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rrtm_taumol4.F90 @ 4190

Last change on this file since 4190 was 3908, checked in by idelkadi, 3 years ago

Online implementation of the radiative transfer code ECRAD in the LMDZ model.

Inclusion of the ecrad directory containing the sources of the ECRAD code
- interface routine : radiation_scheme.F90
Adaptation of compilation scripts :
- compilation under CPP key CPP_ECRAD
- compilation with option "-rad ecard" or "-ecard true"
- The "-rad old/rtm/ecran" build option will need to replace the "-rrtm true" and "-ecrad true" options in the future.
Runing LMDZ simulations with ecrad, you need :
- logical key iflag_rrtm = 2 in physiq.def
- namelist_ecrad (DefLists?)
- the directory "data" containing the configuration files is temporarily placed in ../libfphylmd/ecrad/
Compilation and execution are tested in the 1D case. The repository under svn would allow to continue the implementation work: tests, verification of the results, ...

File size: 13.4 KB

Rev	Line
[3908]	1	!----------------------------------------------------------------------------
	2	SUBROUTINE RRTM_TAUMOL4 (KIDIA,KFDIA,KLEV,P_TAU,&
	3	& P_TAUAERL,P_FAC00,P_FAC01,P_FAC10,P_FAC11,P_FORFAC,P_FORFRAC,K_INDFOR,K_JP,K_JT,K_JT1,P_ONEMINUS,&
	4	& P_COLH2O,P_COLCO2,P_COLO3,K_LAYTROP,P_SELFFAC,P_SELFFRAC,K_INDSELF,PFRAC, &
	5	& P_RAT_H2OCO2, P_RAT_H2OCO2_1, P_RAT_O3CO2, P_RAT_O3CO2_1)
	6
	7	! BAND 4: 630-700 cm-1 (low - H2O,CO2; high - O3,CO2)
	8
	9	! AUTHOR.
	10	! -------
	11	! JJMorcrette, ECMWF
	12
	13	! MODIFICATIONS.
	14	! --------------
	15	! M.Hamrud 01-Oct-2003 CY28 Cleaning
	16	! NEC 25-Oct-2007 Optimisations
	17	! JJMorcrette 20110613 flexible number of g-points
	18	! ABozzo 201306 updated to rrtmg v4.85
	19	! ---------------------------------------------------------------------------
	20
	21	USE PARKIND1 ,ONLY : JPIM ,JPRB
	22	USE YOMHOOK ,ONLY : LHOOK, DR_HOOK
	23
	24	USE PARRRTM , ONLY : JPBAND
	25	USE YOERRTM , ONLY : JPGPT ,NG4 ,NGS3
	26	USE YOERRTWN , ONLY : NSPA ,NSPB
	27	USE YOERRTA4 , ONLY : ABSA ,ABSB ,FRACREFA, FRACREFB,SELFREF,FORREF
	28	USE YOERRTRF, ONLY : CHI_MLS
	29
	30	IMPLICIT NONE
	31
	32	INTEGER(KIND=JPIM),INTENT(IN) :: KIDIA
	33	INTEGER(KIND=JPIM),INTENT(IN) :: KFDIA
	34	INTEGER(KIND=JPIM),INTENT(IN) :: KLEV
	35	REAL(KIND=JPRB) ,INTENT(OUT) :: P_TAU(KIDIA:KFDIA,JPGPT,KLEV)
	36	REAL(KIND=JPRB) ,INTENT(IN) :: P_TAUAERL(KIDIA:KFDIA,KLEV,JPBAND)
	37	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC00(KIDIA:KFDIA,KLEV)
	38	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC01(KIDIA:KFDIA,KLEV)
	39	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC10(KIDIA:KFDIA,KLEV)
	40	REAL(KIND=JPRB) ,INTENT(IN) :: P_FAC11(KIDIA:KFDIA,KLEV)
	41	INTEGER(KIND=JPIM),INTENT(IN) :: K_JP(KIDIA:KFDIA,KLEV)
	42	INTEGER(KIND=JPIM),INTENT(IN) :: K_JT(KIDIA:KFDIA,KLEV)
	43	INTEGER(KIND=JPIM),INTENT(IN) :: K_JT1(KIDIA:KFDIA,KLEV)
	44	REAL(KIND=JPRB) ,INTENT(IN) :: P_ONEMINUS
	45	REAL(KIND=JPRB) ,INTENT(IN) :: P_COLH2O(KIDIA:KFDIA,KLEV)
	46	REAL(KIND=JPRB) ,INTENT(IN) :: P_COLCO2(KIDIA:KFDIA,KLEV)
	47	REAL(KIND=JPRB) ,INTENT(IN) :: P_COLO3(KIDIA:KFDIA,KLEV)
	48	INTEGER(KIND=JPIM),INTENT(IN) :: K_LAYTROP(KIDIA:KFDIA)
	49	REAL(KIND=JPRB) ,INTENT(IN) :: P_SELFFAC(KIDIA:KFDIA,KLEV)
	50	REAL(KIND=JPRB) ,INTENT(IN) :: P_SELFFRAC(KIDIA:KFDIA,KLEV)
	51	INTEGER(KIND=JPIM),INTENT(IN) :: K_INDSELF(KIDIA:KFDIA,KLEV)
	52	REAL(KIND=JPRB) ,INTENT(OUT) :: PFRAC(KIDIA:KFDIA,JPGPT,KLEV)
	53
	54	REAL(KIND=JPRB) ,INTENT(IN) :: P_RAT_H2OCO2(KIDIA:KFDIA,KLEV)
	55	REAL(KIND=JPRB) ,INTENT(IN) :: P_RAT_H2OCO2_1(KIDIA:KFDIA,KLEV)
	56	REAL(KIND=JPRB) ,INTENT(IN) :: P_RAT_O3CO2(KIDIA:KFDIA,KLEV)
	57	REAL(KIND=JPRB) ,INTENT(IN) :: P_RAT_O3CO2_1(KIDIA:KFDIA,KLEV)
	58	INTEGER(KIND=JPIM),INTENT(IN) :: K_INDFOR(KIDIA:KFDIA,KLEV)
	59	REAL(KIND=JPRB) ,INTENT(IN) :: P_FORFAC(KIDIA:KFDIA,KLEV)
	60	REAL(KIND=JPRB) ,INTENT(IN) :: P_FORFRAC(KIDIA:KFDIA,KLEV)
	61	! ---------------------------------------------------------------------------
	62
	63	REAL(KIND=JPRB) :: Z_SPECCOMB(KLEV),Z_SPECCOMB1(KLEV), Z_SPECCOMB_PLANCK(KLEV)
	64	INTEGER(KIND=JPIM) :: IND0(KLEV),IND1(KLEV),INDS(KLEV),INDF(KLEV)
	65
	66	INTEGER(KIND=JPIM) :: IG, JS, JLAY, JS1, JPL
	67	INTEGER(KIND=JPIM) :: JLON
	68
	69
	70	REAL(KIND=JPRB) :: ZREFRAT_PLANCK_A, ZREFRAT_PLANCK_B
	71	REAL(KIND=JPRB) :: Z_FAC000, Z_FAC100, Z_FAC200,&
	72	& Z_FAC010, Z_FAC110, Z_FAC210, &
	73	& Z_FAC001, Z_FAC101, Z_FAC201, &
	74	& Z_FAC011, Z_FAC111, Z_FAC211
	75	REAL(KIND=JPRB) :: ZP, ZP4, ZFK0, ZFK1, ZFK2
	76	REAL(KIND=JPRB) :: ZTAUFOR,ZTAUSELF,ZTAU_MAJOR,ZTAU_MAJOR1
	77	REAL(KIND=JPRB) :: Z_FS, Z_SPECMULT, Z_SPECPARM, &
	78	& Z_FS1, Z_SPECMULT1, Z_SPECPARM1, &
	79	& Z_FPL, Z_SPECMULT_PLANCK, Z_SPECPARM_PLANCK
	80
	81	REAL(KIND=JPRB) :: ZHOOK_HANDLE
	82
	83	! P = 142.5940 mb
	84	ZREFRAT_PLANCK_A = CHI_MLS(1,11)/CHI_MLS(2,11)
	85
	86	! P = 95.58350 mb
	87	ZREFRAT_PLANCK_B = CHI_MLS(3,13)/CHI_MLS(2,13)
	88
	89
	90	! Compute the optical depth by interpolating in ln(pressure),
	91	! temperature, and appropriate species. Below LAYTROP, the water
	92	! vapor self-continuum is interpolated (in temperature) separately.
	93
	94	ASSOCIATE(NFLEVG=>KLEV)
	95	IF (LHOOK) CALL DR_HOOK('RRTM_TAUMOL4',0,ZHOOK_HANDLE)
	96
	97	DO JLAY = 1, KLEV
	98	DO JLON = KIDIA, KFDIA
	99	IF (JLAY <= K_LAYTROP(JLON)) THEN
	100	Z_SPECCOMB(JLAY) = P_COLH2O(JLON,JLAY) + P_RAT_H2OCO2(JLON,JLAY)*P_COLCO2(JLON,JLAY)
	101	Z_SPECPARM = P_COLH2O(JLON,JLAY)/Z_SPECCOMB(JLAY)
	102	Z_SPECPARM=MIN(P_ONEMINUS,Z_SPECPARM)
	103	Z_SPECMULT = 8._JPRB*(Z_SPECPARM)
	104	JS = 1 + INT(Z_SPECMULT)
	105	Z_FS = MOD(Z_SPECMULT,1.0_JPRB)
	106
	107	Z_SPECCOMB1(JLAY) = P_COLH2O(JLON,JLAY) + P_RAT_H2OCO2_1(JLON,JLAY)*P_COLCO2(JLON,JLAY)
	108	Z_SPECPARM1 = P_COLH2O(JLON,JLAY)/Z_SPECCOMB1(JLAY)
	109	IF (Z_SPECPARM1 >= P_ONEMINUS) Z_SPECPARM1 = P_ONEMINUS
	110	Z_SPECMULT1 = 8._JPRB*(Z_SPECPARM1)
	111	JS1 = 1 + INT(Z_SPECMULT1)
	112	Z_FS1 = MOD(Z_SPECMULT1,1.0_JPRB)
	113
	114	Z_SPECCOMB_PLANCK(JLAY) = P_COLH2O(JLON,JLAY)+ZREFRAT_PLANCK_A*P_COLCO2(JLON,JLAY)
	115	Z_SPECPARM_PLANCK = P_COLH2O(JLON,JLAY)/Z_SPECCOMB_PLANCK(JLAY)
	116	IF (Z_SPECPARM_PLANCK >= P_ONEMINUS) Z_SPECPARM_PLANCK=P_ONEMINUS
	117	Z_SPECMULT_PLANCK = 8._JPRB*Z_SPECPARM_PLANCK
	118	JPL= 1 + INT(Z_SPECMULT_PLANCK)
	119	Z_FPL = MOD(Z_SPECMULT_PLANCK,1.0_JPRB)
	120
	121	IND0(JLAY) = ((K_JP(JLON,JLAY)-1)5+(K_JT(JLON,JLAY)-1))NSPA(4) + JS
	122	IND1(JLAY) = (K_JP(JLON,JLAY)5+(K_JT1(JLON,JLAY)-1))NSPA(4) + JS1
	123	INDS(JLAY) = K_INDSELF(JLON,JLAY)
	124	INDF(JLAY) = K_INDFOR(JLON,JLAY)
	125
	126	IF (Z_SPECPARM < 0.125_JPRB) THEN
	127	ZP = Z_FS - 1
	128	ZP4 = ZP**4
	129	ZFK0 = ZP4
	130	ZFK1 = 1 - ZP - 2.0_JPRB*ZP4
	131	ZFK2 = ZP + ZP4
	132	Z_FAC000 = ZFK0*P_FAC00(JLON,JLAY)
	133	Z_FAC100 = ZFK1*P_FAC00(JLON,JLAY)
	134	Z_FAC200 = ZFK2*P_FAC00(JLON,JLAY)
	135	Z_FAC010 = ZFK0*P_FAC10(JLON,JLAY)
	136	Z_FAC110 = ZFK1*P_FAC10(JLON,JLAY)
	137	Z_FAC210 = ZFK2*P_FAC10(JLON,JLAY)
	138	ELSEIF (Z_SPECPARM > 0.875_JPRB) THEN
	139	ZP = -Z_FS
	140	ZP4 = ZP**4
	141	ZFK0 = ZP4
	142	ZFK1 = 1 - ZP - 2.0_JPRB*ZP4
	143	ZFK2 = ZP + ZP4
	144	Z_FAC000 = ZFK0*P_FAC00(JLON,JLAY)
	145	Z_FAC100 = ZFK1*P_FAC00(JLON,JLAY)
	146	Z_FAC200 = ZFK2*P_FAC00(JLON,JLAY)
	147	Z_FAC010 = ZFK0*P_FAC10(JLON,JLAY)
	148	Z_FAC110 = ZFK1*P_FAC10(JLON,JLAY)
	149	Z_FAC210 = ZFK2*P_FAC10(JLON,JLAY)
	150	ELSE
	151	Z_FAC000 = (1._JPRB - Z_FS) * P_FAC00(JLON,JLAY)
	152	Z_FAC010 = (1._JPRB - Z_FS) * P_FAC10(JLON,JLAY)
	153	Z_FAC100 = Z_FS * P_FAC00(JLON,JLAY)
	154	Z_FAC110 = Z_FS * P_FAC10(JLON,JLAY)
	155	ENDIF
	156	IF (Z_SPECPARM1 < 0.125_JPRB) THEN
	157	ZP = Z_FS1 - 1
	158	ZP4 = ZP**4
	159	ZFK0 = ZP4
	160	ZFK1 = 1 - ZP - 2.0_JPRB*ZP4
	161	ZFK2 = ZP + ZP4
	162	Z_FAC001 = ZFK0*P_FAC01(JLON,JLAY)
	163	Z_FAC101 = ZFK1*P_FAC01(JLON,JLAY)
	164	Z_FAC201 = ZFK2*P_FAC01(JLON,JLAY)
	165	Z_FAC011 = ZFK0*P_FAC11(JLON,JLAY)
	166	Z_FAC111 = ZFK1*P_FAC11(JLON,JLAY)
	167	Z_FAC211 = ZFK2*P_FAC11(JLON,JLAY)
	168	ELSEIF (Z_SPECPARM1 > 0.875_JPRB) THEN
	169	ZP = -Z_FS1
	170	ZP4 = ZP**4
	171	ZFK0 = ZP4
	172	ZFK1 = 1 - ZP - 2.0_JPRB*ZP4
	173	ZFK2 = ZP + ZP4
	174	Z_FAC001 = ZFK0*P_FAC01(JLON,JLAY)
	175	Z_FAC101 = ZFK1*P_FAC01(JLON,JLAY)
	176	Z_FAC201 = ZFK2*P_FAC01(JLON,JLAY)
	177	Z_FAC011 = ZFK0*P_FAC11(JLON,JLAY)
	178	Z_FAC111 = ZFK1*P_FAC11(JLON,JLAY)
	179	Z_FAC211 = ZFK2*P_FAC11(JLON,JLAY)
	180	ELSE
	181	Z_FAC001 = (1._JPRB - Z_FS1) * P_FAC01(JLON,JLAY)
	182	Z_FAC011 = (1._JPRB - Z_FS1) * P_FAC11(JLON,JLAY)
	183	Z_FAC101 = Z_FS1 * P_FAC01(JLON,JLAY)
	184	Z_FAC111 = Z_FS1 * P_FAC11(JLON,JLAY)
	185	ENDIF
	186
	187
	188
	189	!-- DS_000515
	190	!CDIR UNROLL=NG4
	191	DO IG = 1, NG4
	192	!-- DS_000515
	193	ZTAUSELF = P_SELFFAC(JLON,JLAY)* (SELFREF(INDS(JLAY),IG) + P_SELFFRAC(JLON,JLAY) * &
	194	& (SELFREF(INDS(JLAY)+1,IG) - SELFREF(INDS(JLAY),IG)))
	195	ZTAUFOR = P_FORFAC(JLON,JLAY) * (FORREF(INDF(JLAY),IG) + P_FORFRAC(JLON,JLAY) * &
	196	& (FORREF(INDF(JLAY)+1,IG) - FORREF(INDF(JLAY),IG)))
	197
	198	IF (Z_SPECPARM < 0.125_JPRB) THEN
	199	ZTAU_MAJOR = Z_SPECCOMB(JLAY) * &
	200	& (Z_FAC000 * ABSA(IND0(JLAY),IG) + &
	201	& Z_FAC100 * ABSA(IND0(JLAY)+1,IG) + &
	202	& Z_FAC200 * ABSA(IND0(JLAY)+2,IG) + &
	203	& Z_FAC010 * ABSA(IND0(JLAY)+9,IG) + &
	204	& Z_FAC110 * ABSA(IND0(JLAY)+10,IG) + &
	205	& Z_FAC210 * ABSA(IND0(JLAY)+11,IG))
	206	ELSEIF (Z_SPECPARM > 0.875_JPRB) THEN
	207	ZTAU_MAJOR = Z_SPECCOMB(JLAY) * &
	208	& (Z_FAC200 * ABSA(IND0(JLAY)-1,IG) + &
	209	& Z_FAC100 * ABSA(IND0(JLAY),IG) + &
	210	& Z_FAC000 * ABSA(IND0(JLAY)+1,IG) + &
	211	& Z_FAC210 * ABSA(IND0(JLAY)+8,IG) + &
	212	& Z_FAC110 * ABSA(IND0(JLAY)+9,IG) + &
	213	& Z_FAC010 * ABSA(IND0(JLAY)+10,IG))
	214	ELSE
	215	ZTAU_MAJOR = Z_SPECCOMB(JLAY) * &
	216	& (Z_FAC000 * ABSA(IND0(JLAY),IG) + &
	217	& Z_FAC100 * ABSA(IND0(JLAY)+1,IG) + &
	218	& Z_FAC010 * ABSA(IND0(JLAY)+9,IG) + &
	219	& Z_FAC110 * ABSA(IND0(JLAY)+10,IG))
	220	ENDIF
	221
	222	IF (Z_SPECPARM1 < 0.125_JPRB) THEN
	223	ZTAU_MAJOR1 = Z_SPECCOMB1(JLAY) * &
	224	& (Z_FAC001 * ABSA(IND1(JLAY),IG) + &
	225	& Z_FAC101 * ABSA(IND1(JLAY)+1,IG) + &
	226	& Z_FAC201 * ABSA(IND1(JLAY)+2,IG) + &
	227	& Z_FAC011 * ABSA(IND1(JLAY)+9,IG) + &
	228	& Z_FAC111 * ABSA(IND1(JLAY)+10,IG) + &
	229	& Z_FAC211 * ABSA(IND1(JLAY)+11,IG))
	230	ELSEIF (Z_SPECPARM1 > 0.875_JPRB) THEN
	231	ZTAU_MAJOR1 = Z_SPECCOMB1(JLAY) * &
	232	& (Z_FAC201 * ABSA(IND1(JLAY)-1,IG) + &
	233	& Z_FAC101 * ABSA(IND1(JLAY),IG) + &
	234	& Z_FAC001 * ABSA(IND1(JLAY)+1,IG) + &
	235	& Z_FAC211 * ABSA(IND1(JLAY)+8,IG) + &
	236	& Z_FAC111 * ABSA(IND1(JLAY)+9,IG) + &
	237	& Z_FAC011 * ABSA(IND1(JLAY)+10,IG))
	238	ELSE
	239	ZTAU_MAJOR1 = Z_SPECCOMB1(JLAY) * &
	240	& (Z_FAC001 * ABSA(IND1(JLAY),IG) + &
	241	& Z_FAC101 * ABSA(IND1(JLAY)+1,IG) + &
	242	& Z_FAC011 * ABSA(IND1(JLAY)+9,IG) + &
	243	& Z_FAC111 * ABSA(IND1(JLAY)+10,IG))
	244	ENDIF
	245
	246
	247	P_TAU(JLON,NGS3+IG,JLAY) = ZTAU_MAJOR + ZTAU_MAJOR1 &
	248	& + ZTAUSELF + ZTAUFOR &
	249	& + P_TAUAERL(JLON,JLAY,4)
	250	PFRAC(JLON,NGS3+IG,JLAY) = FRACREFA(IG,JPL) + Z_FPL *&
	251	& (FRACREFA(IG,JPL+1) - FRACREFA(IG,JPL))
	252	ENDDO
	253	ENDIF
	254
	255	IF (JLAY > K_LAYTROP(JLON)) THEN
	256	Z_SPECCOMB(JLAY) = P_COLO3(JLON,JLAY) + P_RAT_O3CO2(JLON,JLAY)*P_COLCO2(JLON,JLAY)
	257	Z_SPECPARM = P_COLO3(JLON,JLAY)/Z_SPECCOMB(JLAY)
	258	Z_SPECPARM=MIN(P_ONEMINUS,Z_SPECPARM)
	259	Z_SPECMULT = 4._JPRB*(Z_SPECPARM)
	260	JS = 1 + INT(Z_SPECMULT)
	261	Z_FS = MOD(Z_SPECMULT,1.0_JPRB)
	262
	263	Z_SPECCOMB1(JLAY) = P_COLO3(JLON,JLAY) + P_RAT_O3CO2_1(JLON,JLAY)*P_COLCO2(JLON,JLAY)
	264	Z_SPECPARM1 = P_COLO3(JLON,JLAY)/Z_SPECCOMB1(JLAY)
	265	Z_SPECPARM1=MIN(P_ONEMINUS,Z_SPECPARM1)
	266	Z_SPECMULT1 = 4._JPRB*(Z_SPECPARM1)
	267	JS1 = 1 + INT(Z_SPECMULT1)
	268	Z_FS1 = MOD(Z_SPECMULT1,1.0_JPRB)
	269
	270	Z_FAC000 = (1._JPRB - Z_FS) * P_FAC00(JLON,JLAY)
	271	Z_FAC010 = (1._JPRB - Z_FS) * P_FAC10(JLON,JLAY)
	272	Z_FAC100 = Z_FS * P_FAC00(JLON,JLAY)
	273	Z_FAC110 = Z_FS * P_FAC10(JLON,JLAY)
	274	Z_FAC001 = (1._JPRB - Z_FS1) * P_FAC01(JLON,JLAY)
	275	Z_FAC011 = (1._JPRB - Z_FS1) * P_FAC11(JLON,JLAY)
	276	Z_FAC101 = Z_FS1 * P_FAC01(JLON,JLAY)
	277	Z_FAC111 = Z_FS1 * P_FAC11(JLON,JLAY)
	278
	279	Z_SPECCOMB_PLANCK(JLAY) = P_COLO3(JLON,JLAY)+ZREFRAT_PLANCK_B*P_COLCO2(JLON,JLAY)
	280	Z_SPECPARM_PLANCK = P_COLO3(JLON,JLAY)/Z_SPECCOMB_PLANCK(JLAY)
	281	IF (Z_SPECPARM_PLANCK >= P_ONEMINUS) Z_SPECPARM_PLANCK=P_ONEMINUS
	282	Z_SPECMULT_PLANCK = 4._JPRB*Z_SPECPARM_PLANCK
	283	JPL= 1 + INT(Z_SPECMULT_PLANCK)
	284	Z_FPL = MOD(Z_SPECMULT_PLANCK,1.0_JPRB)
	285
	286	IND0(JLAY) = ((K_JP(JLON,JLAY)-13)5+(K_JT(JLON,JLAY)-1))NSPB(4) + JS
	287	IND1(JLAY) = ((K_JP(JLON,JLAY)-12)5+(K_JT1(JLON,JLAY)-1))NSPB(4) + JS1
	288
	289
	290	!CDIR UNROLL=NG4
	291	DO IG = 1, NG4
	292	P_TAU(JLON,NGS3+IG,JLAY) = Z_SPECCOMB(JLAY) * &
	293	&(Z_FAC000 * ABSB(IND0(JLAY) ,IG) +&
	294	& Z_FAC100 * ABSB(IND0(JLAY)+1,IG) +&
	295	& Z_FAC010 * ABSB(IND0(JLAY)+5,IG) +&
	296	& Z_FAC110 * ABSB(IND0(JLAY)+6,IG)) +&
	297	& Z_SPECCOMB1(JLAY) * &
	298	& (Z_FAC001 * ABSB(IND1(JLAY) ,IG) +&
	299	& Z_FAC101 * ABSB(IND1(JLAY)+1,IG) +&
	300	& Z_FAC011 * ABSB(IND1(JLAY)+5,IG) +&
	301	& Z_FAC111 * ABSB(IND1(JLAY)+6,IG))+&
	302	& P_TAUAERL(JLON,JLAY,4)
	303	PFRAC(JLON,NGS3+IG,JLAY) = FRACREFB(IG,JPL) + Z_FPL *&
	304	& (FRACREFB(IG,JPL+1) - FRACREFB(IG,JPL))
	305	ENDDO
	306
	307	! Empirical modification to code to improve stratospheric cooling rates
	308	! for co2. Revised to apply weighting for g-point reduction in this band.
	309
	310	P_TAU(JLON,NGS3+8,JLAY)=P_TAU(JLON,NGS3+8,JLAY)*0.92
	311	P_TAU(JLON,NGS3+9,JLAY)=P_TAU(JLON,NGS3+9,JLAY)*0.88
	312	P_TAU(JLON,NGS3+10,JLAY)=P_TAU(JLON,NGS3+10,JLAY)*1.07
	313	P_TAU(JLON,NGS3+11,JLAY)=P_TAU(JLON,NGS3+11,JLAY)*1.1
	314	P_TAU(JLON,NGS3+12,JLAY)=P_TAU(JLON,NGS3+12,JLAY)*0.99
	315	P_TAU(JLON,NGS3+13,JLAY)=P_TAU(JLON,NGS3+13,JLAY)*0.88
	316	P_TAU(JLON,NGS3+14,JLAY)=P_TAU(JLON,NGS3+14,JLAY)*0.943
	317
	318
	319	ENDIF
	320	ENDDO
	321	ENDDO
	322
	323	IF (LHOOK) CALL DR_HOOK('RRTM_TAUMOL4',1,ZHOOK_HANDLE)
	324
	325	END ASSOCIATE
	326	END SUBROUTINE RRTM_TAUMOL4

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