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ocean_albedo.F90 @ 2677

Last change on this file since 2677 was 2677, checked in by oboucher, 8 years ago
Reorganization of ocean_albedo.F90 calculation to speed up calculations. Should be byte comparable. And speed up the routine by about 25-30%.
File size: 9.7 KB

Line
1	!
2	! $Id$
3	!
4
5	SUBROUTINE ocean_albedo(knon,zrmu0,knindex,pwind,SFRWL,alb_dir_new,alb_dif_new)
6	!!
7	!!**** ALBEDO_RS14
8	!!
9	!! PURPOSE
10	!! -------
11	!! computes the direct & diffuse albedo over open water
12	!!
13	!!** METHOD
14	!! ------
15	!!
16	!! EXTERNAL
17	!! --------
18	!!
19	!! IMPLICIT ARGUMENTS
20	!! ------------------
21	!!
22	!! REFERENCE
23	!! ---------
24	!!
25	!! AUTHOR
26	!! ------
27	!! R. Séférian * Meteo-France *
28	!!
29	!! MODIFICATIONS
30	!! -------------
31	!! Original 03/2014
32	!! 05/2014 R. Séférian & B. Decharme :: Adaptation to spectral
33	!! computation for diffuse and direct albedo
34	!! 08/2014 S. Baek :: for wider wavelength range 200-4000nm and
35	!! adaptation to LMDZ + whitecap effect by Koepke + chrolophyll
36	!! map from climatology file
37	!! 10/2016 O. Boucher :: some optimisation following R.
38	!! Seferian's work in the CNRM Model
39	!!
40	!-------------------------------------------------------------------------------
41	!
42	!* DECLARATIONS
43	! ------------
44	!
45	USE ocean_albedo_para
46	USE dimphy
47	USE phys_state_var_mod, ONLY : chl_con
48	!
49	!
50	IMPLICIT NONE
51	!
52	!* 0.1 declarations of arguments
53	! -------------------------
54	!
55	include "clesphys.h"
56	!
57	INTEGER, INTENT(IN) :: knon
58	INTEGER, DIMENSION(klon), INTENT(IN) :: knindex
59	REAL, DIMENSION(klon), INTENT(IN) :: zrmu0 !--cos(SZA) on full vector
60	REAL, DIMENSION(klon), INTENT(IN) :: pwind !--wind speed on compressed vector
61	REAL, DIMENSION(6),INTENT(IN) :: SFRWL
62	REAL, DIMENSION(klon,nsw), INTENT(OUT) :: alb_dir_new, alb_dif_new
63	!
64	!* 0.2 declarations of local variables
65	! -------------------------
66	!
67	REAL, DIMENSION(klon) :: ZCHL ! surface chlorophyll
68	REAL, DIMENSION(klon) :: ZCOSZEN ! Cosine of the zenith solar angle
69	!
70	INTEGER :: JWL, INU ! indexes
71	REAL :: ZWL ! input parameter: wavelength and diffuse/direct fraction of light
72	REAL:: ZCHLABS, ZAW, ZBW, ZREFM, ZYLMD ! scalar computation variables
73	!
74	REAL, DIMENSION(klon) :: ZAP, ZXX2, ZR00, ZRR0, ZRRR ! computation variables
75	REAL, DIMENSION(klon) :: ZR22, ZUE, ZUE2, ZR11DF, ZALBT ! computation variables
76	REAL, DIMENSION(klon) :: ZBBP, ZNU, ZHB ! computation variables
77	REAL, DIMENSION(klon) :: ZR11, ZRW, ZRWDF, ZRDF ! 4 components of the OSA
78	REAL, DIMENSION(klon) :: ZSIG, ZFWC, ZWORK1, ZWORK2, ZWORK3
79	!
80	!--initialisations-------------
81	!
82	alb_dir_new(:,:) = 0.
83	alb_dif_new(:,:) = 0.
84	!
85	! Initialisation of chlorophyll content
86	! ZCHL(:) = CHL_CON!0.05 ! averaged global values for surface chlorophyll
87	IF (ok_chlorophyll) THEN
88	ZCHL(1:knon)=CHL_CON(knindex(1:knon))
89	ELSE
90	ZCHL(1:knon) = 0.05
91	ENDIF
92
93	! variables that do not depend on wavelengths
94	! loop over the grid points
95	! functions of chlorophyll content
96	ZWORK1(1:knon)= EXP(LOG(ZCHL(1:knon))*0.65)
97	ZWORK2(1:knon)= 0.416 * EXP(LOG(ZCHL(1:knon))*0.766)
98	ZWORK3(1:knon)= LOG10(ZCHL(1:knon))
99	! store the cosine of the solar zenith angle
100	ZCOSZEN(1:knon) = zrmu0(knindex(1:knon))
101	! Compute sigma derived from wind speed (Cox & Munk reflectance model)
102	ZSIG(1:knon)=SQRT(0.003+0.00512*PWIND(1:knon))
103	! original : correction for foam (Eq 16-17)
104	! has to be update once we have information from wave model (discussion with G. Madec)
105	ZFWC(1:knon)=3.97e-4PWIND(1:knon)*1.59 ! Salisbury 2014 eq(2) at 37GHz, value in fraction
106	!
107	DO JWL=1,NNWL ! loop over the wavelengths
108	!
109	!---------------------------------------------------------------------------------
110	! 0- Compute baseline values
111	!---------------------------------------------------------------------------------
112
113	! Get refractive index for the correspoding wavelength
114	ZWL=XAKWL(JWL) !!!--------- wavelength value
115	ZREFM= XAKREFM(JWL) !!!--------- refraction index value
116
117	!---------------------------------------------------------------------------------
118	! 1- Compute direct surface albedo (ZR11)
119	!---------------------------------------------------------------------------------
120	!
121	ZXX2(1:knon)=SQRT(1.0-(1.0-ZCOSZEN(1:knon)2)/ZREFM2)
122	ZRR0(1:knon)=0.50(((ZXX2(1:knon)-ZREFMZCOSZEN(1:knon))/(ZXX2(1:knon)+ZREFMZCOSZEN(1:knon)))*2 + &
123	((ZCOSZEN(1:knon)-ZREFMZXX2(1:knon))/(ZCOSZEN(1:knon)+ZREFMZXX2(1:knon)))**2)
124	ZRRR(1:knon)=0.50(((ZXX2(1:knon)-1.34ZCOSZEN(1:knon))/(ZXX2(1:knon)+1.34ZCOSZEN(1:knon)))*2 + &
125	((ZCOSZEN(1:knon)-1.34ZXX2(1:knon))/(ZCOSZEN(1:knon)+1.34ZXX2(1:knon)))**2)
126	ZR11(1:knon)=ZRR0(1:knon)-(0.0152-1.7873ZCOSZEN(1:knon)+6.8972ZCOSZEN(1:knon)*2-8.5778ZCOSZEN(1:knon)**3+ &
127	4.071ZSIG(1:knon)-7.6446ZCOSZEN(1:knon)ZSIG(1:knon)) &
128	EXP(0.1643-7.8409ZCOSZEN(1:knon)-3.5639ZCOSZEN(1:knon)*2-2.3588ZSIG(1:knon)+ &
129	10.0538ZCOSZEN(1:knon)ZSIG(1:knon))*ZRR0(1:knon)/ZRRR(1:knon)
130	!
131	!---------------------------------------------------------------------------------
132	! 2- Compute surface diffuse albedo (ZRDF)
133	!---------------------------------------------------------------------------------
134	! Diffuse albedo from Jin et al., 2006 + estimation from diffuse fraction of
135	! light (relying later on AOD). CNRM model has opted for Eq 5b
136	ZRDF(1:knon)=-0.1482-0.012ZSIG(1:knon)+0.1609ZREFM-0.0244ZSIG(1:knon)ZREFM ! surface diffuse (Eq 5a)
137	!!ZRDF(1:knon)=-0.1479+0.1502ZREFM-0.0176ZSIG(1:knon)*ZREFM ! surface diffuse (Eq 5b)
138
139	!---------------------------------------------------------------------------------
140	! *- Determine absorption and backscattering
141	! coefficients to determine reflectance below the surface (Ro) once for all
142	!
143	! *.1- Absorption by chlorophyll
144	ZCHLABS= XAKACHL(JWL)
145	! *.2- Absorption by seawater
146	ZAW= XAKAW3(JWL)
147	! *.3- Backscattering by seawater
148	ZBW= XAKBW(JWL)
149	! *.4- Backscattering by chlorophyll
150	ZYLMD = EXP(0.014*(440.0-ZWL))
151	ZAP(1:knon) = 0.06ZCHLABSZWORK1(1:knon) +0.2(XAW440+0.06ZWORK1(1:knon))*ZYLMD
152
153	WHERE ( ZCHL(1:knon) > 0.02 )
154	ZNU(:)=MIN(0.0,0.5*(ZWORK3(:)-0.3))
155	ZBBP(:)=(0.002+0.01(0.5-0.25ZWORK3(:))(ZWL/550.)ZNU)ZWORK2(:)
156	ELSEWHERE
157	ZBBP(:)=0.019(550./ZWL)ZWORK2(:) !ZBBPf=0.0113 at chl<=0.02
158	ENDWHERE
159
160	! Morel-Gentili(1991), Eq (12)
161	! ZHB=h/(h+2ZBBPf(1.-h))
162	ZHB(1:knon)=0.5ZBW/(0.5ZBW+ZBBP(1:knon))
163
164	!---------------------------------------------------------------------------------
165	! 3- Compute direct water-leaving albedo (ZRW)
166	!---------------------------------------------------------------------------------
167	! Based on Morel & Gentilli 1991 parametrization
168	ZR22(1:knon)=0.48168549-0.014894708ZSIG(1:knon)-0.20703885ZSIG(1:knon)**2
169
170	! Use Morel 91 formula to compute the direct reflectance
171	! below the surface
172	ZR00(1:knon)=(0.5ZBW+ZBBP(1:knon))/(ZAW+ZAP(1:knon)) &
173	(0.6279-0.2227ZHB(1:knon)-0.0513ZHB(1:knon)**2 + &
174	(-0.3119+0.2465ZHB(1:knon))ZCOSZEN(1:knon))
175	ZRW(1:knon)=ZR00(1:knon)(1.-ZR22(1:knon))/(1.-ZR00(1:knon)ZR22(1:knon))
176
177	!---------------------------------------------------------------------------------
178	! 4- Compute diffuse water-leaving albedo (ZRWDF)
179	!---------------------------------------------------------------------------------
180	! as previous water-leaving computation but assumes a uniform incidence of
181	! shortwave at surface (ue)
182	ZUE=0.676 ! equivalent u_unif for diffuse incidence
183	ZUE2=SQRT(1.0-(1.0-ZUE2)/ZREFM2)
184	ZRR0(1:knon)=0.50(((ZUE2-ZREFMZUE)/(ZUE2+ZREFMZUE))2 +((ZUE-ZREFMZUE2)/(ZUE+ZREFMZUE2))*2)
185	ZRRR(1:knon)=0.50(((ZUE2-1.34ZUE)/(ZUE2+1.34ZUE))2 +((ZUE-1.34ZUE2)/(ZUE+1.34ZUE2))*2)
186	ZR11DF(1:knon)=ZRR0(1:knon)-(0.0152-1.7873ZUE+6.8972ZUE*2-8.5778ZUE*3+4.071ZSIG(1:knon)-7.6446ZUEZSIG(1:knon)) * &
187	EXP(0.1643-7.8409ZUE-3.5639ZUE*2-2.3588ZSIG(1:knon)+10.0538ZUEZSIG(1:knon))*ZRR0(1:knon)/ZRRR(1:knon)
188
189	! Use Morel 91 formula to compute the diffuse
190	! reflectance below the surface
191	ZR00(1:knon)=(0.5ZBW+ZBBP(1:knon))/(ZAW+ZAP(1:knon))(0.6279-0.2227ZHB(1:knon)-0.0513ZHB(1:knon)*2 + (-0.3119+0.2465ZHB(1:knon))*ZUE)
192	ZRWDF(1:knon)=ZR00(1:knon)(1.-ZR22(1:knon))(1.-ZR11DF(1:knon))/(1.-ZR00(1:knon)*ZR22(1:knon))
193
194	! get waveband index inu for each nsw band
195	SELECT CASE(nsw)
196	CASE(2)
197	IF (JWL.LE.49) THEN ! from 200 to 680 nm
198	inu=1
199	ELSE ! from 690 to 4000 nm
200	inu=2
201	ENDIF
202	CASE(4)
203	IF (JWL.LE.49) THEN ! from 200 to 680 nm
204	inu=1
205	ELSE IF (JWL.LE.99) THEN ! from 690 to 1180 nm
206	inu=2
207	ELSE IF (JWL.LE.218) THEN ! from 1190 to 2370 nm
208	inu=3
209	ELSE ! from 2380 to 4000 nm
210	inu=4
211	ENDIF
212	CASE(6)
213	IF (JWL.LE.5) THEN ! from 200 to 240 nm
214	inu=1
215	ELSE IF (JWL.LE.24) THEN ! from 250 to 430 nm
216	inu=2
217	ELSE IF (JWL.LE.49) THEN ! from 440 to 680 nm
218	inu=3
219	ELSE IF (JWL.LE.99) THEN ! from 690 to 1180 nm
220	inu=4
221	ELSE IF (JWL.LE.218) THEN ! from 1190 to 2370 nm
222	inu=5
223	ELSE ! from 2380 to 4000 nm
224	inu=6
225	ENDIF
226	END SELECT
227
228	! partitionning direct and diffuse albedo
229	! excluding diffuse albedo ZRW on ZDIR_ALB
230
231	!--direct
232	alb_dir_new(1:knon,inu)=alb_dir_new(1:knon,inu) + &
233	( XFRWL(JWL) * ((1.-ZFWC(1:knon)) * (ZR11(1:knon)+ZRW(1:knon)) + ZFWC(1:knon)*XRWC(JWL)) )/SFRWL(inu)
234	!--diffuse
235	alb_dif_new(1:knon,inu)=alb_dif_new(1:knon,inu) + &
236	( XFRWL(JWL) * ((1.-ZFWC(1:knon)) * (ZRDF(1:knon)+ZRWDF(1:knon)) + ZFWC(1:knon)*XRWC(JWL)) )/SFRWL(inu)
237
238	ENDDO ! ending loop over wavelengths
239
240	END SUBROUTINE ocean_albedo

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