1 |
SUBROUTINE coefkz(nsrf, knon, paprs, pplay, |
module coefkz_m |
2 |
cIM 261103 |
|
3 |
. ksta, ksta_ter, |
IMPLICIT none |
4 |
cIM 261103 |
|
5 |
. ts, rugos, |
contains |
6 |
. u,v,t,q, |
|
7 |
. qsurf, |
SUBROUTINE coefkz(nsrf, knon, paprs, pplay, ksta, ksta_ter, ts, rugos, u, v, & |
8 |
. pcfm, pcfh) |
t, q, qsurf, pcfm, pcfh) |
9 |
use dimens_m |
|
10 |
use indicesol |
! Authors: F. Hourdin, M. Forichon, Z.X. Li (LMD/CNRS) |
11 |
use dimphy |
! date: 1993/09/22 |
12 |
use iniprint |
! Objet : calculer le coefficient de frottement du sol ("Cdrag") et les |
13 |
use YOMCST |
! coefficients d'échange turbulent dans l'atmosphère. |
14 |
use yoethf |
|
15 |
use fcttre |
USE indicesol, ONLY : is_oce |
16 |
use conf_phys_m |
USE dimphy, ONLY : klev, klon, max |
17 |
IMPLICIT none |
USE conf_gcm_m, ONLY : prt_level |
18 |
c====================================================================== |
USE suphec_m, ONLY : rcpd, rd, retv, rg, rkappa, rlstt, rlvtt, rtt |
19 |
c Auteur(s) F. Hourdin, M. Forichon, Z.X. Li (LMD/CNRS) date: 19930922 |
USE yoethf_m, ONLY : r2es, r5ies, r5les, rvtmp2 |
20 |
c (une version strictement identique a l'ancien modele) |
USE fcttre, ONLY : dqsatl, dqsats, foede, foeew, qsatl, qsats, thermcep |
21 |
c Objet: calculer le coefficient du frottement du sol (Cdrag) et les |
USE conf_phys_m, ONLY : iflag_pbl |
22 |
c coefficients d'echange turbulent dans l'atmosphere. |
|
23 |
c Arguments: |
! Arguments: |
24 |
c nsrf-----input-I- indicateur de la nature du sol |
|
25 |
c knon-----input-I- nombre de points a traiter |
integer, intent(in):: nsrf ! indicateur de la nature du sol |
26 |
c paprs----input-R- pression a chaque intercouche (en Pa) |
INTEGER, intent(in):: knon ! nombre de points a traiter |
27 |
c pplay----input-R- pression au milieu de chaque couche (en Pa) |
|
28 |
c ts-------input-R- temperature du sol (en Kelvin) |
REAL, intent(in):: paprs(klon, klev+1) |
29 |
c rugos----input-R- longeur de rugosite (en m) |
! pression a chaque intercouche (en Pa) |
30 |
c u--------input-R- vitesse u |
|
31 |
c v--------input-R- vitesse v |
real, intent(in):: pplay(klon, klev) |
32 |
c t--------input-R- temperature (K) |
! pression au milieu de chaque couche (en Pa) |
33 |
c q--------input-R- vapeur d'eau (kg/kg) |
|
34 |
c |
REAL, intent(in):: ksta, ksta_ter |
35 |
c itop-----output-I- numero de couche du sommet de la couche limite |
REAL, intent(in):: ts(klon) ! temperature du sol (en Kelvin) |
36 |
c pcfm-----output-R- coefficients a calculer (vitesse) |
REAL, intent(in):: rugos(klon) ! longeur de rugosite (en m) |
37 |
c pcfh-----output-R- coefficients a calculer (chaleur et humidite) |
REAL, intent(in):: u(klon, klev), v(klon, klev) ! wind |
38 |
c====================================================================== |
REAL, intent(in):: t(klon, klev) ! temperature (K) |
39 |
c |
real, intent(in):: q(klon, klev) ! vapeur d'eau (kg/kg) |
40 |
c Arguments: |
real, intent(in):: qsurf(klon) |
41 |
c |
REAL, intent(inout):: pcfm(klon, klev) ! coefficient, vitesse |
42 |
INTEGER knon, nsrf |
real, intent(inout):: pcfh(klon, klev) ! coefficient, chaleur et humidité |
43 |
REAL ts(klon) |
|
44 |
REAL paprs(klon,klev+1), pplay(klon,klev) |
! Local: |
45 |
REAL u(klon,klev), v(klon,klev), t(klon,klev), q(klon,klev) |
|
46 |
REAL rugos(klon) |
INTEGER itop(klon) ! numero de couche du sommet de la couche limite |
47 |
c |
|
48 |
REAL pcfm(klon,klev), pcfh(klon,klev) |
! Quelques constantes et options: |
49 |
INTEGER itop(klon) |
|
50 |
c |
REAL, PARAMETER:: cepdu2 =0.1**2 |
51 |
c Quelques constantes et options: |
REAL, PARAMETER:: CKAP = 0.4 |
52 |
c |
REAL, PARAMETER:: cb = 5. |
53 |
REAL cepdu2, ckap, cb, cc, cd, clam |
REAL, PARAMETER:: cc = 5. |
54 |
PARAMETER (cepdu2 =(0.1)**2) |
REAL, PARAMETER:: cd = 5. |
55 |
PARAMETER (CKAP=0.4) |
REAL, PARAMETER:: clam = 160. |
56 |
PARAMETER (cb=5.0) |
REAL, PARAMETER:: ratqs = 0.05 ! ! largeur de distribution de vapeur d'eau |
57 |
PARAMETER (cc=5.0) |
LOGICAL, PARAMETER:: richum = .TRUE. ! utilise le nombre de Richardson humide |
58 |
PARAMETER (cd=5.0) |
REAL, PARAMETER:: ric = 0.4 ! nombre de Richardson critique |
59 |
PARAMETER (clam=160.0) |
REAL, PARAMETER:: prandtl = 0.4 |
60 |
REAL ratqs ! largeur de distribution de vapeur d'eau |
|
61 |
PARAMETER (ratqs=0.05) |
REAL kstable ! diffusion minimale (situation stable) |
62 |
LOGICAL richum ! utilise le nombre de Richardson humide |
REAL, PARAMETER:: mixlen = 35. ! constante controlant longueur de melange |
63 |
PARAMETER (richum=.TRUE.) |
INTEGER, PARAMETER:: isommet = klev ! le sommet de la couche limite |
64 |
REAL ric ! nombre de Richardson critique |
|
65 |
PARAMETER(ric=0.4) |
LOGICAL, PARAMETER:: tvirtu = .TRUE. |
66 |
REAL prandtl |
! calculer Ri d'une maniere plus performante |
67 |
PARAMETER (prandtl=0.4) |
|
68 |
REAL kstable ! diffusion minimale (situation stable) |
LOGICAL, PARAMETER:: opt_ec = .FALSE. |
69 |
! GKtest |
! formule du Centre Europeen dans l'atmosphere |
70 |
! PARAMETER (kstable=1.0e-10) |
|
71 |
REAL ksta, ksta_ter |
INTEGER i, k, kk |
72 |
cIM: 261103 REAL kstable_ter, kstable_sinon |
REAL zgeop(klon, klev) |
73 |
cIM: 211003 cf GK PARAMETER (kstable_ter = 1.0e-6) |
REAL zmgeom(klon) |
74 |
cIM: 261103 PARAMETER (kstable_ter = 1.0e-8) |
REAL zri(klon) |
75 |
cIM: 261103 PARAMETER (kstable_ter = 1.0e-10) |
REAL zl2(klon) |
76 |
cIM: 261103 PARAMETER (kstable_sinon = 1.0e-10) |
|
77 |
! fin GKtest |
REAL u1(klon), v1(klon), t1(klon), q1(klon), z1(klon) |
78 |
REAL mixlen ! constante controlant longueur de melange |
REAL pcfm1(klon), pcfh1(klon) |
79 |
PARAMETER (mixlen=35.0) |
|
80 |
INTEGER isommet ! le sommet de la couche limite |
REAL zdphi, zdu2, ztvd, ztvu, zcdn |
81 |
PARAMETER (isommet=klev) |
REAL zscf |
82 |
LOGICAL tvirtu ! calculer Ri d'une maniere plus performante |
REAL zt, zq, zdelta, zcvm5, zcor, zqs, zfr, zdqs |
83 |
PARAMETER (tvirtu=.TRUE.) |
REAL z2geomf, zalh2, zalm2, zscfh, zscfm |
84 |
LOGICAL opt_ec ! formule du Centre Europeen dans l'atmosphere |
REAL, PARAMETER:: t_coup = 273.15 |
85 |
PARAMETER (opt_ec=.FALSE.) |
REAL gamt(2:klev) ! contre-gradient pour la chaleur sensible: Kelvin/metre |
86 |
|
|
87 |
c |
!-------------------------------------------------------------------- |
88 |
c Variables locales: |
|
89 |
c |
! Initialiser les sorties |
90 |
INTEGER i, k, kk !IM 120704 |
DO k = 1, klev |
91 |
REAL zgeop(klon,klev) |
DO i = 1, knon |
92 |
REAL zmgeom(klon) |
pcfm(i, k) = 0. |
93 |
REAL zri(klon) |
pcfh(i, k) = 0. |
94 |
REAL zl2(klon) |
ENDDO |
95 |
|
ENDDO |
96 |
REAL u1(klon), v1(klon), t1(klon), q1(klon), z1(klon) |
DO i = 1, knon |
97 |
REAL pcfm1(klon), pcfh1(klon) |
itop(i) = 0 |
98 |
c |
ENDDO |
99 |
REAL zdphi, zdu2, ztvd, ztvu, zcdn |
|
100 |
REAL zscf |
! Prescrire la valeur de contre-gradient |
101 |
REAL zt, zq, zdelta, zcvm5, zcor, zqs, zfr, zdqs |
if (iflag_pbl.eq.1) then |
102 |
REAL z2geomf, zalh2, zalm2, zscfh, zscfm |
DO k = 3, klev |
103 |
REAL t_coup |
gamt(k) = -1.0E-03 |
104 |
PARAMETER (t_coup=273.15) |
ENDDO |
105 |
cIM |
gamt(2) = -2.5E-03 |
106 |
LOGICAL check |
else |
107 |
PARAMETER (check=.false.) |
DO k = 2, klev |
108 |
c |
gamt(k) = 0.0 |
109 |
c contre-gradient pour la chaleur sensible: Kelvin/metre |
ENDDO |
110 |
REAL gamt(2:klev) |
ENDIF |
111 |
real qsurf(klon) |
|
112 |
c |
IF ( nsrf .NE. is_oce ) THEN |
113 |
LOGICAL appel1er |
kstable = ksta_ter |
114 |
SAVE appel1er |
ELSE |
115 |
c |
kstable = ksta |
116 |
c Fonctions thermodynamiques et fonctions d'instabilite |
ENDIF |
117 |
REAL fsta, fins, x |
|
118 |
LOGICAL zxli ! utiliser un jeu de fonctions simples |
! Calculer les géopotentiels de chaque couche |
119 |
PARAMETER (zxli=.FALSE.) |
DO i = 1, knon |
120 |
c |
zgeop(i, 1) = RD * t(i, 1) / (0.5 * (paprs(i, 1) + pplay(i, 1))) & |
121 |
fsta(x) = 1.0 / (1.0+10.0*x*(1+8.0*x)) |
* (paprs(i, 1) - pplay(i, 1)) |
122 |
fins(x) = SQRT(1.0-18.0*x) |
ENDDO |
123 |
c |
DO k = 2, klev |
124 |
DATA appel1er /.TRUE./ |
DO i = 1, knon |
125 |
c |
zgeop(i, k) = zgeop(i, k-1) & |
126 |
IF (appel1er) THEN |
+ RD * 0.5*(t(i, k-1)+t(i, k)) / paprs(i, k) & |
127 |
if (prt_level > 9) THEN |
* (pplay(i, k-1)-pplay(i, k)) |
128 |
print *,'coefkz, opt_ec:', opt_ec |
ENDDO |
129 |
print *,'coefkz, richum:', richum |
ENDDO |
130 |
IF (richum) print *,'coefkz, ratqs:', ratqs |
|
131 |
print *,'coefkz, isommet:', isommet |
! Calculer le frottement au sol (Cdrag) |
132 |
print *,'coefkz, tvirtu:', tvirtu |
|
133 |
appel1er = .FALSE. |
DO i = 1, knon |
134 |
endif |
u1(i) = u(i, 1) |
135 |
ENDIF |
v1(i) = v(i, 1) |
136 |
c |
t1(i) = t(i, 1) |
137 |
c Initialiser les sorties |
q1(i) = q(i, 1) |
138 |
c |
z1(i) = zgeop(i, 1) |
139 |
DO k = 1, klev |
ENDDO |
140 |
DO i = 1, knon |
|
141 |
pcfm(i,k) = 0.0 |
CALL clcdrag(klon, knon, nsrf, .false., u1, v1, t1, q1, z1, ts, qsurf, & |
142 |
pcfh(i,k) = 0.0 |
rugos, pcfm1, pcfh1) |
143 |
ENDDO |
|
144 |
ENDDO |
DO i = 1, knon |
145 |
DO i = 1, knon |
pcfm(i, 1) = pcfm1(i) |
146 |
itop(i) = 0 |
pcfh(i, 1) = pcfh1(i) |
147 |
ENDDO |
ENDDO |
148 |
|
|
149 |
c |
! Calculer les coefficients turbulents dans l'atmosphere |
150 |
c Prescrire la valeur de contre-gradient |
|
151 |
c |
DO i = 1, knon |
152 |
if (iflag_pbl.eq.1) then |
itop(i) = isommet |
153 |
DO k = 3, klev |
ENDDO |
154 |
gamt(k) = -1.0E-03 |
|
155 |
ENDDO |
loop_vertical: DO k = 2, isommet |
156 |
gamt(2) = -2.5E-03 |
loop_horiz: DO i = 1, knon |
157 |
else |
zdu2 = MAX(cepdu2, (u(i, k)-u(i, k-1))**2 & |
158 |
DO k = 2, klev |
+(v(i, k)-v(i, k-1))**2) |
159 |
gamt(k) = 0.0 |
zmgeom(i) = zgeop(i, k)-zgeop(i, k-1) |
160 |
ENDDO |
zdphi =zmgeom(i) / 2.0 |
161 |
ENDIF |
zt = (t(i, k)+t(i, k-1)) * 0.5 |
162 |
cIM cf JLD/ GKtest |
zq = (q(i, k)+q(i, k-1)) * 0.5 |
163 |
IF ( nsrf .NE. is_oce ) THEN |
|
164 |
cIM 261103 kstable = kstable_ter |
! calculer Qs et dQs/dT: |
165 |
kstable = ksta_ter |
|
166 |
ELSE |
IF (thermcep) THEN |
167 |
cIM 261103 kstable = kstable_sinon |
zdelta = MAX(0., SIGN(1., RTT-zt)) |
168 |
kstable = ksta |
zcvm5 = R5LES*RLVTT/RCPD/(1.0+RVTMP2*zq)*(1.-zdelta) & |
169 |
ENDIF |
+ R5IES*RLSTT/RCPD/(1.0+RVTMP2*zq)*zdelta |
170 |
cIM cf JLD/ GKtest fin |
zqs = R2ES * FOEEW(zt, zdelta) / pplay(i, k) |
171 |
c |
zqs = MIN(0.5, zqs) |
172 |
c Calculer les geopotentiels de chaque couche |
zcor = 1./(1.-RETV*zqs) |
173 |
c |
zqs = zqs*zcor |
174 |
DO i = 1, knon |
zdqs = FOEDE(zt, zdelta, zcvm5, zqs, zcor) |
175 |
zgeop(i,1) = RD * t(i,1) / (0.5*(paprs(i,1)+pplay(i,1))) |
ELSE |
176 |
. * (paprs(i,1)-pplay(i,1)) |
IF (zt .LT. t_coup) THEN |
177 |
ENDDO |
zqs = qsats(zt) / pplay(i, k) |
178 |
DO k = 2, klev |
zdqs = dqsats(zt, zqs) |
179 |
DO i = 1, knon |
ELSE |
180 |
zgeop(i,k) = zgeop(i,k-1) |
zqs = qsatl(zt) / pplay(i, k) |
181 |
. + RD * 0.5*(t(i,k-1)+t(i,k)) / paprs(i,k) |
zdqs = dqsatl(zt, zqs) |
182 |
. * (pplay(i,k-1)-pplay(i,k)) |
ENDIF |
183 |
ENDDO |
ENDIF |
184 |
ENDDO |
|
185 |
c |
! calculer la fraction nuageuse (processus humide): |
186 |
c Calculer le frottement au sol (Cdrag) |
|
187 |
c |
zfr = (zq+ratqs*zq-zqs) / (2.0*ratqs*zq) |
188 |
DO i = 1, knon |
zfr = MAX(0.0, MIN(1.0, zfr)) |
189 |
u1(i) = u(i,1) |
IF (.NOT.richum) zfr = 0.0 |
190 |
v1(i) = v(i,1) |
|
191 |
t1(i) = t(i,1) |
! calculer le nombre de Richardson: |
192 |
q1(i) = q(i,1) |
|
193 |
z1(i) = zgeop(i,1) |
IF (tvirtu) THEN |
194 |
ENDDO |
ztvd =( t(i, k) & |
195 |
c |
+ zdphi/RCPD/(1.+RVTMP2*zq) & |
196 |
CALL clcdrag(klon, knon, nsrf, zxli, |
*( (1.-zfr) + zfr*(1.+RLVTT*zqs/RD/zt)/(1.+zdqs) ) & |
197 |
$ u1, v1, t1, q1, z1, |
)*(1.+RETV*q(i, k)) |
198 |
$ ts, qsurf, rugos, |
ztvu =( t(i, k-1) & |
199 |
$ pcfm1, pcfh1) |
- zdphi/RCPD/(1.+RVTMP2*zq) & |
200 |
cIM $ ts, qsurf, rugos, |
*( (1.-zfr) + zfr*(1.+RLVTT*zqs/RD/zt)/(1.+zdqs) ) & |
201 |
C |
)*(1.+RETV*q(i, k-1)) |
202 |
DO i = 1, knon |
zri(i) =zmgeom(i)*(ztvd-ztvu)/(zdu2*0.5*(ztvd+ztvu)) |
203 |
pcfm(i,1)=pcfm1(i) |
zri(i) = zri(i) & |
204 |
pcfh(i,1)=pcfh1(i) |
+ zmgeom(i)*zmgeom(i)/RG*gamt(k) & |
205 |
ENDDO |
*(paprs(i, k)/101325.0)**RKAPPA & |
206 |
c |
/(zdu2*0.5*(ztvd+ztvu)) |
207 |
c Calculer les coefficients turbulents dans l'atmosphere |
ELSE |
208 |
c |
! calcul de Ridchardson compatible LMD5 |
209 |
DO i = 1, knon |
zri(i) =(RCPD*(t(i, k)-t(i, k-1)) & |
210 |
itop(i) = isommet |
-RD*0.5*(t(i, k)+t(i, k-1))/paprs(i, k) & |
211 |
ENDDO |
*(pplay(i, k)-pplay(i, k-1)) & |
212 |
|
)*zmgeom(i)/(zdu2*0.5*RCPD*(t(i, k-1)+t(i, k))) |
213 |
|
zri(i) = zri(i) + & |
214 |
DO k = 2, isommet |
zmgeom(i)*zmgeom(i)*gamt(k)/RG & |
215 |
DO i = 1, knon |
*(paprs(i, k)/101325.0)**RKAPPA & |
216 |
zdu2=MAX(cepdu2,(u(i,k)-u(i,k-1))**2 |
/(zdu2*0.5*(t(i, k-1)+t(i, k))) |
217 |
. +(v(i,k)-v(i,k-1))**2) |
ENDIF |
218 |
zmgeom(i)=zgeop(i,k)-zgeop(i,k-1) |
|
219 |
zdphi =zmgeom(i) / 2.0 |
! finalement, les coefficients d'echange sont obtenus: |
220 |
zt = (t(i,k)+t(i,k-1)) * 0.5 |
|
221 |
zq = (q(i,k)+q(i,k-1)) * 0.5 |
zcdn = SQRT(zdu2) / zmgeom(i) * RG |
222 |
c |
|
|
c calculer Qs et dQs/dT: |
|
|
c |
|
|
IF (thermcep) THEN |
|
|
zdelta = MAX(0.,SIGN(1.,RTT-zt)) |
|
|
zcvm5 = R5LES*RLVTT/RCPD/(1.0+RVTMP2*zq)*(1.-zdelta) |
|
|
. + R5IES*RLSTT/RCPD/(1.0+RVTMP2*zq)*zdelta |
|
|
zqs = R2ES * FOEEW(zt,zdelta) / pplay(i,k) |
|
|
zqs = MIN(0.5,zqs) |
|
|
zcor = 1./(1.-RETV*zqs) |
|
|
zqs = zqs*zcor |
|
|
zdqs = FOEDE(zt,zdelta,zcvm5,zqs,zcor) |
|
|
ELSE |
|
|
IF (zt .LT. t_coup) THEN |
|
|
zqs = qsats(zt) / pplay(i,k) |
|
|
zdqs = dqsats(zt,zqs) |
|
|
ELSE |
|
|
zqs = qsatl(zt) / pplay(i,k) |
|
|
zdqs = dqsatl(zt,zqs) |
|
|
ENDIF |
|
|
ENDIF |
|
|
c |
|
|
c calculer la fraction nuageuse (processus humide): |
|
|
c |
|
|
zfr = (zq+ratqs*zq-zqs) / (2.0*ratqs*zq) |
|
|
zfr = MAX(0.0,MIN(1.0,zfr)) |
|
|
IF (.NOT.richum) zfr = 0.0 |
|
|
c |
|
|
c calculer le nombre de Richardson: |
|
|
c |
|
|
IF (tvirtu) THEN |
|
|
ztvd =( t(i,k) |
|
|
. + zdphi/RCPD/(1.+RVTMP2*zq) |
|
|
. *( (1.-zfr) + zfr*(1.+RLVTT*zqs/RD/zt)/(1.+zdqs) ) |
|
|
. )*(1.+RETV*q(i,k)) |
|
|
ztvu =( t(i,k-1) |
|
|
. - zdphi/RCPD/(1.+RVTMP2*zq) |
|
|
. *( (1.-zfr) + zfr*(1.+RLVTT*zqs/RD/zt)/(1.+zdqs) ) |
|
|
. )*(1.+RETV*q(i,k-1)) |
|
|
zri(i) =zmgeom(i)*(ztvd-ztvu)/(zdu2*0.5*(ztvd+ztvu)) |
|
|
zri(i) = zri(i) |
|
|
. + zmgeom(i)*zmgeom(i)/RG*gamt(k) |
|
|
. *(paprs(i,k)/101325.0)**RKAPPA |
|
|
. /(zdu2*0.5*(ztvd+ztvu)) |
|
|
c |
|
|
ELSE ! calcul de Ridchardson compatible LMD5 |
|
|
c |
|
|
zri(i) =(RCPD*(t(i,k)-t(i,k-1)) |
|
|
. -RD*0.5*(t(i,k)+t(i,k-1))/paprs(i,k) |
|
|
. *(pplay(i,k)-pplay(i,k-1)) |
|
|
. )*zmgeom(i)/(zdu2*0.5*RCPD*(t(i,k-1)+t(i,k))) |
|
|
zri(i) = zri(i) + |
|
|
. zmgeom(i)*zmgeom(i)*gamt(k)/RG |
|
|
cSB . /(paprs(i,k)/101325.0)**RKAPPA |
|
|
. *(paprs(i,k)/101325.0)**RKAPPA |
|
|
. /(zdu2*0.5*(t(i,k-1)+t(i,k))) |
|
|
ENDIF |
|
|
c |
|
|
c finalement, les coefficients d'echange sont obtenus: |
|
|
c |
|
|
zcdn=SQRT(zdu2) / zmgeom(i) * RG |
|
|
c |
|
223 |
IF (opt_ec) THEN |
IF (opt_ec) THEN |
224 |
z2geomf=zgeop(i,k-1)+zgeop(i,k) |
z2geomf = zgeop(i, k-1)+zgeop(i, k) |
225 |
zalm2=(0.5*ckap/RG*z2geomf |
zalm2 = (0.5*ckap/RG*z2geomf & |
226 |
. /(1.+0.5*ckap/rg/clam*z2geomf))**2 |
/(1.+0.5*ckap/rg/clam*z2geomf))**2 |
227 |
zalh2=(0.5*ckap/rg*z2geomf |
zalh2 = (0.5*ckap/rg*z2geomf & |
228 |
. /(1.+0.5*ckap/RG/(clam*SQRT(1.5*cd))*z2geomf))**2 |
/(1.+0.5*ckap/RG/(clam*SQRT(1.5*cd))*z2geomf))**2 |
229 |
IF (zri(i).LT.0.0) THEN ! situation instable |
IF (zri(i).LT.0.0) THEN |
230 |
zscf = ((zgeop(i,k)/zgeop(i,k-1))**(1./3.)-1.)**3 |
! situation instable |
231 |
. / (zmgeom(i)/RG)**3 / (zgeop(i,k-1)/RG) |
zscf = ((zgeop(i, k)/zgeop(i, k-1))**(1./3.)-1.)**3 & |
232 |
zscf = SQRT(-zri(i)*zscf) |
/ (zmgeom(i)/RG)**3 / (zgeop(i, k-1)/RG) |
233 |
zscfm = 1.0 / (1.0+3.0*cb*cc*zalm2*zscf) |
zscf = SQRT(-zri(i)*zscf) |
234 |
zscfh = 1.0 / (1.0+3.0*cb*cc*zalh2*zscf) |
zscfm = 1.0 / (1.0+3.0*cb*cc*zalm2*zscf) |
235 |
pcfm(i,k)=zcdn*zalm2*(1.-2.0*cb*zri(i)*zscfm) |
zscfh = 1.0 / (1.0+3.0*cb*cc*zalh2*zscf) |
236 |
pcfh(i,k)=zcdn*zalh2*(1.-3.0*cb*zri(i)*zscfh) |
pcfm(i, k) = zcdn*zalm2*(1.-2.0*cb*zri(i)*zscfm) |
237 |
ELSE ! situation stable |
pcfh(i, k) = zcdn*zalh2*(1.-3.0*cb*zri(i)*zscfh) |
238 |
zscf=SQRT(1.+cd*zri(i)) |
ELSE |
239 |
pcfm(i,k)=zcdn*zalm2/(1.+2.0*cb*zri(i)/zscf) |
! situation stable |
240 |
pcfh(i,k)=zcdn*zalh2/(1.+3.0*cb*zri(i)*zscf) |
zscf = SQRT(1.+cd*zri(i)) |
241 |
ENDIF |
pcfm(i, k) = zcdn*zalm2/(1.+2.0*cb*zri(i)/zscf) |
242 |
|
pcfh(i, k) = zcdn*zalh2/(1.+3.0*cb*zri(i)*zscf) |
243 |
|
ENDIF |
244 |
ELSE |
ELSE |
245 |
zl2(i)=(mixlen*MAX(0.0,(paprs(i,k)-paprs(i,itop(i)+1)) |
zl2(i) = (mixlen*MAX(0.0, (paprs(i, k)-paprs(i, itop(i)+1)) & |
246 |
. /(paprs(i,2)-paprs(i,itop(i)+1)) ))**2 |
/(paprs(i, 2)-paprs(i, itop(i)+1)) ))**2 |
247 |
pcfm(i,k)=sqrt(max(zcdn*zcdn*(ric-zri(i))/ric, kstable)) |
pcfm(i, k) = sqrt(max(zcdn*zcdn*(ric-zri(i))/ric, kstable)) |
248 |
pcfm(i,k)= zl2(i)* pcfm(i,k) |
pcfm(i, k)= zl2(i)* pcfm(i, k) |
249 |
pcfh(i,k) = pcfm(i,k) /prandtl ! h et m different |
pcfh(i, k) = pcfm(i, k) /prandtl ! h et m different |
250 |
ENDIF |
ENDIF |
251 |
ENDDO |
ENDDO loop_horiz |
252 |
ENDDO |
ENDDO loop_vertical |
253 |
c |
|
254 |
c Au-dela du sommet, pas de diffusion turbulente: |
! Au-dela du sommet, pas de diffusion turbulente: |
255 |
c |
|
256 |
DO i = 1, knon |
DO i = 1, knon |
257 |
IF (itop(i)+1 .LE. klev) THEN |
IF (itop(i)+1 .LE. klev) THEN |
258 |
DO k = itop(i)+1, klev |
DO k = itop(i)+1, klev |
259 |
pcfh(i,k) = 0.0 |
pcfh(i, k) = 0. |
260 |
pcfm(i,k) = 0.0 |
pcfm(i, k) = 0. |
261 |
ENDDO |
ENDDO |
262 |
ENDIF |
ENDIF |
263 |
ENDDO |
ENDDO |
264 |
c |
|
265 |
RETURN |
END SUBROUTINE coefkz |
266 |
END |
|
267 |
|
end module coefkz_m |