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jthermcalc_e107.F @ 1704

Last change on this file since 1704 was 1530, checked in by emillour, 9 years ago

Venus and Titan GCMs:
Updates in the physics to keep up with updates in LMDZ5 (up to
LMDZ5 trunk, rev 2350) concerning dynamics/physics separation:

Adapted makelmdz and makelmdz_fcm script to stop if trying to compile 1d model or newstart or start2archive in parallel.
got rid of references to "dimensions.h" in physics. Within physics packages, use nbp_lon (=iim), nbp_lat (=jjmp1) and nbp_lev (=llm) from module mod_grid_phy_lmdz (in phy_common) instead. Only partially done for Titan, because of many hard-coded commons; a necessary first step will be to clean these up (using modules).

File size: 36.4 KB

Rev	Line
[1310]	1	c**********************************************************************
	2
	3	subroutine jthermcalc_e107
	4	$ (ig,chemthermod,rm,nesptherm,tx,iz,zenit,zday)
	5
	6
	7	c feb 2002 fgg first version
	8	c nov 2002 fgg second version
	9	c
	10	c modified from paramhr.F
	11	c MAC July 2003
	12	c**********************************************************************
	13	use dimphy
	14	use conc
	15	implicit none
	16
	17	c common variables and constants
	18	#include "param.h"
	19	#include "param_v4.h"
	20
	21	c input and output variables
	22
	23	integer ig
	24	integer chemthermod
	25	integer nesptherm !Number of species considered
	26	real rm(klev,nesptherm) !Densities (cm-3)
	27	real tx(klev) !temperature
	28	real zenit !SZA
	29	real iz(klev) !Local altitude
	30	real zday !Martian day after Ls=0
	31
	32
	33	c local parameters and variables
	34
	35	real co2colx(klev) !column density of CO2 (cm^-2)
	36	real o2colx(klev) !column density of O2(cm^-2)
	37	real o3pcolx(klev) !column density of O(3P)(cm^-2)
	38	real h2colx(klev) !H2 column density (cm-2)
	39	real h2ocolx(klev) !H2O column density (cm-2)
	40	real h2o2colx(klev) !column density of H2O2(cm^-2)
	41	real o3colx(klev) !O3 column density (cm-2)
	42	real n2colx(klev) !N2 column density (cm-2)
	43	real ncolx(klev) !N column density (cm-2)
	44	real nocolx(klev) !NO column density (cm-2)
	45	real cocolx(klev) !CO column density (cm-2)
	46	real hcolx(klev) !H column density (cm-2)
	47	real no2colx(klev) !NO2 column density (cm-2)
	48	real t2(klev)
	49	real coltemp(klev)
	50	real sigma(ninter,klev)
	51	real alfa(ninter,klev)
	52	real realday
	53
	54	integer i,j,k,indexint !indexes
	55	character dn
	56	integer tinf,tsup
	57
	58
	59
	60	c variables used in interpolation
	61
	62	real*8 auxcoltab(nz2)
	63	real*8 auxjco2(nz2)
	64	real*8 auxjo2(nz2)
	65	real*8 auxjo3p(nz2)
	66	real*8 auxjh2o(nz2)
	67	real*8 auxjh2(nz2)
	68	real*8 auxjh2o2(nz2)
	69	real*8 auxjo3(nz2)
	70	real*8 auxjn2(nz2)
	71	real*8 auxjn(nz2)
	72	real*8 auxjno(nz2)
	73	real*8 auxjco(nz2)
	74	real*8 auxjh(nz2)
	75	real*8 auxjno2(nz2)
	76	real*8 wp(klev),wm(klev)
	77	real*8 auxcolinp(klev)
	78	integer auxind(klev)
	79	integer auxi
	80	integer ind
	81	real*8 cortemp(klev)
	82
	83	real*8 limdown !limits for interpolation
	84	real*8 limup ! ""
	85
	86	!!!ATTENTION. Here i_co2 has to have the same value than in chemthermos.F90
	87	!!!If the value is changed there, if has to be changed also here !!!!
	88	integer,parameter :: i_co2=1
	89
	90
	91	c***********************PROGRAM STARTS*****************************
	92
	93	if(zenit.gt.140.) then
	94	dn='n'
	95	else
	96	dn='d'
	97	end if
	98	if(dn.eq.'n') then
	99	return
	100	endif
	101
	102	!Initializing the photoabsorption coefficients
	103	jfotsout(:,:,:)=0.
	104
	105	!Auxiliar temperature to take into account the temperature dependence
	106	!of CO2 cross section
	107	do i=1,klev
	108	t2(i)=tx(i)
	109	if(t2(i).lt.195.0) t2(i)=195.0
	110	if(t2(i).gt.295.0) t2(i)=295.0
	111	end do
	112
	113	!Calculation of column amounts
	114	call column(ig,chemthermod,rm,nesptherm,tx,iz,zenit,
	115	$ co2colx,o2colx,o3pcolx,h2colx,h2ocolx,
	116	$ h2o2colx,o3colx,n2colx,ncolx,nocolx,cocolx,hcolx,no2colx)
	117
	118	!Auxiliar column to include the temperature dependence
	119	!of CO2 cross section
	120	coltemp(klev)=co2colx(klev)*abs(t2(klev)-t0(klev))
	121	do i=klev-1,1,-1
	122	coltemp(i)=!coltemp(i+1)+ PQ SE ELIMINA? REVISAR
	123	$ ( rm(i,i_co2) + rm(i+1,i_co2) ) * 0.5
	124	$ * 1e5 * (iz(i+1)-iz(i)) * abs(t2(i)-t0(i))
	125	end do
	126
	127	!Calculation of CO2 cross section at temperature t0(i)
	128	do i=1,klev
	129	do indexint=24,32
	130	sigma(indexint,i)=co2crsc195(indexint-23)
	131	alfa(indexint,i)=((co2crsc295(indexint-23)
	132	$ /sigma(indexint,i))-1.)/(295.-t0(i))
	133	end do
	134	end do
	135
	136	!E10.7 for the day: linear interpolation to tabulated values
	137	realday=mod(zday,669.)
	138	if(realday.lt.date_e107(1)) then
	139	e107=e107_tab(1)
	140	else if(realday.ge.date_e107(669)) then
	141	e107=e107_tab(669)
	142	else if(realday.ge.date_e107(1).and.
	143	$ realday.lt.date_e107(669)) then
	144	do i=1,668
	145	if(realday.ge.date_e107(i).and.
	146	$ realday.lt.date_e107(i+1)) then
	147	tinf=i
	148	tsup=i+1
	149	e107=e107_tab(tinf)+(realday-date_e107(tinf))*
	150	$ (e107_tab(tsup)-e107_tab(tinf))
	151	endif
	152	enddo
	153	endif
	154
	155	!Photoabsorption coefficients at TOA as a function of E10.7
	156	do j=1,nabs
	157	do indexint=1,ninter
	158	jfotsout(indexint,j,klev)=coefit0(indexint,j)+
	159	$ coefit1(indexint,j)e107+coefit2(indexint,j)e107**2+
	160	$ coefit3(indexint,j)e1073+coefit4(indexint,j)e107**4
	161	enddo
	162	enddo
	163	! Interpolation to the tabulated photoabsorption coefficients for each species
	164	! in each spectral interval
	165
	166
	167	c auxcolinp-> Actual atmospheric column
	168	c auxj*-> Tabulated photoabsorption coefficients
	169	c auxcoltab-> Tabulated atmospheric columns
	170
	171	ccccccccccccccccccccccccccccccc
	172	c 0.1,5.0 (int 1)
	173	c
	174	c Absorption by:
	175	c CO2, O2, O, H2, N
	176	ccccccccccccccccccccccccccccccc
	177
	178	c Input atmospheric column
	179	indexint=1
	180	do i=1,klev
	181	auxcolinp(klev-i+1) = co2colx(i)*crscabsi2(1,indexint) +
	182	$ o2colx(i)*crscabsi2(2,indexint) +
	183	$ o3pcolx(i)*crscabsi2(3,indexint) +
	184	$ h2colx(i)*crscabsi2(5,indexint) +
	185	$ ncolx(i)*crscabsi2(9,indexint)
	186	end do
	187	limdown=1.e-20
	188	limup=1.e26
	189
	190
	191	c Interpolations
	192
	193	do i=1,nz2
	194	auxi = nz2-i+1
	195	!CO2 tabulated coefficient
	196	auxjco2(i) = jabsifotsintpar(auxi,1,indexint)
	197	!O2 tabulated coefficient
	198	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	199	!O3p tabulated coefficient
	200	auxjo3p(i) = jabsifotsintpar(auxi,3,indexint)
	201	!H2 tabulated coefficient
	202	auxjh2(i) = jabsifotsintpar(auxi,5,indexint)
	203	!Tabulated column
	204	auxcoltab(i) = c1_16(auxi,indexint)
	205	enddo
	206	!Only if chemthermod.ge.2
	207	!N tabulated coefficient
	208	if(chemthermod.ge.2) then
	209	do i=1,nz2
	210	auxjn(i) = jabsifotsintpar(nz2-i+1,9,indexint)
	211	enddo
	212	endif
	213
	214	call interfast
	215	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	216	do i=1,klev
	217	ind=auxind(i)
	218	auxi=klev-i+1
	219	!CO2 interpolated coefficient
	220	jfotsout(indexint,1,auxi) = jfotsout(indexint,1,klev) *
	221	$ (wm(i)auxjco2(ind+1) + wp(i)auxjco2(ind))
	222	!O2 interpolated coefficient
	223	jfotsout(indexint,2,auxi) = jfotsout(indexint,2,klev) *
	224	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind))
	225	!O3p interpolated coefficient
	226	jfotsout(indexint,3,auxi) = jfotsout(indexint,3,klev) *
	227	$ (wm(i)auxjo3p(ind+1) + wp(i)auxjo3p(ind))
	228	!H2 interpolated coefficient
	229	jfotsout(indexint,5,auxi) = jfotsout(indexint,5,auxi) *
	230	$ (wm(i)auxjh2(ind+1) + wp(i)auxjh2(ind))
	231	enddo
	232	!Only if chemthermod.ge.2
	233	!N interpolated coefficient
	234	if(chemthermod.ge.2) then
	235	do i=1,klev
	236	ind=auxind(i)
	237	jfotsout(indexint,9,klev-i+1) =
	238	$ jfotsout(indexint,9,klev) *
	239	$ (wm(i)auxjn(ind+1) + wp(i)auxjn(ind))
	240	enddo
	241	endif
	242
	243
	244	c End interval 1
	245
	246
	247	ccccccccccccccccccccccccccccccc
	248	c 5-80.5nm (int 2-15)
	249	c
	250	c Absorption by:
	251	c CO2, O2, O, H2, N2, N,
	252	c NO, CO, H, NO2
	253	ccccccccccccccccccccccccccccccc
	254
	255	c Input atmospheric column
	256	do indexint=2,15
	257	do i=1,klev
	258	auxcolinp(klev-i+1) = co2colx(i)*crscabsi2(1,indexint)+
	259	$ o2colx(i)*crscabsi2(2,indexint)+
	260	$ o3pcolx(i)*crscabsi2(3,indexint)+
	261	$ h2colx(i)*crscabsi2(5,indexint)+
	262	$ n2colx(i)*crscabsi2(8,indexint)+
	263	$ ncolx(i)*crscabsi2(9,indexint)+
	264	$ nocolx(i)*crscabsi2(10,indexint)+
	265	$ cocolx(i)*crscabsi2(11,indexint)+
	266	$ hcolx(i)*crscabsi2(12,indexint)+
	267	$ no2colx(i)*crscabsi2(13,indexint)
	268	end do
	269
	270	c Interpolations
	271
	272	do i=1,nz2
	273	auxi = nz2-i+1
	274	!O2 tabulated coefficient
	275	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	276	!O3p tabulated coefficient
	277	auxjo3p(i) = jabsifotsintpar(auxi,3,indexint)
	278	!CO2 tabulated coefficient
	279	auxjco2(i) = jabsifotsintpar(auxi,1,indexint)
	280	!H2 tabulated coefficient
	281	auxjh2(i) = jabsifotsintpar(auxi,5,indexint)
	282	!N2 tabulated coefficient
	283	auxjn2(i) = jabsifotsintpar(auxi,8,indexint)
	284	!CO tabulated coefficient
	285	auxjco(i) = jabsifotsintpar(auxi,11,indexint)
	286	!H tabulated coefficient
	287	auxjh(i) = jabsifotsintpar(auxi,12,indexint)
	288	!tabulated column
	289	auxcoltab(i) = c1_16(auxi,indexint)
	290	enddo
	291	!Only if chemthermod.ge.2
	292	if(chemthermod.ge.2) then
	293	do i=1,nz2
	294	auxi = nz2-i+1
	295	!N tabulated coefficient
	296	auxjn(i) = jabsifotsintpar(auxi,9,indexint)
	297	!NO tabulated coefficient
	298	auxjno(i) = jabsifotsintpar(auxi,10,indexint)
	299	!NO2 tabulated coefficient
	300	auxjno2(i) = jabsifotsintpar(auxi,13,indexint)
	301	enddo
	302	endif
	303
	304	call interfast(wm,wp,auxind,auxcolinp,klev,
	305	$ auxcoltab,nz2,limdown,limup)
	306	do i=1,klev
	307	ind=auxind(i)
	308	auxi = klev-i+1
	309	!O2 interpolated coefficient
	310	jfotsout(indexint,2,auxi) =
	311	$ jfotsout(indexint,2,klev) *
	312	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind))
	313	!O3p interpolated coefficient
	314	jfotsout(indexint,3,auxi) =
	315	$ jfotsout(indexint,3,klev) *
	316	$ (wm(i)auxjo3p(ind+1) + wp(i)auxjo3p(ind))
	317	!CO2 interpolated coefficient
	318	jfotsout(indexint,1,auxi) =
	319	$ jfotsout(indexint,1,klev) *
	320	$ (wm(i)auxjco2(ind+1) + wp(i)auxjco2(ind))
	321	!H2 interpolated coefficient
	322	jfotsout(indexint,5,auxi) =
	323	$ jfotsout(indexint,5,klev) *
	324	$ (wm(i)auxjh2(ind+1) + wp(i)auxjh2(ind))
	325	!N2 interpolated coefficient
	326	jfotsout(indexint,8,auxi) =
	327	$ jfotsout(indexint,8,klev) *
	328	$ (wm(i)auxjn2(ind+1) + wp(i)auxjn2(ind))
	329	!CO interpolated coefficient
	330	jfotsout(indexint,11,auxi) =
	331	$ jfotsout(indexint,11,klev) *
	332	$ (wm(i)auxjco(ind+1) + wp(i)auxjco(ind))
	333	!H interpolated coefficient
	334	jfotsout(indexint,12,auxi) =
	335	$ jfotsout(indexint,12,klev) *
	336	$ (wm(i)auxjh(ind+1) + wp(i)auxjh(ind))
	337	enddo
	338	!Only if chemthermod.ge.2
	339	if(chemthermod.ge.2) then
	340	do i=1,klev
	341	ind=auxind(i)
	342	auxi = klev-i+1
	343	!N interpolated coefficient
	344	jfotsout(indexint,9,auxi) =
	345	$ jfotsout(indexint,9,klev) *
	346	$ (wm(i)auxjn(ind+1) + wp(i)auxjn(ind))
	347	!NO interpolated coefficient
	348	jfotsout(indexint,10,auxi)=
	349	$ jfotsout(indexint,10,klev) *
	350	$ (wm(i)auxjno(ind+1) + wp(i)auxjno(ind))
	351	!NO2 interpolated coefficient
	352	jfotsout(indexint,13,auxi)=
	353	$ jfotsout(indexint,13,klev) *
	354	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind))
	355	enddo
	356	endif
	357	end do
	358
	359	c End intervals 2-15
	360
	361
	362	ccccccccccccccccccccccccccccccc
	363	c 80.6-90.8nm (int16)
	364	c
	365	c Absorption by:
	366	c CO2, O2, O, N2, N, NO,
	367	c CO, H, NO2
	368	ccccccccccccccccccccccccccccccc
	369
	370	c Input atmospheric column
	371	indexint=16
	372	do i=1,klev
	373	auxcolinp(klev-i+1) = co2colx(i)*crscabsi2(1,indexint)+
	374	$ o2colx(i)*crscabsi2(2,indexint)+
	375	$ o3pcolx(i)*crscabsi2(3,indexint)+
	376	$ n2colx(i)*crscabsi2(8,indexint)+
	377	$ ncolx(i)*crscabsi2(9,indexint)+
	378	$ nocolx(i)*crscabsi2(10,indexint)+
	379	$ cocolx(i)*crscabsi2(11,indexint)+
	380	$ hcolx(i)*crscabsi2(12,indexint)+
	381	$ no2colx(i)*crscabsi2(13,indexint)
	382	end do
	383
	384	c Interpolations
	385
	386	do i=1,nz2
	387	auxi = nz2-i+1
	388	!O2 tabulated coefficient
	389	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	390	!CO2 tabulated coefficient
	391	auxjco2(i) = jabsifotsintpar(auxi,1,indexint)
	392	!O3p tabulated coefficient
	393	auxjo3p(i) = jabsifotsintpar(auxi,3,indexint)
	394	!N2 tabulated coefficient
	395	auxjn2(i) = jabsifotsintpar(auxi,8,indexint)
	396	!CO tabulated coefficient
	397	auxjco(i) = jabsifotsintpar(auxi,11,indexint)
	398	!H tabulated coefficient
	399	auxjh(i) = jabsifotsintpar(auxi,12,indexint)
	400	!NO2 tabulated coefficient
	401	auxjno2(i) = jabsifotsintpar(auxi,13,indexint)
	402	!Tabulated column
	403	auxcoltab(i) = c1_16(auxi,indexint)
	404	enddo
	405	!Only if chemthermod.ge.2
	406	if(chemthermod.ge.2) then
	407	do i=1,nz2
	408	auxi = nz2-i+1
	409	!N tabulated coefficient
	410	auxjn(i) = jabsifotsintpar(auxi,9,indexint)
	411	!NO tabulated coefficient
	412	auxjno(i) = jabsifotsintpar(auxi,10,indexint)
	413	!NO2 tabulated coefficient
	414	auxjno2(i) = jabsifotsintpar(auxi,13,indexint)
	415	enddo
	416	endif
	417
	418	call interfast
	419	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	420	do i=1,klev
	421	ind=auxind(i)
	422	auxi = klev-i+1
	423	!O2 interpolated coefficient
	424	jfotsout(indexint,2,auxi) = jfotsout(indexint,2,klev) *
	425	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind))
	426	!CO2 interpolated coefficient
	427	jfotsout(indexint,1,auxi) = jfotsout(indexint,1,klev) *
	428	$ (wm(i)auxjco2(ind+1) + wp(i)auxjco2(ind))
	429	!O3p interpolated coefficient
	430	jfotsout(indexint,3,auxi) = jfotsout(indexint,3,klev) *
	431	$ (wm(i)auxjo3p(ind+1) + wp(i)auxjo3p(ind))
	432	!N2 interpolated coefficient
	433	jfotsout(indexint,8,auxi) = jfotsout(indexint,8,klev) *
	434	$ (wm(i)auxjn2(ind+1) + wp(i)auxjn2(ind))
	435	!CO interpolated coefficient
	436	jfotsout(indexint,11,auxi) =
	437	$ jfotsout(indexint,11,klev) *
	438	$ (wm(i)auxjco(ind+1) + wp(i)auxjco(ind))
	439	!H interpolated coefficient
	440	jfotsout(indexint,12,auxi) =
	441	$ jfotsout(indexint,12,klev) *
	442	$ (wm(i)auxjh(ind+1) + wp(i)auxjh(ind))
	443	enddo
	444	!Only if chemthermod.ge.2
	445	if(chemthermod.ge.2) then
	446	do i=1,klev
	447	ind=auxind(i)
	448	auxi = klev-i+1
	449	!N interpolated coefficient
	450	jfotsout(indexint,9,auxi) =
	451	$ jfotsout(indexint,9,klev) *
	452	$ (wm(i)auxjn(ind+1) + wp(i)auxjn(ind))
	453	!NO interpolated coefficient
	454	jfotsout(indexint,10,auxi) =
	455	$ jfotsout(indexint,10,klev) *
	456	$ (wm(i)auxjno(ind+1) + wp(i)auxjno(ind))
	457	!NO2 interpolated coefficient
	458	jfotsout(indexint,13,auxi) =
	459	$ jfotsout(indexint,13,klev) *
	460	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind))
	461	enddo
	462	endif
	463	c End interval 16
	464
	465
	466	ccccccccccccccccccccccccccccccc
	467	c 90.9-119.5nm (int 17-24)
	468	c
	469	c Absorption by:
	470	c CO2, O2, N2, NO, CO, NO2
	471	ccccccccccccccccccccccccccccccc
	472
	473	c Input column
	474
	475	do i=1,klev
	476	auxcolinp(klev-i+1) = co2colx(i) + o2colx(i) + n2colx(i) +
	477	$ nocolx(i) + cocolx(i) + no2colx(i)
	478	end do
	479
	480	do indexint=17,24
	481
	482	c Interpolations
	483
	484	do i=1,nz2
	485	auxi = nz2-i+1
	486	!CO2 tabulated coefficient
	487	auxjco2(i) = jabsifotsintpar(auxi,1,indexint)
	488	!O2 tabulated coefficient
	489	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	490	!N2 tabulated coefficient
	491	auxjn2(i) = jabsifotsintpar(auxi,8,indexint)
	492	!CO tabulated coefficient
	493	auxjco(i) = jabsifotsintpar(auxi,11,indexint)
	494	!Tabulated column
	495	auxcoltab(i) = c17_24(auxi)
	496	enddo
	497	!Only if chemthermod.ge.2
	498	if(chemthermod.ge.2) then
	499	do i=1,nz2
	500	auxi = nz2-i+1
	501	!NO tabulated coefficient
	502	auxjno(i) = jabsifotsintpar(auxi,10,indexint)
	503	!NO2 tabulated coefficient
	504	auxjno2(i) = jabsifotsintpar(auxi,13,indexint)
	505	enddo
	506	endif
	507
	508	call interfast
	509	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	510	!Correction to include T variation of CO2 cross section
	511	if(indexint.eq.24) then
	512	do i=1,klev
	513	auxi = klev-i+1
	514	if(sigma(indexint,auxi)*
	515	$ alfa(indexint,auxi)*coltemp(auxi)
	516	$ .lt.60.) then
	517	cortemp(i)=exp(-sigma(indexint,auxi)*
	518	$ alfa(indexint,auxi)*coltemp(auxi))
	519	else
	520	cortemp(i)=0.
	521	end if
	522	enddo
	523	else
	524	do i=1,klev
	525	cortemp(i)=1.
	526	enddo
	527	end if
	528	do i=1,klev
	529	ind=auxind(i)
	530	auxi = klev-i+1
	531	!O2 interpolated coefficient
	532	jfotsout(indexint,2,auxi) =
	533	$ jfotsout(indexint,2,klev) *
	534	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind)) *
	535	$ cortemp(i)
	536	!CO2 interpolated coefficient
	537	jfotsout(indexint,1,auxi) =
	538	$ jfotsout(indexint,1,klev) *
	539	$ (wm(i)auxjco2(ind+1) + wp(i)auxjco2(ind))
	540	$ * cortemp(i)
	541	if(indexint.eq.24) jfotsout(indexint,1,auxi)=
	542	$ jfotsout(indexint,1,auxi)*
	543	$ (1+alfa(indexint,auxi)*
	544	$ (t2(auxi)-t0(auxi)))
	545	!N2 interpolated coefficient
	546	jfotsout(indexint,8,auxi) =
	547	$ jfotsout(indexint,8,klev) *
	548	$ (wm(i)auxjn2(ind+1) + wp(i)auxjn2(ind)) *
	549	$ cortemp(i)
	550	!CO interpolated coefficient
	551	jfotsout(indexint,11,auxi) =
	552	$ jfotsout(indexint,11,klev) *
	553	$ (wm(i)auxjco(ind+1) + wp(i)auxjco(ind)) *
	554	$ cortemp(i)
	555	enddo
	556	!Only if chemthermod.ge.2
	557	if(chemthermod.ge.2) then
	558	do i=1,klev
	559	ind=auxind(i)
	560	auxi = klev-i+1
	561	!NO interpolated coefficient
	562	jfotsout(indexint,10,auxi)=
	563	$ jfotsout(indexint,10,klev) *
	564	$ (wm(i)auxjno(ind+1) + wp(i)auxjno(ind)) *
	565	$ cortemp(i)
	566	!NO2 interpolated coefficient
	567	jfotsout(indexint,13,auxi)=
	568	$ jfotsout(indexint,13,klev) *
	569	$ (wm(i)auxjno2(ind+1)+ wp(i)auxjno2(ind)) *
	570	$ cortemp(i)
	571	enddo
	572	endif
	573	end do
	574	c End intervals 17-24
	575
	576
	577	ccccccccccccccccccccccccccccccc
	578	c 119.6-167.0nm (int 25-29)
	579	c
	580	c Absorption by:
	581	c CO2, O2, H2O, H2O2, NO,
	582	c CO, NO2
	583	ccccccccccccccccccccccccccccccc
	584
	585	c Input atmospheric column
	586
	587	do i=1,klev
	588	auxcolinp(klev-i+1) = co2colx(i) + o2colx(i) + h2ocolx(i) +
	589	$ h2o2colx(i) + nocolx(i) + cocolx(i) + no2colx(i)
	590	end do
	591
	592	do indexint=25,29
	593
	594	c Interpolations
	595
	596	do i=1,nz2
	597	auxi = nz2-i+1
	598	!CO2 tabulated coefficient
	599	auxjco2(i) = jabsifotsintpar(auxi,1,indexint)
	600	!O2 tabulated coefficient
	601	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	602	!H2O tabulated coefficient
	603	auxjh2o(i) = jabsifotsintpar(auxi,4,indexint)
	604	!H2O2 tabulated coefficient
	605	auxjh2o2(i) = jabsifotsintpar(auxi,6,indexint)
	606	!CO tabulated coefficient
	607	auxjco(i) = jabsifotsintpar(auxi,11,indexint)
	608	!Tabulated column
	609	auxcoltab(i) = c25_29(auxi)
	610	enddo
	611	!Only if chemthermod.ge.2
	612	if(chemthermod.ge.2) then
	613	do i=1,nz2
	614	auxi = nz2-i+1
	615	!NO tabulated coefficient
	616	auxjno(i) = jabsifotsintpar(auxi,10,indexint)
	617	!NO2 tabulated coefficient
	618	auxjno2(i) = jabsifotsintpar(auxi,13,indexint)
	619	enddo
	620	endif
	621	call interfast
	622	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	623	do i=1,klev
	624	ind=auxind(i)
	625	auxi = klev-i+1
	626	!Correction to include T variation of CO2 cross section
	627	if(sigma(indexint,auxi)alfa(indexint,auxi)
	628	$ coltemp(auxi).lt.60.) then
	629	cortemp(i)=exp(-sigma(indexint,auxi)*
	630	$ alfa(indexint,auxi)*coltemp(auxi))
	631	else
	632	cortemp(i)=0.
	633	end if
	634	!CO2 interpolated coefficient
	635	jfotsout(indexint,1,auxi) =
	636	$ jfotsout(indexint,1,klev) *
	637	$ (wm(i)auxjco2(ind+1) + wp(i)auxjco2(ind)) *
	638	$ cortemp(i) *
	639	$ (1+alfa(indexint,auxi)*
	640	$ (t2(auxi)-t0(auxi)))
	641	!O2 interpolated coefficient
	642	jfotsout(indexint,2,auxi) =
	643	$ jfotsout(indexint,2,klev) *
	644	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind)) *
	645	$ cortemp(i)
	646	!H2O interpolated coefficient
	647	jfotsout(indexint,4,auxi) =
	648	$ jfotsout(indexint,4,klev) *
	649	$ (wm(i)auxjh2o(ind+1) + wp(i)auxjh2o(ind)) *
	650	$ cortemp(i)
	651	!H2O2 interpolated coefficient
	652	jfotsout(indexint,6,auxi) =
	653	$ jfotsout(indexint,6,klev) *
	654	$ (wm(i)auxjh2o2(ind+1) + wp(i)auxjh2o2(ind)) *
	655	$ cortemp(i)
	656	!CO interpolated coefficient
	657	jfotsout(indexint,11,auxi) =
	658	$ jfotsout(indexint,11,klev) *
	659	$ (wm(i)auxjco(ind+1) + wp(i)auxjco(ind)) *
	660	$ cortemp(i)
	661	enddo
	662	!Only if chemthermod.ge.2
	663	if(chemthermod.ge.2) then
	664	do i=1,klev
	665	ind=auxind(i)
	666	auxi = klev-i+1
	667	!NO interpolated coefficient
	668	jfotsout(indexint,10,auxi)=
	669	$ jfotsout(indexint,10,klev) *
	670	$ (wm(i)auxjno(ind+1) + wp(i)auxjno(ind)) *
	671	$ cortemp(i)
	672	!NO2 interpolated coefficient
	673	jfotsout(indexint,13,auxi)=
	674	$ jfotsout(indexint,13,klev) *
	675	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind)) *
	676	$ cortemp(i)
	677	enddo
	678	endif
	679
	680	end do
	681
	682	c End intervals 25-29
	683
	684
	685	cccccccccccccccccccccccccccccccc
	686	c 167.1-202.5nm (int 30-31)
	687	c
	688	c Absorption by:
	689	c CO2, O2, H2O, H2O2, NO,
	690	c NO2
	691	cccccccccccccccccccccccccccccccc
	692
	693	c Input atmospheric column
	694
	695	do i=1,klev
	696	auxcolinp(klev-i+1) = co2colx(i) + o2colx(i) + h2ocolx(i) +
	697	$ h2o2colx(i) + nocolx(i) + no2colx(i)
	698	end do
	699
	700	c Interpolation
	701
	702	do indexint=30,31
	703
	704	do i=1,nz2
	705	auxi = nz2-i+1
	706	!CO2 tabulated coefficient
	707	auxjco2(i) = jabsifotsintpar(auxi,1,indexint)
	708	!O2 tabulated coefficient
	709	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	710	!H2O tabulated coefficient
	711	auxjh2o(i) = jabsifotsintpar(auxi,4,indexint)
	712	!H2O2 tabulated coefficient
	713	auxjh2o2(i) = jabsifotsintpar(auxi,6,indexint)
	714	!Tabulated column
	715	auxcoltab(i) = c30_31(auxi)
	716	enddo
	717	!Only if chemthermod.ge.2
	718	if(chemthermod.ge.2) then
	719	do i=1,nz2
	720	auxi = nz2-i+1
	721	!NO tabulated coefficient
	722	auxjno(i) = jabsifotsintpar(auxi,10,indexint)
	723	!NO2 tabulated coefficient
	724	auxjno2(i) = jabsifotsintpar(auxi,13,indexint)
	725	enddo
	726	endif
	727
	728	call interfast
	729	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	730	do i=1,klev
	731	ind=auxind(i)
	732	auxi = klev-i+1
	733	!Correction to include T variation of CO2 cross section
	734	if(sigma(indexint,auxi)alfa(indexint,auxi)
	735	$ coltemp(auxi).lt.60.) then
	736	cortemp(i)=exp(-sigma(indexint,auxi)*
	737	$ alfa(indexint,auxi)*coltemp(auxi))
	738	else
	739	cortemp(i)=0.
	740	end if
	741	!CO2 interpolated coefficient
	742	jfotsout(indexint,1,auxi) =
	743	$ jfotsout(indexint,1,klev) *
	744	$ (wm(i)auxjco2(ind+1) + wp(i)auxjco2(ind)) *
	745	$ cortemp(i) *
	746	$ (1+alfa(indexint,auxi)*
	747	$ (t2(auxi)-t0(auxi)))
	748	!O2 interpolated coefficient
	749	jfotsout(indexint,2,auxi) =
	750	$ jfotsout(indexint,2,klev) *
	751	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind)) *
	752	$ cortemp(i)
	753	!H2O interpolated coefficient
	754	jfotsout(indexint,4,auxi) =
	755	$ jfotsout(indexint,4,klev) *
	756	$ (wm(i)auxjh2o(ind+1) + wp(i)auxjh2o(ind)) *
	757	$ cortemp(i)
	758	!H2O2 interpolated coefficient
	759	jfotsout(indexint,6,auxi) =
	760	$ jfotsout(indexint,6,klev) *
	761	$ (wm(i)auxjh2o2(ind+1) + wp(i)auxjh2o2(ind)) *
	762	$ cortemp(i)
	763	enddo
	764	!Only if chemthermod.ge.2
	765	if(chemthermod.ge.2) then
	766	do i=1,klev
	767	ind=auxind(i)
	768	auxi = klev-i+1
	769	!NO interpolated coefficient
	770	jfotsout(indexint,10,auxi)=
	771	$ jfotsout(indexint,10,klev) *
	772	$ (wm(i)auxjno(ind+1) +wp(i)auxjno(ind)) *
	773	$ cortemp(i)
	774	!NO2 interpolated coefficient
	775	jfotsout(indexint,13,auxi)=
	776	$ jfotsout(indexint,13,auxi) *
	777	$ (wm(i)auxjno2(ind+1)+wp(i)auxjno2(ind)) *
	778	$ cortemp(i)
	779	enddo
	780	endif
	781
	782	end do
	783
	784	c End intervals 30-31
	785
	786
	787	ccccccccccccccccccccccccccccccc
	788	c 202.6-210.0nm (int 32)
	789	c
	790	c Absorption by:
	791	c CO2, O2, H2O2, NO, NO2
	792	ccccccccccccccccccccccccccccccc
	793
	794	c Input atmospheric column
	795
	796	indexint=32
	797	do i=1,klev
	798	auxcolinp(klev-i+1) =co2colx(i) + o2colx(i) + h2o2colx(i) +
	799	$ nocolx(i) + no2colx(i)
	800	end do
	801
	802	c Interpolation
	803
	804	do i=1,nz2
	805	auxi = nz2-i+1
	806	!CO2 tabulated coefficient
	807	auxjco2(i) = jabsifotsintpar(auxi,1,indexint)
	808	!O2 tabulated coefficient
	809	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	810	!H2O2 tabulated coefficient
	811	auxjh2o2(i) = jabsifotsintpar(auxi,6,indexint)
	812	!Tabulated column
	813	auxcoltab(i) = c32(auxi)
	814	enddo
	815	!Only if chemthermod.ge.2
	816	if(chemthermod.ge.2) then
	817	do i=1,nz2
	818	auxi = nz2-i+1
	819	!NO tabulated coefficient
	820	auxjno(i) = jabsifotsintpar(auxi,10,indexint)
	821	!NO2 tabulated coefficient
	822	auxjno2(i) = jabsifotsintpar(auxi,13,indexint)
	823	enddo
	824	endif
	825	call interfast
	826	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	827	do i=1,klev
	828	ind=auxind(i)
	829	auxi = klev-i+1
	830	!Correction to include T variation of CO2 cross section
	831	if(sigma(indexint,klev-i+1)alfa(indexint,auxi)
	832	$ coltemp(auxi).lt.60.) then
	833	cortemp(i)=exp(-sigma(indexint,auxi)*
	834	$ alfa(indexint,auxi)*coltemp(auxi))
	835	else
	836	cortemp(i)=0.
	837	end if
	838	!CO2 interpolated coefficient
	839	jfotsout(indexint,1,auxi) =
	840	$ jfotsout(indexint,1,klev) *
	841	$ (wm(i)auxjco2(ind+1)+wp(i)auxjco2(ind)) *
	842	$ cortemp(i) *
	843	$ (1+alfa(indexint,auxi)*
	844	$ (t2(auxi)-t0(auxi)))
	845	!O2 interpolated coefficient
	846	jfotsout(indexint,2,auxi) =
	847	$ jfotsout(indexint,2,klev) *
	848	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind)) *
	849	$ cortemp(i)
	850	!H2O2 interpolated coefficient
	851	jfotsout(indexint,6,auxi) =
	852	$ jfotsout(indexint,6,klev) *
	853	$ (wm(i)auxjh2o2(ind+1) + wp(i)auxjh2o2(ind)) *
	854	$ cortemp(i)
	855	enddo
	856	!Only if chemthermod.ge.2
	857	if(chemthermod.ge.2) then
	858	do i=1,klev
	859	auxi = klev-i+1
	860	ind=auxind(i)
	861	!NO interpolated coefficient
	862	jfotsout(indexint,10,auxi) =
	863	$ jfotsout(indexint,10,klev) *
	864	$ (wm(i)auxjno(ind+1) + wp(i)auxjno(ind)) *
	865	$ cortemp(i)
	866	!NO2 interpolated coefficient
	867	jfotsout(indexint,13,auxi) =
	868	$ jfotsout(indexint,13,klev) *
	869	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind)) *
	870	$ cortemp(i)
	871	enddo
	872	endif
	873
	874	c End of interval 32
	875
	876
	877	ccccccccccccccccccccccccccccccc
	878	c 210.1-231.0nm (int 33)
	879	c
	880	c Absorption by:
	881	c O2, H2O2, NO2
	882	ccccccccccccccccccccccccccccccc
	883
	884	c Input atmospheric column
	885
	886	indexint=33
	887	do i=1,klev
	888	auxcolinp(klev-i+1) = o2colx(i) + h2o2colx(i) + no2colx(i)
	889	end do
	890
	891	c Interpolation
	892
	893	do i=1,nz2
	894	auxi = nz2-i+1
	895	!O2 tabulated coefficient
	896	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	897	!H2O2 tabulated coefficient
	898	auxjh2o2(i) = jabsifotsintpar(auxi,6,indexint)
	899	!Tabulated column
	900	auxcoltab(i) = c33(auxi)
	901	enddo
	902	!Only if chemthermod.ge.2
	903	if(chemthermod.ge.2) then
	904	do i=1,nz2
	905	!NO2 tabulated coefficient
	906	auxjno2(i) = jabsifotsintpar(nz2-i+1,13,indexint)
	907	enddo
	908	endif
	909	call interfast
	910	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	911	do i=1,klev
	912	ind=auxind(i)
	913	auxi = klev-i+1
	914	!O2 interpolated coefficient
	915	jfotsout(indexint,2,auxi) = jfotsout(indexint,2,klev) *
	916	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind))
	917	!H2O2 interpolated coefficient
	918	jfotsout(indexint,6,auxi) = jfotsout(indexint,6,klev) *
	919	$ (wm(i)auxjh2o2(ind+1) + wp(i)auxjh2o2(ind))
	920	enddo
	921	!Only if chemthermod.ge.2
	922	if(chemthermod.ge.2) then
	923	do i=1,klev
	924	ind=auxind(i)
	925	!NO2 interpolated coefficient
	926	jfotsout(indexint,13,klev-i+1) =
	927	$ jfotsout(indexint,13,klev) *
	928	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind))
	929	enddo
	930	endif
	931
	932	c End of interval 33
	933
	934
	935	ccccccccccccccccccccccccccccccc
	936	c 231.1-240.0nm (int 34)
	937	c
	938	c Absorption by:
	939	c O2, H2O2, O3, NO2
	940	ccccccccccccccccccccccccccccccc
	941
	942	c Input atmospheric column
	943
	944	indexint=34
	945	do i=1,klev
	946	auxcolinp(klev-i+1) = h2o2colx(i) + o2colx(i) + o3colx(i) +
	947	$ no2colx(i)
	948	end do
	949
	950	c Interpolation
	951
	952	do i=1,nz2
	953	auxi = nz2-i+1
	954	!O2 tabulated coefficient
	955	auxjo2(i) = jabsifotsintpar(auxi,2,indexint)
	956	!H2O2 tabulated coefficient
	957	auxjh2o2(i) = jabsifotsintpar(auxi,6,indexint)
	958	!O3 tabulated coefficient
	959	auxjo3(i) = jabsifotsintpar(auxi,7,indexint)
	960	!Tabulated column
	961	auxcoltab(i) = c34(nz2-i+1)
	962	enddo
	963	!Only if chemthermod.ge.2
	964	if(chemthermod.ge.2) then
	965	do i=1,nz2
	966	!NO2 tabulated coefficient
	967	auxjno2(i) = jabsifotsintpar(nz2-i+1,13,indexint)
	968	enddo
	969	endif
	970	call interfast
	971	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	972	do i=1,klev
	973	ind=auxind(i)
	974	auxi = klev-i+1
	975	!O2 interpolated coefficient
	976	jfotsout(indexint,2,auxi) = jfotsout(indexint,2,klev) *
	977	$ (wm(i)auxjo2(ind+1) + wp(i)auxjo2(ind))
	978	!H2O2 interpolated coefficient
	979	jfotsout(indexint,6,auxi) = jfotsout(indexint,6,klev) *
	980	$ (wm(i)auxjh2o2(ind+1) + wp(i)auxjh2o2(ind))
	981	!O3 interpolated coefficient
	982	jfotsout(indexint,7,auxi) = jfotsout(indexint,7,klev) *
	983	$ (wm(i)auxjo3(ind+1) + wp(i)auxjo3(ind))
	984	enddo
	985	!Only if chemthermod.ge.2
	986	if(chemthermod.ge.2) then
	987	do i=1,klev
	988	ind=auxind(i)
	989	!NO2 interpolated coefficient
	990	jfotsout(indexint,13,klev-i+1) =
	991	$ jfotsout(indexint,13,klev) *
	992	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind))
	993	enddo
	994	endif
	995
	996	c End of interval 34
	997
	998
	999	ccccccccccccccccccccccccccccccc
	1000	c 240.1-337.7nm (int 35)
	1001	c
	1002	c Absorption by:
	1003	c H2O2, O3, NO2
	1004	ccccccccccccccccccccccccccccccc
	1005
	1006	c Input atmospheric column
	1007
	1008	indexint=35
	1009	do i=1,klev
	1010	auxcolinp(klev-i+1) = h2o2colx(i) + o3colx(i) + no2colx(i)
	1011	end do
	1012
	1013	c Interpolation
	1014
	1015	do i=1,nz2
	1016	auxi = nz2-i+1
	1017	!H2O2 tabulated coefficient
	1018	auxjh2o2(i) = jabsifotsintpar(auxi,6,indexint)
	1019	!O3 tabulated coefficient
	1020	auxjo3(i) = jabsifotsintpar(auxi,7,indexint)
	1021	!Tabulated column
	1022	auxcoltab(i) = c35(auxi)
	1023	enddo
	1024	!Only if chemthermod.ge.2
	1025	if(chemthermod.ge.2) then
	1026	do i=1,nz2
	1027	!NO2 tabulated coefficient
	1028	auxjno2(i) = jabsifotsintpar(nz2-i+1,13,indexint)
	1029	enddo
	1030	endif
	1031	call interfast
	1032	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	1033	do i=1,klev
	1034	ind=auxind(i)
	1035	auxi = klev-i+1
	1036	!H2O2 interpolated coefficient
	1037	jfotsout(indexint,6,auxi) = jfotsout(indexint,6,klev) *
	1038	$ (wm(i)auxjh2o2(ind+1) + wp(i)auxjh2o2(ind))
	1039	!O3 interpolated coefficient
	1040	jfotsout(indexint,7,auxi) = jfotsout(indexint,7,klev) *
	1041	$ (wm(i)auxjo3(ind+1) + wp(i)auxjo3(ind))
	1042	enddo
	1043	if(chemthermod.ge.2) then
	1044	do i=1,klev
	1045	ind=auxind(i)
	1046	!NO2 interpolated coefficient
	1047	jfotsout(indexint,13,klev-i+1) =
	1048	$ jfotsout(indexint,13,klev) *
	1049	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind))
	1050	enddo
	1051	endif
	1052
	1053	c End of interval 35
	1054
	1055	ccccccccccccccccccccccccccccccc
	1056	c 337.8-800.0 nm (int 36)
	1057	c
	1058	c Absorption by:
	1059	c O3, NO2
	1060	ccccccccccccccccccccccccccccccc
	1061
	1062	c Input atmospheric column
	1063
	1064	indexint=36
	1065	do i=1,klev
	1066	auxcolinp(klev-i+1) = o3colx(i) + no2colx(i)
	1067	end do
	1068
	1069	c Interpolation
	1070
	1071	do i=1,nz2
	1072	auxi = nz2-i+1
	1073	!O3 tabulated coefficient
	1074	auxjo3(i) = jabsifotsintpar(auxi,7,indexint)
	1075	!Tabulated column
	1076	auxcoltab(i) = c36(auxi)
	1077	enddo
	1078	!Only if chemthermod.ge.2
	1079	if(chemthermod.ge.2) then
	1080	do i=1,nz2
	1081	!NO2 tabulated coefficient
	1082	auxjno2(i) = jabsifotsintpar(nz2-i+1,13,indexint)
	1083	enddo
	1084	endif
	1085	call interfast
	1086	$ (wm,wp,auxind,auxcolinp,klev,auxcoltab,nz2,limdown,limup)
	1087	do i=1,klev
	1088	ind=auxind(i)
	1089	!O3 interpolated coefficient
	1090	jfotsout(indexint,7,klev-i+1) =
	1091	$ jfotsout(indexint,7,klev) *
	1092	$ (wm(i)auxjo3(ind+1) + wp(i)auxjo3(ind))
	1093	enddo
	1094	!Only if chemthermod.ge.2
	1095	if(chemthermod.ge.2) then
	1096	do i=1,klev
	1097	ind=auxind(i)
	1098	!NO2 interpolated coefficient
	1099	jfotsout(indexint,13,klev-i+1) =
	1100	$ jfotsout(indexint,13,klev) *
	1101	$ (wm(i)auxjno2(ind+1) + wp(i)auxjno2(ind))
	1102	enddo
	1103	endif
	1104
	1105	c End of interval 36
	1106
	1107	c End of interpolation to obtain photoabsorption rates
	1108
	1109
	1110	return
	1111
	1112	end
	1113
	1114
	1115
	1116
	1117
	1118

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