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nirco2abs.F @ 3569

Last change on this file since 3569 was 2580, checked in by slebonnois, 4 years ago
SL: Version used for VCD 1.1 (tuneupperatm => key+photochemistry, nirco2abs) add prod and loss from photochem new nonorographic routine (not used for VCD 1.1) update of deftank files
File size: 15.6 KB

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1	SUBROUTINE nirco2abs(nlon,nlev,nplay,dist_sol,nq,pq,
2	$ mu0,fract,pdtnirco2)
3
4	use dimphy
5	use geometry_mod, only: longitude_deg, latitude_deg
6	use chemparam_mod, only: i_co2, i_o
7	c use compo_hedin83_mod2
8
9
10	IMPLICIT NONE
11	c=======================================================================
12	c subject:
13	c --------
14	c Computing heating rate due to
15	c absorption by CO2 in the near-infrared
16	c This version includes NLTE effects
17	c
18	c (Scheme to be described in Forget et al., JGR, 2003)
19	c (old Scheme described in Forget et al., JGR, 1999)
20	c
21	c This version updated with a new functional fit,
22	c see NLTE correction-factor of Lopez-Valverde et al (1998)
23	c Stephen Lewis 2000
24	c
25	c apr 2019 d.quirino Improving NLTE params, SOIR/SPICAV Temp comparison
26	c oct 2014 g.gilli Coupling with photochemical model
27	C jan 2014 g.gilli Revision (following martian non-lte param)
28	C jun 2013 l.salmi First adaptation to Venus and NIR NLTE param
29	c jul 2011 malv+fgg New corrections for NLTE implemented
30	c 08/2002 : correction for bug when running with diurnal=F
31	c
32	c author: Frederic Hourdin 1996
33	c ------
34	c Francois Forget 1999
35	c
36	c input:
37	c -----
38	c nlon number of gridpoint of horizontal grid
39	c nlev Number of layer
40	c dist_sol sun-Venus distance (AU)
41	c mu0(nlon)
42	c fract(nlon) day fraction of the time interval
43	c declin latitude of subslar point
44	c
45	c output:
46	c -------
47	c
48	c pdtnirco2(nlon,nlev) Heating rate (K/sec)
49	c
50	c
51	c=======================================================================
52	c
53	c 0. Declarations :
54	c ------------------
55	c
56
57	#include "YOMCST.h"
58	#include "clesphys.h"
59	c#include "comdiurn.h"
60	#include "nirdata.h"
61	c#include "tracer.h"
62	#include "mmol.h"
63	c-----------------------------------------------------------------------
64	c Input/Output
65	c ------------
66	integer,intent(in) :: nlon ! number of (horizontal) grid points
67	integer,intent(in) :: nlev ! number of atmospheric layers
68
69	real,intent(in) :: nplay(nlon,nlev) ! Pressure
70	real,intent(in) :: dist_sol ! Sun-Venus distance (in AU)
71	integer,intent(in) :: nq ! number of tracers
72	real,intent(in) :: pq(nlon,nlev,nq) ! mass mixing ratio tracers
73	real,intent(in) :: mu0(nlon) ! solar angle
74	real,intent(in) :: fract(nlon) ! day fraction of the time interval
75	c real,intent(in) :: declin ! latitude of sub-solar point
76	real :: co2vmr_gcm(nlon,nlev), o3pvmr_gcm(nlon,nlev)
77
78	real,intent(out) :: pdtnirco2(nlon,nlev) ! heating rate (K/sec)
79
80	c
81	c Local variables :
82	c -----------------
83	INTEGER l,ig, n, nstep,i
84	REAL co2heat0, zmu(nlon)
85
86	c special diurnal=F
87	real mu0_int(nlon),fract_int(nlon),zday_int
88	real ztim1,ztim2,ztim3,step
89
90	logical onepeak
91	parameter (onepeak=.false.)
92	c parameter (onepeak=.true.)
93	c
94	c local saved variables
95	c ---------------------
96	logical,save :: firstcall=.true.
97	integer,save :: ico2=0 ! index of "co2" tracer
98	integer,save :: io=0 ! index of "o" tracer
99
100	ccc=================================================
101	cccc parameters for CO2 heating fit
102	ccc=================================================
103
104	c--------------------------------------------------
105	c One-peak martian-type fit => Gabriella (2014+)
106	c--------------------------------------------------
107	c n_a = heating rate for Venusian day at p0, r0, mu =0 [K day-1]
108	c Here p0 = p_cloud top [Pa]
109	c n_p0 = is a pressure below which non LTE effects are significant [Pa]
110	c n_a Solar heating [K/Eday] at the cloud top, taken from Crisps table
111
112	real n_a, n_p0, n_b, p_ctop
113
114	cc "Nominal" values used in Gilli+2017
115	c parameter (n_a = 18.13/86400.0) !c K/Eday ---> K/sec
116	c parameter (p_ctop=13.2e2)
117	c parameter (n_p0=0.008)
118
119	cc "New" values used to improve SPICAV/SOIR Temperature comparision (D.Quirino)
120	cc Gilli+2021
121	parameter (n_a = 15.92/86400.0) !c K/Eday ---> K/sec
122	parameter (p_ctop=19.85e2)
123	parameter (n_p0=0.1)
124	parameter (n_b=1.362)
125
126	c -- NLTE Param v2 --
127	C parameter (n_p0=0.01)
128	c parameter (n_b = 1.3)
129
130	c--------------------------------------------------
131	c Multi-peaks Roldan-type fit => Laura (2013)
132	c New paramaters (Param9*0.5) => Enora (2021)
133	c--------------------------------------------------
134	c ENORA FINE TUNING used for VCD 1.1
135	c (fit to fig 12 Roldan-2000)
136	real n_coFB, n_aFB, n_bFB, n_p0FB, n_eFB
137	real n_coISO, n_aISO, n_bISO, n_p0ISO, n_eISO
138	real n_coFH, n_aFH, n_bFH, n_p0FH, n_eFH
139	real n_co43, n_a43, n_b43, n_p043, n_e43
140	real n_co43b, n_a43b, n_b43b, n_p043b, n_e43b
141	real n_conir, n_anir, n_bnir, n_p0nir, n_enir
142
143	parameter (n_coFB=119./86400.0) !c K/Eday ---> K/sec
144	parameter (n_aFB=0.185)
145	parameter (n_bFB=3.7)
146	parameter (n_p0FB=2.9e-4)
147	parameter (n_eFB=0.76)
148
149	parameter (n_coISO=265./86400.0) !c K/Eday ---> K/sec
150	parameter (n_aISO=0.313)
151	parameter (n_bISO=1.65)
152	parameter (n_p0ISO=0.076)
153	parameter (n_eISO=0.99)
154
155	parameter (n_coFH=2.5/86400.0) !c K/Eday ---> K/sec
156	parameter (n_aFH=3.98)
157	parameter (n_bFH=2.9)
158	parameter (n_p0FH=0.17)
159	parameter (n_eFH=2.16)
160
161	parameter (n_co43=55./86400.0) !c K/Eday ---> K/sec
162	parameter (n_a43=0.625)
163	parameter (n_b43=2.6)
164	parameter (n_p043=0.043)
165	parameter (n_e43=1.654)
166
167	! parameter (n_co43b=100./86400.0) !c K/Eday ---> K/sec
168	! => fine tuning: not affected by the *0.5 below (see ENORA FINE TUNING)
169	parameter (n_co43b=200./86400.0) !c K/Eday ---> K/sec
170	parameter (n_a43b=5.5)
171	parameter (n_b43b=2.3)
172	parameter (n_p043b=1.)
173	parameter (n_e43b=0.4)
174
175	parameter (n_conir=6.5/86400.0) !c K/Eday ---> K/sec
176	parameter (n_anir=35.65)
177	parameter (n_bnir=2.1)
178	parameter (n_p0nir=0.046)
179	parameter (n_enir=0.9)
180
181	real :: picFB(nlon,nlev), picISO(nlon,nlev), picFH(nlon,nlev)
182	real :: pic43(nlon,nlev), pic43b(nlon,nlev), picnir(nlon,nlev)
183
184	ccc=================================================
185
186	c Variables added to implement NLTE correction factor (feb 2011)
187	real pyy(nlev)
188	real cor1(nlev),oldoco2(nlev),alfa2(nlev)
189	real p2011,cociente1,merge
190	real cor0,oco2gcm
191
192	c----------------------------------------------------------------------
193	c Initialisation
194	c --------------
195	if (firstcall) then
196	if (nircorr.eq.1) then
197	c ! we will need co2 and o tracers
198	ico2= i_co2
199	if (ico2==0) then
200	write(,) "nirco2abs error: I need a CO2 tracer"
201	write(,) " when running with nircorr==1"
202	stop
203	endif
204	io=i_o
205	if (io==0) then
206	write(,) "nirco2abs error: I need an O tracer"
207	write(,) " when running with nircorr==1"
208	stop
209	endif
210	endif
211	firstcall=.false.
212	endif
213	c --------------
214	c co2heat0 is correction for dist_sol (is 1 for Venus)
215	co2heat0=(0.7233/dist_sol)**2
216
217	pdtnirco2(:,:)=0.
218	c----------------------------------------------------------------------
219
220	c
221	c Simple calcul for a given sun incident angle (if cycle_diurne=T)
222	c --------------------------------------------
223
224	IF (cycle_diurne) THEN
225
226	do ig=1,nlon
227	zmu(ig)=sqrt(1224.mu0(ig)mu0(ig)+1.)/35.
228
229	c---------------------------
230	if (onepeak) then
231	c---------------------------
232	if(nircorr.eq.1) then
233	do l=1,nlev
234	pyy(l)=nplay(ig,l)
235	enddo
236	call interpnir(cor1,pyy,nlev,corgcm,pres1d,npres)
237	call interpnir(oldoco2,pyy,nlev,oco21d,pres1d,npres)
238	call interpnir(alfa2,pyy,nlev,alfa,pres1d,npres)
239	endif
240	do l=1,nlev
241	c Calculations for the O/CO2 correction
242	if(nircorr.eq.1) then
243	cor0=1./(1.+n_p0/nplay(ig,l))**n_b
244	if(pq(ig,l,ico2) .gt. 1.e-6) then
245	oco2gcm=pq(ig,l,io)/pq(ig,l,ico2)
246	! handle the rare cases when pq(ig,l,io)<0
247	if (pq(ig,l,io).lt.0) then
248	write(,) "nirco2abs: warning ig=",ig," l=",l,
249	& " pq(ig,l,io)=",pq(ig,l,io)
250	oco2gcm=1.e6
251	endif
252	else
253	oco2gcm=1.e6
254	endif
255	cociente1=oco2gcm/oldoco2(l)
256
257	c WRITE(,) "nirco2abs line 211", l, cociente1
258
259	merge=alog10(cociente1)alfa2(l)+alog10(cor0)
260	$ (1.-alfa2(l))
261	merge=10**merge
262	p2011=sqrt(merge)*cor0
263
264	else if (nircorr.eq.0) then
265	p2011=1.
266	cor1(l)=1.
267	endif
268
269	if(fract(ig).gt.0.) pdtnirco2(ig,l)=
270	& co2heat0n_asqrt((p_ctop*zmu(ig))/nplay(ig,l))
271	& /(1.+n_p0/nplay(ig,l))**n_b
272	c Corrections from tabulation
273	$ * cor1(l) * p2011
274
275	enddo !nlev
276	c---------------------------
277	else ! multipeak
278	c---------------------------
279	do l=1,nlev
280	if(fract(ig).gt.0.) then
281	picFB(ig,l)=n_coFB
282	& ((n_aFB/nplay(ig,l))*n_eFB)
283	& zmu(ig)*0.82
284	& /(1.+n_p0FB/nplay(ig,l))**n_bFB
285
286	picISO(ig,l)=n_coISO
287	& ((n_aISO/nplay(ig,l))*n_eISO)
288	& zmu(ig)*0.55
289	& /(1.+n_p0ISO/nplay(ig,l))**n_bISO
290
291	picFH(ig,l)=n_coFH
292	& ((n_aFH/nplay(ig,l))*n_eFH)
293	& zmu(ig)*0.55
294	& /(1.+n_p0FH/nplay(ig,l))**n_bFH
295
296	pic43(ig,l)=n_co43
297	& ((n_a43/nplay(ig,l))*n_e43)
298	& zmu(ig)*0.55
299	& /(1.+n_p043/nplay(ig,l))**n_b43
300
301	pic43b(ig,l)=n_co43b
302	& ((n_a43b/nplay(ig,l))*n_e43b)
303	& zmu(ig)*0.55
304	& /(1.+n_p043b/nplay(ig,l))**n_b43b
305
306	picnir(ig,l)=n_conir
307	& ((n_anir/nplay(ig,l))*n_enir)
308	& zmu(ig)*0.55
309	& /(1.+n_p0nir/nplay(ig,l))**n_bnir
310
311	pdtnirco2(ig,l)=co2heat0*
312	& (picFB(ig,l)+picISO(ig,l)+picFH(ig,l)+pic43(ig,l)
313	& +pic43b(ig,l)+picnir(ig,l))0.5 ! 0.5 = ENORA FINE TUNING
314
315	endif
316	enddo !nlev
317	c---------------------------
318	endif
319	c---------------------------
320	enddo !nlon
321
322
323	c Averaging over diurnal cycle (if diurnal=F)
324	c -------------------------------------------
325	c NIR CO2 abs is slightly non linear. To remove the diurnal
326	c cycle, it is better to average the heating rate over 1 day rather
327	c than using the mean mu0 computed by mucorr in physiq.F (FF, 1998)
328
329	ELSE ! if (.not.diurnal) then
330	nstep = 20 ! number of integration step /sol
331	do n=1,nstep
332
333	zday_int = (n-1)/float(nstep)
334
335	CALL zenang(0.,zday_int,RDAY/nstep,
336	& latitude_deg,longitude_deg,
337	& mu0_int,fract_int)
338
339	do ig=1,nlon
340	zmu(ig)=sqrt(1224.mu0_int(ig)mu0_int(ig)+1.)/35.
341
342	c---------------------------
343	if (onepeak) then
344	c---------------------------
345	if(nircorr.eq.1) then
346	do l=1,nlev
347	pyy(l)=nplay(ig,l)
348	enddo
349	call interpnir(cor1,pyy,nlev,corgcm,pres1d,npres)
350	call interpnir(oldoco2,pyy,nlev,oco21d,pres1d,npres)
351	call interpnir(alfa2,pyy,nlev,alfa,pres1d,npres)
352	endif
353	do l=1,nlev
354	c Calculations for the O/CO2 correction
355	if(nircorr.eq.1) then
356	cor0=1./(1.+n_p0/nplay(ig,l))**n_b
357	if(pq(ig,l,ico2) .gt. 1.e-6) then
358	oco2gcm=pq(ig,l,io)/pq(ig,l,ico2)
359	! handle the rare cases when pq(ig,l,io)<0
360	if (pq(ig,l,io).lt.0) then
361	write(,) "nirco2abs: warning ig=",ig," l=",l,
362	& " pq(ig,l,io)=",pq(ig,l,io)
363	oco2gcm=1.e6
364	endif
365	else
366	oco2gcm=1.e6
367	endif
368	cociente1=oco2gcm/oldoco2(l)
369
370	c WRITE(,) "nirco2abs line 211", l, cociente1
371
372	merge=alog10(cociente1)alfa2(l)+alog10(cor0)
373	$ (1.-alfa2(l))
374	merge=10**merge
375	p2011=sqrt(merge)*cor0
376
377	else if (nircorr.eq.0) then
378	p2011=1.
379	cor1(l)=1.
380	endif
381
382	if(fract(ig).gt.0.) pdtnirco2(ig,l)=
383	& pdtnirco2(ig,l) + (1/float(nstep))*
384	& co2heat0n_asqrt((p_ctop*zmu(ig))/nplay(ig,l))
385	& /(1.+n_p0/nplay(ig,l))**n_b
386	c Corrections from tabulation
387	$ * cor1(l) * p2011
388
389	enddo !nlev
390	c---------------------------
391	else ! multipeak
392	c---------------------------
393	do l=1,nlev
394	if(fract(ig).gt.0.) then
395	picFB(ig,l)=n_coFB
396	& ((n_aFB/nplay(ig,l))*n_eFB)
397	& zmu(ig)*0.82
398	& /(1.+n_p0FB/nplay(ig,l))**n_bFB
399
400	picISO(ig,l)=n_coISO
401	& ((n_aISO/nplay(ig,l))*n_eISO)
402	& zmu(ig)*0.55
403	& /(1.+n_p0ISO/nplay(ig,l))**n_bISO
404
405	picFH(ig,l)=n_coFH
406	& ((n_aFH/nplay(ig,l))*n_eFH)
407	& zmu(ig)*0.55
408	& /(1.+n_p0FH/nplay(ig,l))**n_bFH
409
410	pic43(ig,l)=n_co43
411	& ((n_a43/nplay(ig,l))*n_e43)
412	& zmu(ig)*0.55
413	& /(1.+n_p043/nplay(ig,l))**n_b43
414
415	pic43b(ig,l)=n_co43b
416	& ((n_a43b/nplay(ig,l))*n_e43b)
417	& zmu(ig)*0.55
418	& /(1.+n_p043b/nplay(ig,l))**n_b43b
419
420	picnir(ig,l)=n_conir
421	& ((n_anir/nplay(ig,l))*n_enir)
422	& zmu(ig)*0.55
423	& /(1.+n_p0nir/nplay(ig,l))**n_bnir
424
425	pdtnirco2(ig,l)=
426	& pdtnirco2(ig,l)+(1/float(nstep))co2heat0
427	& (picFB(ig,l)+picISO(ig,l)+picFH(ig,l)+pic43(ig,l)
428	& +pic43b(ig,l)+picnir(ig,l))0.5 ! 0.5 = ENORA FINE TUNING
429
430	endif
431	enddo !nlev
432	c---------------------------
433	endif
434	c---------------------------
435	enddo !nlon
436	enddo !nstep
437
438	END IF ! diurnal cycle
439
440	return
441	end
442
443
444	subroutine interpnir(escout,p,nlev,escin,pin,nl)
445	C
446	C subroutine to perform linear interpolation in pressure from 1D profile
447	C escin(nl) sampled on pressure grid pin(nl) to profile
448	C escout(nlev) on pressure grid p(nlev).
449	C
450	real escout(nlev),p(nlev)
451	real escin(nl),pin(nl),wm,wp
452	integer nl,nlev,n1,n,nm,np
453	do n1=1,nlev
454	if(p(n1) .gt. 1500. .or. p(n1) .lt. 1.0e-13) then
455	c escout(n1) = 0.0
456	escout(n1) = 1.e-15
457	else
458	do n = 1,nl-1
459	if (p(n1).le.pin(n).and.p(n1).ge.pin(n+1)) then
460	nm=n
461	np=n+1
462	wm=abs(pin(np)-p(n1))/(pin(nm)-pin(np))
463	wp=1.0 - wm
464	endif
465	enddo
466	escout(n1) = escin(nm)wm + escin(np)wp
467	endif
468	enddo
469	return
470	end

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