      !       5.2. Sensible heat flux due to rainfall (ZRF, W/m2)
658
659      ! See Eq.12 in GoF95 with ZCPWA as specific heat of water at atm level (J/kg/K),
660      ! ZDQSDT from Clausius-Clapeyron relation, ZDWAT as water vapor diffusivity
661      ! (Eq.13-3 of Pruppacher and Klett, 1978), ZDTMP as heat diffusivity, and ZBULB
662      ! as wet-bulb factor (Eq.11 in GoF95).
663
664      ZTAC = PTA(JLON) - XTT
665      ZCPWA = 4217.51 - 3.65566 * ZTAC + 0.1381 * ZTAC**2       &
666              - 2.8309E-03 * ZTAC**3 + 3.42061E-05 * ZTAC**4   &
667              - 2.18107E-07 * ZTAC**5 + 5.74535E-10 * ZTAC**6
668      ZDQSDT = (ZLVA(JLON) * ZQSATA(JLON)) / (XRV * PTA(JLON)**2)
669      ZDWAT = 2.11E-05 * (ZP00 / PPA(JLON)) * (PTA(JLON) / XTT)**1.94
670      ZDTMP = (1.0 + 3.309E-03 * ZTAC - 1.44E-06 * ZTAC**2)   &
671              * 0.02411 / (PRHOA(JLON) * ZCPA(JLON))
672      ZBULB = 1.0 / (1.0 + ZDQSDT * (ZLVA(JLON) * ZDWAT) / (ZCPA(JLON) * ZDTMP))
673      ZRF(JLON) = PRAIN(JLON) * ZCPWA * ZBULB * ((PSST(JLON) - PTA(JLON))   &
674              + (PQSATA(JLON) - PQA(JLON)) * (ZLVA(JLON) * ZDWAT) / (ZCPA(JLON) * ZDTMP))
675
676    ENDDO
677  ENDIF
678
679  !-------------------------------------------------------------------------------
680
681  !       6.   COMPUTATION OF WEBB CORRECTION TO LATENT HEAT FLUX (ZEFWEBB, W/m2).
682  !       ------------------------------------------------------------------------
683
684  ! See Eq.21 and Eq.22 in FBR96.
685  IF (OPWEBB) THEN
686    DO JLON = 1, SIZE(PTA)
687      ZWW = (1.0 + ZETV) * (ZUSR(JLON) * ZQSR(JLON))   &
688              + (1.0 + (1.0 + ZETV) * PQA(JLON)) * (ZUSR(JLON) * ZTSR(JLON)) / PTA(JLON)
689      ZEFWEBB(JLON) = -PRHOA(JLON) * ZLVS(JLON) * ZWW * PQA(JLON)
690    ENDDO
691  ENDIF
692
693  !-------------------------------------------------------------------------------
694
695  !       7.   FINAL STEP : TOTAL SURFACE FLUXES AND DERIVED DIAGNOSTICS.
696  !       ---------------------------------------------------------------
697
698  !       7.1. Richardson number
699
700  ! CALL SURFACE_RI(PSST,PQSAT,PEXNS,PEXNA,PTA,PQA,   &
701  !                PZREF,PUREF,ZDIRCOSZW,PVMOD,PRI)
702
703  !       7.2. Friction velocity which contains correction due to rain
704
705  ZUSTAR2(:) = -(ZTAU(:) + ZTAUR(:)) / PRHOA(:)       !>>0 as ZTAU<<0 & ZTAUR<=0
706
707  IF (OPRECIP) THEN
708    PCD(:) = ZUSTAR2(:) / ZDDU(:)**2
709  ENDIF
710
711  PUSTAR(:) = SQRT(ZUSTAR2(:))                    !>>0
712
713  !       7.3. Aerodynamical conductance and resistance
714
715  ZAC  (:) = PCH(:) * ZDDU(:)
716  PRESA(:) = 1.0 / ZAC(:)
717
718  !       7.4. Total surface fluxes
719
720  PSFTH(:) = ZHF(:) + ZRF(:)
721  PSFTQ(:) = (ZEF(:) + ZEFWEBB(:)) / ZLVS(:)
722
723  !       7.5. Charnock number
724
725  IF (CCHARNOCK == 'OLD') THEN
726    ZCHARN(:) = XVCHRNK
727  ELSE            !modified for moderate wind speed as in COARE3.0
728    ZCHARN(:) = MIN(0.018, MAX(0.011, 0.011 + (0.007 / 8.0) * (ZDDU(:) - 10.0)))
729  ENDIF
730
731  !       7.6. Roughness lengths Z0 and Z0H over sea
732
733  !IF (KZ0 == 0) THEN      ! ARPEGE formulation
734  !  PZ0SEA (:) = (ZCHARN(:)/XG)*ZUSTAR2(:) + XVZ0CM*PCD(:)/PCDN(:)
735  !  PZ0HSEA(:) = PZ0SEA (:)
736  !ELSEIF (KZ0 == 1) THEN  ! Smith (1988) formulation
737  !  PZ0SEA (:) = (ZCHARN(:)/XG)*ZUSTAR2(:) + 0.11*ZVISA(:)/PUSTAR(:)
738  !  PZ0HSEA(:) = PZ0SEA (:)
739  !ELSEIF (KZ0 == 2) THEN  ! Direct computation using the stability functions
740  !  DO JLON=1,SIZE(PTA)
741  !    PZ0SEA (JLON) = PUREF(JLON)/EXP(XKARMAN*ZDDU(JLON)/PUSTAR(JLON)+ZPSIU(JLON))
742  !    Z0TSEA        = PZREF(JLON)/EXP(XKARMAN*ZDDT(JLON)/ZTSR  (JLON)+ZPSIT(JLON))
743  !    Z0QSEA        = PZREF(JLON)/EXP(XKARMAN*ZDDQ(JLON)/ZQSR  (JLON)+ZPSIT(JLON))
744  !    PZ0HSEA(JLON) = 0.5*(Z0TSEA+Z0QSEA)
745  !  ENDDO
746  !ENDIF
747
748  WRITE(*, *) "JLON ", JLON
749  WRITE(*, *) "PTA ", klon, PTA
750  WRITE(*, *) "PCD ", SIZE(PCD), PCD
751  WRITE(*, *) "PCQ ", SIZE(PCE), PCE
752  WRITE(*, *) "PCH ", SIZE(PCH), PCH
753
754  coeffs = [PCD, &
755          PCE, &
756          PCH]
757
758
759  !IF (LHOOK) CALL DR_HOOK('ECUMEV6_FLUX',1,ZHOOK_HANDLE)
760
761  !-------------------------------------------------------------------------------
762END SUBROUTINE ECUMEV6_FLUX
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