1 | PROGRAM mie |
---|
2 | IMPLICIT NONE |
---|
3 | C |
---|
4 | C-------Mie computations for a size distribution |
---|
5 | C of homogeneous spheres. |
---|
6 | c |
---|
7 | C========================================================== |
---|
8 | C--Ref : Toon and Ackerman, Applied Optics, 1981 |
---|
9 | C Stephens, CSIRO, 1979 |
---|
10 | C Attention : surdimensionement des tableaux |
---|
11 | C to be compiled with double precision option (-r8 on Sun) |
---|
12 | C AUTHOR: Olivier Boucher |
---|
13 | C-------SIZE distribution properties---------------- |
---|
14 | C--sigma_g : geometric standard deviation |
---|
15 | C--r_0 : geometric number mean dry radius (um)=modal dry radius |
---|
16 | C--rho : density in kg/m3 |
---|
17 | C--Ntot : total concentration in m-3 (does not matter) |
---|
18 | c |
---|
19 | REAL rmin, rmax !----integral bounds in m |
---|
20 | PARAMETER (rmin=0.002E-6, rmax=30.E-6) |
---|
21 | c |
---|
22 | INTEGER Ndis, dis |
---|
23 | PARAMETER (Ndis=1) |
---|
24 | REAL sigma_g(Ndis), r_0(Ndis), Ntot(Ndis) |
---|
25 | DATA r_0 /0.1E-6/ |
---|
26 | DATA sigma_g/1.8/ |
---|
27 | DATA Ntot /1.0/ |
---|
28 | c |
---|
29 | INTEGER irh,Nrh |
---|
30 | PARAMETER(Nrh=12) |
---|
31 | REAL RH_tab(Nrh),RH |
---|
32 | DATA RH_tab/0.,10.,20.,30.,40.,50.,60.,70.,80.,85.,90.,95./ |
---|
33 | REAL rh_growth(Nrh), rho_SUL(Nrh), rhgrowth |
---|
34 | c |
---|
35 | REAL nombre, masse, massebc, massesul, volume,rho, rho_BC |
---|
36 | c |
---|
37 | PARAMETER (rho_BC=1.8E3) !--dry density kg/m3 |
---|
38 | c |
---|
39 | c--growth factor for radius for sulfate (=non-BC) aerosols |
---|
40 | c--output from exact calculations as a function of RH |
---|
41 | DATA rh_growth/1.000, 1.000, 1.000, 1.000, 1.169, 1.220, |
---|
42 | . 1.282, 1.363, 1.485, 1.580, 1.735, 2.085 / |
---|
43 | c |
---|
44 | c--density for sulfate (=non-BC) aerosols |
---|
45 | c--output from exact calculations as a function of RH |
---|
46 | DATA rho_SUL/ 1769., 1769., 1769., 1769., 1430., 1390., |
---|
47 | . 1349., 1302., 1245., 1210., 1165., 1101./ !--kg/m3 |
---|
48 | c |
---|
49 | INTEGER class,Nclass |
---|
50 | PARAMETER (Nclass=7) |
---|
51 | c |
---|
52 | c--dry mass content of BC |
---|
53 | REAL bc_content(Nclass) |
---|
54 | DATA bc_content/0.0, 0.001, 0.01, 0.02, 0.05, 0.1, 0.2/ |
---|
55 | c |
---|
56 | REAL bccontentbymass, sulcontentbymass, drycontentbymass |
---|
57 | REAL bccontentbyvol, sulcontentbyvol |
---|
58 | c |
---|
59 | c------------------------------------- |
---|
60 | c |
---|
61 | COMPLEX m !----refractive index m=n_r-i*n_i |
---|
62 | c--the following is added by Rong Wang |
---|
63 | COMPLEX zmax1, zmax2, zmax3 |
---|
64 | c--end |
---|
65 | INTEGER Nmax,Nstart !--number of iterations |
---|
66 | COMPLEX k2, k3, z1, z2 |
---|
67 | COMPLEX u1,u5,u6,u8 |
---|
68 | COMPLEX a(1:21000), b(1:21000) |
---|
69 | COMPLEX I |
---|
70 | INTEGER n !--loop index |
---|
71 | REAL pi, nnn |
---|
72 | COMPLEX nn |
---|
73 | REAL Q_ext, Q_abs, Q_sca, g, omega !--parameters for radius r |
---|
74 | REAL x !--size parameter |
---|
75 | REAL r !--radius |
---|
76 | REAL sigma_sca, sigma_ext, sigma_abs |
---|
77 | REAL omegatot, gtot !--averaged parameters |
---|
78 | COMPLEX ksiz2(-1:21000), psiz2(1:21000) |
---|
79 | COMPLEX nu1z1(1:21010), nu1z2(1:21010) |
---|
80 | COMPLEX nu3z2(0:21000) |
---|
81 | REAL dnumber, deltar |
---|
82 | INTEGER bin, Nbin, k |
---|
83 | PARAMETER (Nbin=700) |
---|
84 | c |
---|
85 | C---wavelengths STREAMER |
---|
86 | INTEGER Nwv, NwvmaxSW |
---|
87 | PARAMETER (NwvmaxSW=25) |
---|
88 | REAL lambda(1:NwvmaxSW) |
---|
89 | DATA lambda/0.28E-6, 0.30E-6, 0.33E-6, 0.36E-6, 0.40E-6, |
---|
90 | . 0.44E-6, 0.48E-6, 0.52E-6, 0.57E-6, 0.64E-6, |
---|
91 | . 0.69E-6, 0.75E-6, 0.78E-6, 0.87E-6, 1.00E-6, |
---|
92 | . 1.10E-6, 1.19E-6, 1.28E-6, 1.53E-6, 1.64E-6, |
---|
93 | . 2.13E-6, 2.38E-6, 2.91E-6, 3.42E-6, 4.00E-6/ |
---|
94 | c |
---|
95 | INTEGER nb, nb_lambda |
---|
96 | PARAMETER (nb_lambda=5) |
---|
97 | REAL lambda_ref(nb_lambda) |
---|
98 | DATA lambda_ref /0.443E-6,0.550E-6,0.670E-6,0.765E-6,0.865E-6/ |
---|
99 | c |
---|
100 | C---BOA fluxes from typical STREAMER run - Tad |
---|
101 | REAL weight(1:NwvmaxSW-1) |
---|
102 | DATA weight/ 0.01, 4.05, 9.51, 15.99, 26.07, 33.10, 33.07, |
---|
103 | . 39.91, 52.67, 27.89, 43.60, 13.67, 42.22, 40.12, |
---|
104 | . 32.70, 14.44, 19.48, 14.23, 13.43, 16.42, 8.33, |
---|
105 | . 0.95, 0.65, 2.76/ |
---|
106 | c |
---|
107 | REAL lambda_int(1:NwvmaxSW-1+nb_lambda) |
---|
108 | c |
---|
109 | REAL n_r_BC(1:NwvmaxSW-1+nb_lambda) |
---|
110 | REAL n_i_BC(1:NwvmaxSW-1+nb_lambda) |
---|
111 | c |
---|
112 | REAL n_r_SUL(1:Nrh,1:NwvmaxSW-1+nb_lambda) |
---|
113 | REAL n_i_SUL(1:Nrh,1:NwvmaxSW-1+nb_lambda) |
---|
114 | c |
---|
115 | REAL final_a(1:NwvmaxSW-1+nb_lambda) |
---|
116 | REAL final_g(1:NwvmaxSW-1+nb_lambda) |
---|
117 | REAL final_w(1:NwvmaxSW-1+nb_lambda) |
---|
118 | c |
---|
119 | INTEGER band, NbandSW |
---|
120 | PARAMETER (NbandSW=6) |
---|
121 | c |
---|
122 | REAL gcm_a(NbandSW) |
---|
123 | REAL gcm_g(NbandSW) |
---|
124 | REAL gcm_w(NbandSW) |
---|
125 | REAL gcm_weight_a(NbandSW) |
---|
126 | REAL gcm_weight_g(NbandSW) |
---|
127 | REAL gcm_weight_w(NbandSW) |
---|
128 | c |
---|
129 | REAL ss_a(Nclass,Nrh,NbandSW+nb_lambda) |
---|
130 | REAL ss_w(Nclass,Nrh,NbandSW+nb_lambda) |
---|
131 | REAL ss_g(Nclass,Nrh,NbandSW+nb_lambda) |
---|
132 | c |
---|
133 | REAL ss_a_bc(Nclass,Nrh,NbandSW+nb_lambda) |
---|
134 | REAL ss_w_bc(Nclass,Nrh,NbandSW+nb_lambda) |
---|
135 | REAL ss_g_bc(Nclass,Nrh,NbandSW+nb_lambda) |
---|
136 | c |
---|
137 | INTEGER wv, nb_wv_BCr, nb_wv_BCi, nb_wv_SUL |
---|
138 | REAL count_n_r, count_n_i |
---|
139 | c |
---|
140 | REAL n_r, n_i |
---|
141 | c |
---|
142 | c--refractive index for soluble stuff other than BC |
---|
143 | PARAMETER (nb_wv_SUL=100) |
---|
144 | REAL wv_SUL(1:nb_wv_SUL) |
---|
145 | REAL index_r_SUL(1:Nrh,1:nb_wv_SUL) |
---|
146 | REAL index_i_SUL(1:Nrh,1:nb_wv_SUL) |
---|
147 | |
---|
148 | c--refractive index for BC |
---|
149 | c--Greg Schuster data |
---|
150 | c PARAMETER (nb_wv_BCr=21, nb_wv_BCi=21) |
---|
151 | c--Sheffield |
---|
152 | PARAMETER (nb_wv_BCr=61, nb_wv_BCi=61) |
---|
153 | REAL wv_BCr(1:nb_wv_BCr), wv_BCi(1:nb_wv_BCi) |
---|
154 | REAL index_r_BC(1:nb_wv_BCr), index_i_BC(1:nb_wv_BCi) |
---|
155 | REAL dummy |
---|
156 | c--this is used by Rong Wang to test the square root |
---|
157 | c zmax1=CMPLX(0,2) |
---|
158 | c zmax1=zmax1**(1./2.) |
---|
159 | c n_r=REAL(zmax1) |
---|
160 | c n_i=AIMAG(zmax1) |
---|
161 | c print *, n_r,n_i |
---|
162 | c |
---|
163 | c zmax1=CMPLX(-3,4) |
---|
164 | c zmax1=zmax1**(1./2.) |
---|
165 | c n_r=REAL(zmax1) |
---|
166 | c n_i=AIMAG(zmax1) |
---|
167 | c print *, n_r,n_i |
---|
168 | c--end |
---|
169 | c--reading real part of refractive index |
---|
170 | c OPEN(unit=10,file='r_bc_greg.dat') |
---|
171 | OPEN(unit=10,file='r_bcsoot_she.dat') |
---|
172 | DO wv=1, nb_wv_BCr |
---|
173 | READ (10,*) wv_BCr(wv), index_r_BC(wv) |
---|
174 | ENDDO |
---|
175 | CLOSE(10) |
---|
176 | c |
---|
177 | c--reading imaginary part of refractive index |
---|
178 | c OPEN(unit=10,file='i_bc_greg.dat') |
---|
179 | OPEN(unit=10,file='i_bcsoot_she.dat') |
---|
180 | DO wv=1, nb_wv_BCi |
---|
181 | READ (10,*) wv_BCi(wv), index_i_BC(wv) |
---|
182 | ENDDO |
---|
183 | CLOSE(10) |
---|
184 | c |
---|
185 | c--reading imaginary part of refractive index |
---|
186 | c--for sulfate (=non-BC) aerosols |
---|
187 | OPEN(unit=10,file='ri_sul_v2') |
---|
188 | DO irh=1, Nrh |
---|
189 | DO wv=1, nb_wv_SUL |
---|
190 | READ (10,*) dummy, wv_SUL(wv), |
---|
191 | . index_r_SUL(irh,wv), index_i_SUL(irh,wv) |
---|
192 | ENDDO |
---|
193 | ENDDO |
---|
194 | CLOSE(10) |
---|
195 | c |
---|
196 | c------------------------------------------------------------ |
---|
197 | c--initialising BC refractice indices before interpolation |
---|
198 | DO Nwv=1, NwvmaxSW-1+nb_lambda |
---|
199 | n_r_BC(Nwv)=0.0 |
---|
200 | n_i_BC(Nwv)=0.0 |
---|
201 | ENDDO |
---|
202 | c |
---|
203 | c--interpolating on our wavelengths |
---|
204 | DO Nwv=1, NwvmaxSW-1 |
---|
205 | c |
---|
206 | lambda_int(Nwv)=( lambda(Nwv)+lambda(Nwv+1) ) /2. |
---|
207 | c |
---|
208 | c--first real part |
---|
209 | count_n_r=0.0 |
---|
210 | DO wv=1, nb_wv_BCr |
---|
211 | IF (wv_BCr(wv)/1.e9.GT.lambda(Nwv).AND. |
---|
212 | . wv_BCr(wv)/1.e9.LT.lambda(Nwv+1)) THEN |
---|
213 | n_r_BC(Nwv)=n_r_BC(Nwv)+index_r_BC(wv) |
---|
214 | count_n_r=count_n_r+1.0 |
---|
215 | ENDIF |
---|
216 | ENDDO |
---|
217 | c |
---|
218 | IF (count_n_r.GT.0.5) THEN |
---|
219 | c--averaging |
---|
220 | n_r_BC(Nwv)=n_r_BC(Nwv)/count_n_r |
---|
221 | ELSE |
---|
222 | c--otherwise closest neighbour |
---|
223 | DO wv=1, nb_wv_BCr |
---|
224 | IF (wv_BCr(wv)/1.e9.LT.lambda_int(Nwv)) THEN |
---|
225 | n_r_BC(Nwv)=index_r_BC(wv) |
---|
226 | ENDIF |
---|
227 | ENDDO |
---|
228 | ENDIF |
---|
229 | c |
---|
230 | c--then imaginary part |
---|
231 | count_n_i=0.0 |
---|
232 | DO wv=1, nb_wv_BCi |
---|
233 | IF (wv_BCi(wv)/1.e9.GT.lambda(Nwv).AND. |
---|
234 | . wv_BCi(wv)/1.e9.LT.lambda(Nwv+1)) THEN |
---|
235 | n_i_BC(Nwv)=n_i_BC(Nwv)+index_i_BC(wv) |
---|
236 | count_n_i=count_n_i+1.0 |
---|
237 | ENDIF |
---|
238 | ENDDO |
---|
239 | c |
---|
240 | IF (count_n_i.GT.0.5) THEN |
---|
241 | c--averaging |
---|
242 | n_i_BC(Nwv)=n_i_BC(Nwv)/count_n_i |
---|
243 | ELSE |
---|
244 | c--otherwise closest neighbour |
---|
245 | DO wv=1, nb_wv_BCi |
---|
246 | IF (wv_BCi(wv)/1.e9.LT.lambda_int(Nwv)) THEN |
---|
247 | n_i_BC(Nwv)=index_i_BC(wv) |
---|
248 | ENDIF |
---|
249 | ENDDO |
---|
250 | ENDIF |
---|
251 | c |
---|
252 | ENDDO |
---|
253 | c |
---|
254 | c------------------------------------------------------------ |
---|
255 | c--initialising SUL refractice indices before interpolation |
---|
256 | DO irh=1, Nrh |
---|
257 | c |
---|
258 | DO Nwv=1, NwvmaxSW-1+nb_lambda |
---|
259 | n_r_SUL(irh,Nwv)=0.0 |
---|
260 | n_i_SUL(irh,Nwv)=0.0 |
---|
261 | ENDDO |
---|
262 | c |
---|
263 | c--interpolating on our wavelengths |
---|
264 | c |
---|
265 | DO Nwv=1, NwvmaxSW-1 |
---|
266 | c |
---|
267 | lambda_int(Nwv)=( lambda(Nwv)+lambda(Nwv+1) ) /2. |
---|
268 | c |
---|
269 | c--first real part |
---|
270 | count_n_r=0.0 |
---|
271 | DO wv=1, nb_wv_SUL |
---|
272 | IF (wv_SUL(wv).GT.lambda(Nwv).AND. |
---|
273 | . wv_SUL(wv).LT.lambda(Nwv+1)) THEN |
---|
274 | n_r_SUL(irh,Nwv)=n_r_SUL(irh,Nwv)+index_r_SUL(irh,wv) |
---|
275 | count_n_r=count_n_r+1.0 |
---|
276 | ENDIF |
---|
277 | ENDDO |
---|
278 | c |
---|
279 | IF (count_n_r.GT.0.5) THEN |
---|
280 | c--averaging |
---|
281 | n_r_SUL(irh,Nwv)=n_r_SUL(irh,Nwv)/count_n_r |
---|
282 | ELSE |
---|
283 | c--otherwise closest neighbour |
---|
284 | DO wv=1, nb_wv_SUL |
---|
285 | IF (wv_SUL(wv).LT.lambda_int(Nwv)) THEN |
---|
286 | n_r_SUL(irh,Nwv)=index_r_SUL(irh,wv) |
---|
287 | ENDIF |
---|
288 | ENDDO |
---|
289 | ENDIF |
---|
290 | c |
---|
291 | c--then imaginary part |
---|
292 | count_n_i=0.0 |
---|
293 | DO wv=1, nb_wv_SUL |
---|
294 | IF (wv_SUL(wv).GT.lambda(Nwv).AND. |
---|
295 | . wv_SUL(wv).LT.lambda(Nwv+1)) THEN |
---|
296 | n_i_SUL(irh,Nwv)=n_i_SUL(irh,Nwv)+index_i_SUL(irh,wv) |
---|
297 | count_n_i=count_n_i+1.0 |
---|
298 | ENDIF |
---|
299 | ENDDO |
---|
300 | c |
---|
301 | IF (count_n_i.GT.0.5) THEN |
---|
302 | c--averaging |
---|
303 | n_i_SUL(irh,Nwv)=n_i_SUL(irh,Nwv)/count_n_i |
---|
304 | ELSE |
---|
305 | c--otherwise closest neighbour |
---|
306 | DO wv=1, nb_wv_SUL |
---|
307 | IF (wv_SUL(wv).LT.lambda_int(Nwv)) THEN |
---|
308 | n_i_SUL(irh,Nwv)=index_i_SUL(irh,wv) |
---|
309 | ENDIF |
---|
310 | ENDDO |
---|
311 | ENDIF |
---|
312 | c |
---|
313 | ENDDO |
---|
314 | c |
---|
315 | ENDDO |
---|
316 | c |
---|
317 | c----------------------------------------------------------- |
---|
318 | c |
---|
319 | c--now defining nr and ni for my set of reference wavelengths |
---|
320 | DO nb=1, nb_lambda |
---|
321 | c |
---|
322 | lambda_int(NwvmaxSW-1+nb)=lambda_ref(nb) |
---|
323 | c |
---|
324 | c--for BC |
---|
325 | DO wv=1, nb_wv_BCr |
---|
326 | IF (wv_BCr(wv)/1.e9.LT.lambda_ref(nb)) THEN |
---|
327 | n_r_BC(NwvmaxSW-1+nb)=index_r_BC(wv) |
---|
328 | ENDIF |
---|
329 | ENDDO |
---|
330 | |
---|
331 | DO wv=1, nb_wv_BCi |
---|
332 | IF (wv_BCi(wv)/1.e9.LT.lambda_ref(nb)) THEN |
---|
333 | n_i_BC(NwvmaxSW-1+nb)=index_i_BC(wv) |
---|
334 | ENDIF |
---|
335 | ENDDO |
---|
336 | c |
---|
337 | c--for SUL |
---|
338 | DO irh=1,Nrh |
---|
339 | DO wv=1, nb_wv_SUL |
---|
340 | IF (wv_SUL(wv).LT.lambda_ref(nb)) THEN |
---|
341 | n_r_SUL(irh,NwvmaxSW-1+nb)=index_r_SUL(irh,wv) |
---|
342 | n_i_SUL(irh,NwvmaxSW-1+nb)=index_i_SUL(irh,wv) |
---|
343 | ENDIF |
---|
344 | ENDDO |
---|
345 | ENDDO |
---|
346 | c |
---|
347 | ENDDO |
---|
348 | c |
---|
349 | c--n_r and n_i are defined manually for first band |
---|
350 | n_r_BC(1)=index_r_BC(1) |
---|
351 | n_i_BC(1)=index_i_BC(1) |
---|
352 | c |
---|
353 | c--here check that n_r and n_i are fine after interpolation scheme |
---|
354 | c PRINT *,'n_r_BC=', n_r_BC |
---|
355 | c PRINT *,'n_i_BC=', n_i_BC |
---|
356 | c PRINT *,'n_r_SUL=', n_r_SUL |
---|
357 | c PRINT *,'n_i_SUL=', n_i_SUL |
---|
358 | c |
---|
359 | c |
---|
360 | c--------------------------------------------------------------------- |
---|
361 | c------MASTER LOOPS |
---|
362 | c |
---|
363 | DO class=1, Nclass |
---|
364 | c |
---|
365 | DO irh=1, Nrh |
---|
366 | c |
---|
367 | c print *,'class=', class, ' irh=', irh |
---|
368 | c |
---|
369 | c--Mie calculation starts here |
---|
370 | DO Nwv=1, NwvmaxSW-1+nb_lambda |
---|
371 | c |
---|
372 | c--BC and non-BC mass fraction |
---|
373 | c--for the dry aerosol |
---|
374 | bccontentbymass=bc_content(class) !--dry mass fraction |
---|
375 | sulcontentbymass=1.0-bccontentbymass !--dry mass fraction |
---|
376 | c--rhgrowth for the mixed particle |
---|
377 | rhgrowth=(( bccontentbymass/rho_BC + |
---|
378 | . sulcontentbymass/rho_SUL(1)*rh_growth(irh)**3.) / |
---|
379 | . ( bccontentbymass/rho_BC + |
---|
380 | . sulcontentbymass/rho_SUL(1) ))**(1./3.) |
---|
381 | c--added by Rong Wang to compute dry mass content |
---|
382 | drycontentbymass= ( bccontentbymass + sulcontentbymass ) / |
---|
383 | . (bccontentbymass + |
---|
384 | . sulcontentbymass*rh_growth(irh)**3.0* |
---|
385 | . rho_SUL(irh)/rho_SUL(1) ) !--wet mass fraction |
---|
386 | c--BC and non-BC mass fraction |
---|
387 | c--correcting for the wet aerosol |
---|
388 | c--sulcontent is for sulfate + water |
---|
389 | bccontentbymass=bccontentbymass / ( bccontentbymass + |
---|
390 | . sulcontentbymass*rh_growth(irh)**3.0* |
---|
391 | . rho_SUL(irh)/rho_SUL(1) ) !--wet mass fraction |
---|
392 | sulcontentbymass=1.0-bccontentbymass !--wet mass fraction |
---|
393 | c--BC and non-BC volume fraction |
---|
394 | c--for the wet aerosol |
---|
395 | bccontentbyvol=(bccontentbymass/rho_BC) / |
---|
396 | . (bccontentbymass/rho_BC + |
---|
397 | . sulcontentbymass/rho_SUL(irh)) !--wet vol fraction |
---|
398 | sulcontentbyvol=1.0-bccontentbyvol !--wet vol fraction |
---|
399 | c |
---|
400 | c |
---|
401 | c print *, rhgrowth, rh_growth(irh) |
---|
402 | c print *,'BC=',bc_content(class), bccontentbymass, bccontentbyvol |
---|
403 | c |
---|
404 | c--density of mixture rho = (Mbc+Msul)/(Vbc+Vsul) |
---|
405 | c = (Mbc+Msul)/Msul*Msul/Vsul*Vsul/(Vbc+Vsul) |
---|
406 | c = rhoSUL*sulcontentbyvol/sulcontentbymass |
---|
407 | rho=rho_SUL(irh)*sulcontentbyvol/sulcontentbymass |
---|
408 | c print *,'rho=',rho_BC, rho_SUL(irh), rho, |
---|
409 | c |
---|
410 | c--volume weighed refractive index |
---|
411 | c--the following is modified by Rong Wang |
---|
412 | c n_r=n_r_BC(Nwv)*bccontentbyvol+n_r_SUL(irh,Nwv)*sulcontentbyvol |
---|
413 | c n_i=n_i_BC(Nwv)*bccontentbyvol+n_i_SUL(irh,Nwv)*sulcontentbyvol |
---|
414 | zmax1=CMPLX(n_r_BC(Nwv),-n_i_BC(Nwv)) |
---|
415 | zmax2=CMPLX(n_r_SUL(irh,Nwv),-n_i_SUL(irh,Nwv)) |
---|
416 | zmax3=(zmax2**2) * |
---|
417 | . (zmax1**2+2.*zmax2**2+2.*bccontentbyvol*(zmax1**2 |
---|
418 | . -zmax2**2)) / |
---|
419 | . (zmax1**2+2.*zmax2**2-bccontentbyvol*(zmax1**2 |
---|
420 | . -zmax2**2)) |
---|
421 | zmax3=zmax3**(1./2.) |
---|
422 | n_r=REAL(zmax3) |
---|
423 | n_i=-AIMAG(zmax3) |
---|
424 | c |
---|
425 | c----test print 550 nm refractive index |
---|
426 | c if (Nwv.eq.NwvmaxSW-1+2) then |
---|
427 | c print *, 'n_r=',n_r, n_r_BC(Nwv), n_r_SUL(irh,Nwv) |
---|
428 | c print *, 'n_i=',n_i, n_i_BC(Nwv), n_i_SUL(irh,Nwv) |
---|
429 | c endif |
---|
430 | c |
---|
431 | m=CMPLX(n_r,-n_i) |
---|
432 | c |
---|
433 | pi=4.*ATAN(1.) |
---|
434 | c |
---|
435 | I=CMPLX(0.,1.) |
---|
436 | c |
---|
437 | sigma_sca=0.0 |
---|
438 | sigma_ext=0.0 |
---|
439 | sigma_abs=0.0 |
---|
440 | gtot=0.0 |
---|
441 | omegatot=0.0 |
---|
442 | masse = 0.0 |
---|
443 | massebc = 0.0 |
---|
444 | massesul = 0.0 |
---|
445 | volume=0.0 |
---|
446 | nombre=0.0 |
---|
447 | c |
---|
448 | DO bin=0, Nbin !---loop on size bins |
---|
449 | |
---|
450 | c--this radius is the wet aerosol radius |
---|
451 | r=exp(log(rmin)+FLOAT(bin)/FLOAT(Nbin)*(log(rmax)-log(rmin))) |
---|
452 | x=2.*pi*r/lambda_int(Nwv) |
---|
453 | deltar=1./FLOAT(Nbin)*(log(rmax)-log(rmin)) |
---|
454 | c |
---|
455 | c--computing number concentration using log-normal for the dry aerosols |
---|
456 | dnumber=0 |
---|
457 | DO dis=1, Ndis |
---|
458 | dnumber=dnumber+Ntot(dis)/SQRT(2.*pi)/log(sigma_g(dis))* |
---|
459 | . exp(-0.5*(log(r/(r_0(dis)*rhgrowth)) |
---|
460 | . /log(sigma_g(dis)))**2) |
---|
461 | ENDDO |
---|
462 | c--be careful here we compute the mass of BC in the mixed particle |
---|
463 | c--using the rho of the mixed particle gives total mass |
---|
464 | c--then multiply by bc content by mass for the wet aerosol |
---|
465 | massebc = massebc +4./3.*pi*(r**3)*dnumber* |
---|
466 | . deltar*rho*1.E3*bccontentbymass !--g/m3 |
---|
467 | c--added by Rong Wang |
---|
468 | masse = masse + 4./3.*pi*(r**3)*dnumber* |
---|
469 | . deltar*rho*1.E3*drycontentbymass !--g/m3 |
---|
470 | massesul = massesul + 4./3.*pi*(r**3)*dnumber* |
---|
471 | . deltar*rho*1.E3*(drycontentbymass - bccontentbymass) !--g/m3 |
---|
472 | c--be careful here we compute the volume of BC in the mixed particle |
---|
473 | volume=volume+4./3.*pi*(r**3)*dnumber*deltar*bccontentbyvol |
---|
474 | c--total number |
---|
475 | nombre=nombre+dnumber*deltar |
---|
476 | c |
---|
477 | k2=m |
---|
478 | k3=CMPLX(1.0,0.0) |
---|
479 | |
---|
480 | z2=CMPLX(x,0.0) |
---|
481 | z1=m*z2 |
---|
482 | |
---|
483 | IF (0.0.LE.x.AND.x.LE.8.) THEN |
---|
484 | Nmax=INT(x+4*x**(1./3.)+1.)+2 |
---|
485 | ELSEIF (8..LT.x.AND.x.LT.4200.) THEN |
---|
486 | Nmax=INT(x+4.05*x**(1./3.)+2.)+1 |
---|
487 | ELSEIF (4200..LE.x.AND.x.LE.20000.) THEN |
---|
488 | Nmax=INT(x+4*x**(1./3.)+2.)+1 |
---|
489 | ELSE |
---|
490 | WRITE(10,*) 'x out of bound, x=', x |
---|
491 | STOP |
---|
492 | ENDIF |
---|
493 | |
---|
494 | Nstart=Nmax+10 |
---|
495 | |
---|
496 | C-----------loop for nu1z1, nu1z2 |
---|
497 | |
---|
498 | nu1z1(Nstart)=CMPLX(0.0,0.0) |
---|
499 | nu1z2(Nstart)=CMPLX(0.0,0.0) |
---|
500 | DO n=Nstart-1, 1 , -1 |
---|
501 | nn=CMPLX(FLOAT(n),0.0) |
---|
502 | nu1z1(n)=(nn+1.)/z1 - 1./( (nn+1.)/z1 + nu1z1(n+1) ) |
---|
503 | nu1z2(n)=(nn+1.)/z2 - 1./( (nn+1.)/z2 + nu1z2(n+1) ) |
---|
504 | ENDDO |
---|
505 | |
---|
506 | C------------loop for nu3z2 |
---|
507 | |
---|
508 | nu3z2(0)=-I |
---|
509 | DO n=1, Nmax |
---|
510 | nn=CMPLX(FLOAT(n),0.0) |
---|
511 | nu3z2(n)=-nn/z2 + 1./ (nn/z2 - nu3z2(n-1) ) |
---|
512 | ENDDO |
---|
513 | |
---|
514 | C-----------loop for psiz2 and ksiz2 (z2) |
---|
515 | ksiz2(-1)=COS(REAL(z2))-I*SIN(REAL(z2)) |
---|
516 | ksiz2(0)=SIN(REAL(z2))+I*COS(REAL(z2)) |
---|
517 | DO n=1,Nmax |
---|
518 | nn=CMPLX(FLOAT(n),0.0) |
---|
519 | ksiz2(n)=(2.*nn-1.)/z2 * ksiz2(n-1) - ksiz2(n-2) |
---|
520 | psiz2(n)=CMPLX(REAL(ksiz2(n)),0.0) |
---|
521 | ENDDO |
---|
522 | |
---|
523 | C-----------loop for a(n) and b(n) |
---|
524 | |
---|
525 | DO n=1, Nmax |
---|
526 | u1=k3*nu1z1(n) - k2*nu1z2(n) |
---|
527 | u5=k3*nu1z1(n) - k2*nu3z2(n) |
---|
528 | u6=k2*nu1z1(n) - k3*nu1z2(n) |
---|
529 | u8=k2*nu1z1(n) - k3*nu3z2(n) |
---|
530 | a(n)=psiz2(n)/ksiz2(n) * u1/u5 |
---|
531 | b(n)=psiz2(n)/ksiz2(n) * u6/u8 |
---|
532 | ENDDO |
---|
533 | |
---|
534 | C-----------------final loop-------------- |
---|
535 | Q_ext=0.0 |
---|
536 | Q_sca=0.0 |
---|
537 | g=0.0 |
---|
538 | DO n=Nmax-1,1,-1 |
---|
539 | nnn=FLOAT(n) |
---|
540 | Q_ext=Q_ext+ (2.*nnn+1.) * REAL( a(n)+b(n) ) |
---|
541 | Q_sca=Q_sca+ (2.*nnn+1.) * |
---|
542 | . REAL( a(n)*CONJG(a(n)) + b(n)*CONJG(b(n)) ) |
---|
543 | g=g + nnn*(nnn+2.)/(nnn+1.) * |
---|
544 | . REAL( a(n)*CONJG(a(n+1))+b(n)*CONJG(b(n+1)) ) + |
---|
545 | . (2.*nnn+1.)/nnn/(nnn+1.) * REAL(a(n)*CONJG(b(n))) |
---|
546 | ENDDO |
---|
547 | Q_ext=2./x**2 * Q_ext |
---|
548 | Q_sca=2./x**2 * Q_sca |
---|
549 | Q_abs=Q_ext-Q_sca |
---|
550 | IF (AIMAG(m).EQ.0.0) Q_abs=0.0 |
---|
551 | omega=Q_sca/Q_ext |
---|
552 | g=g*4./x**2/Q_sca |
---|
553 | c |
---|
554 | sigma_sca=sigma_sca+r**2*Q_sca*dnumber*deltar |
---|
555 | sigma_abs=sigma_abs+r**2*Q_abs*dnumber*deltar |
---|
556 | sigma_ext=sigma_ext+r**2*Q_ext*dnumber*deltar |
---|
557 | omegatot=omegatot+r**2*Q_ext*omega*dnumber*deltar |
---|
558 | gtot =gtot+r**2*Q_sca*g*dnumber*deltar |
---|
559 | c |
---|
560 | ENDDO !---bin |
---|
561 | C------------------------------------------------------------------ |
---|
562 | |
---|
563 | sigma_sca=pi*sigma_sca |
---|
564 | sigma_abs=pi*sigma_abs |
---|
565 | sigma_ext=pi*sigma_ext |
---|
566 | gtot=pi*gtot/sigma_sca |
---|
567 | omegatot=pi*omegatot/sigma_ext |
---|
568 | c |
---|
569 | final_g(Nwv)=gtot |
---|
570 | final_w(Nwv)=min(1.,omegatot) |
---|
571 | c-- Rong Wang modify this to compute the alpha based on the dry mass of |
---|
572 | c-- whole mixture (black carbon + sulfate) |
---|
573 | final_a(Nwv)=sigma_ext/masse |
---|
574 | c |
---|
575 | ENDDO !--loop on wavelength |
---|
576 | c |
---|
577 | c---averaging over LMDZ wavebands |
---|
578 | c |
---|
579 | c print *, final_a(6), final_a(NwvmaxSW), final_a(NwvmaxSW+1) |
---|
580 | DO band=1, NbandSW |
---|
581 | gcm_a(band)=0.0 |
---|
582 | gcm_g(band)=0.0 |
---|
583 | gcm_w(band)=0.0 |
---|
584 | gcm_weight_a(band)=0.0 |
---|
585 | gcm_weight_g(band)=0.0 |
---|
586 | gcm_weight_w(band)=0.0 |
---|
587 | ENDDO |
---|
588 | c |
---|
589 | c---band 1 is now in the UV, so we take the first wavelength as being representative |
---|
590 | c---it doesn't matter anyway because all radiation is absorbed in the stratosphere |
---|
591 | DO Nwv=1,1 |
---|
592 | band=1 |
---|
593 | gcm_a(band)=gcm_a(band)+final_a(Nwv)*weight(Nwv) |
---|
594 | gcm_weight_a(band)=gcm_weight_a(band)+weight(Nwv) |
---|
595 | gcm_w(band)=gcm_w(band)+ |
---|
596 | . final_w(Nwv)*final_a(Nwv)*weight(Nwv) |
---|
597 | gcm_weight_w(band)=gcm_weight_w(band)+ |
---|
598 | . final_a(Nwv)*weight(Nwv) |
---|
599 | gcm_g(band)=gcm_g(band)+ |
---|
600 | . final_g(Nwv)*final_a(Nwv)*final_w(Nwv)*weight(Nwv) |
---|
601 | gcm_weight_g(band)=gcm_weight_g(band)+ |
---|
602 | . final_a(Nwv)*final_w(Nwv)*weight(Nwv) |
---|
603 | ENDDO |
---|
604 | c |
---|
605 | DO Nwv=1,NwvmaxSW-1 |
---|
606 | c |
---|
607 | IF (Nwv.LE.5) THEN !--RRTM spectral interval 2 |
---|
608 | band=2 |
---|
609 | ELSEIF (Nwv.LE.10) THEN !--RRTM spectral interval 3 |
---|
610 | band=3 |
---|
611 | ELSEIF (Nwv.LE.16) THEN !--RRTM spectral interval 4 |
---|
612 | band=4 |
---|
613 | ELSEIF (Nwv.LE.21) THEN !--RRTM spectral interval 5 |
---|
614 | band=5 |
---|
615 | ELSE !--RRTM spectral interval 6 |
---|
616 | band=6 |
---|
617 | ENDIF |
---|
618 | c |
---|
619 | gcm_a(band)=gcm_a(band)+final_a(Nwv)*weight(Nwv) |
---|
620 | gcm_weight_a(band)=gcm_weight_a(band)+weight(Nwv) |
---|
621 | gcm_w(band)=gcm_w(band)+ |
---|
622 | . final_w(Nwv)*final_a(Nwv)*weight(Nwv) |
---|
623 | gcm_weight_w(band)=gcm_weight_w(band)+ |
---|
624 | . final_a(Nwv)*weight(Nwv) |
---|
625 | gcm_g(band)=gcm_g(band)+ |
---|
626 | . final_g(Nwv)*final_a(Nwv)*final_w(Nwv)*weight(Nwv) |
---|
627 | gcm_weight_g(band)=gcm_weight_g(band)+ |
---|
628 | . final_a(Nwv)*final_w(Nwv)*weight(Nwv) |
---|
629 | ENDDO |
---|
630 | c |
---|
631 | DO band=1, NbandSW |
---|
632 | gcm_a(band)=gcm_a(band)/gcm_weight_a(band) |
---|
633 | gcm_w(band)=gcm_w(band)/gcm_weight_w(band) |
---|
634 | gcm_g(band)=gcm_g(band)/gcm_weight_g(band) |
---|
635 | ss_a(class,irh,band)=gcm_a(band) |
---|
636 | ss_w(class,irh,band)=gcm_w(band) |
---|
637 | ss_g(class,irh,band)=gcm_g(band) |
---|
638 | ENDDO |
---|
639 | c |
---|
640 | DO nb=NbandSW+1, NbandSW+nb_lambda |
---|
641 | ss_a(class,irh,nb)=final_a(NwvmaxSW-1+nb-NbandSW) |
---|
642 | ss_w(class,irh,nb)=final_w(NwvmaxSW-1+nb-NbandSW) |
---|
643 | ss_g(class,irh,nb)=final_g(NwvmaxSW-1+nb-NbandSW) |
---|
644 | ENDDO |
---|
645 | c |
---|
646 | c-- Rong Wang (July 7, 2016)) |
---|
647 | c-- From this line, it should be very careful |
---|
648 | c-- Here, I compute the ext, abs, sca for dry BC mass |
---|
649 | c-- I have checked these variables for mass: |
---|
650 | c-- masse, dry total mass; massebc, dry BC; massesul, dry sulfate |
---|
651 | c-- masse = massebc + massesul |
---|
652 | c-- |
---|
653 | c-- I derive the ext, abs, sca for dry sulfate mass by setting class=1 |
---|
654 | c-- where BCcontent=0 |
---|
655 | c-- So, I compute the ext since class=2 here |
---|
656 | |
---|
657 | IF (class.EQ.1) THEN ! For class=1, we do nothing (no BC) |
---|
658 | |
---|
659 | DO nb=1, NbandSW+nb_lambda |
---|
660 | |
---|
661 | ss_a_bc(class,irh,nb) = 0.0 |
---|
662 | ss_w_bc(class,irh,nb) = 1.0 |
---|
663 | ss_g_bc(class,irh,nb) = 0.0 |
---|
664 | |
---|
665 | ENDDO |
---|
666 | |
---|
667 | ELSE |
---|
668 | |
---|
669 | c--here we compute the properties for an equivalent BC that would be in |
---|
670 | c--external mixture. The properties do not make sense as such but have |
---|
671 | c--to be recombined with that of SUL (classe=1) to be those of the mixed |
---|
672 | c--particle |
---|
673 | |
---|
674 | DO nb=1, NbandSW+nb_lambda |
---|
675 | |
---|
676 | ! this ss_a is for dry BC only hereafter |
---|
677 | ss_a_bc(class,irh,nb) = ( ss_a(class,irh,nb)*masse - |
---|
678 | . ss_a(1,irh,nb)*massesul ) / massebc |
---|
679 | |
---|
680 | ! this ss_w is for dry BC only hereafter |
---|
681 | ss_w_bc(class,irh,nb) = (ss_w(class,irh,nb)* |
---|
682 | . ss_a(class,irh,nb)*masse - |
---|
683 | . ss_w(1,irh,nb)*ss_a(1,irh,nb)*massesul ) / |
---|
684 | . (ss_a_bc(class,irh,nb)*massebc) |
---|
685 | |
---|
686 | ! this ss_g is for dry BC only hereafter |
---|
687 | ss_g_bc(class,irh,nb) = ( ss_g(class,irh,nb)* |
---|
688 | . ss_w(class,irh,nb)*ss_a(class,irh,nb)*masse - |
---|
689 | . ss_g(1,irh,nb)*ss_w(1,irh,nb)*ss_a(1,irh,nb)*massesul) / |
---|
690 | . (ss_w_bc(class,irh,nb)*ss_a_bc(class,irh,nb)*massebc) |
---|
691 | |
---|
692 | ENDDO |
---|
693 | ENDIF |
---|
694 | c-- End (Rong Wang) |
---|
695 | |
---|
696 | ENDDO !--irh |
---|
697 | c |
---|
698 | ENDDO !--Nclass |
---|
699 | c |
---|
700 | c--saving MEC, g and SSA for SUL for the model two bands |
---|
701 | OPEN (unit=14,file='SEXT_sulfate_internal_mixture_6bands.txt') |
---|
702 | WRITE(14,*) ' !-- Sulfate Accumulation (BC content=0)' |
---|
703 | DO k=1,NbandSW |
---|
704 | WRITE(14,950) (ss_a(1,irh,k),irh=1, Nrh) |
---|
705 | ENDDO |
---|
706 | CLOSE(14) |
---|
707 | |
---|
708 | OPEN (unit=14,file='SSA_sulfate_internal_mixture_6bands.txt') |
---|
709 | WRITE(14,*) ' !-- Sulfate Accumulation (BC content=0)' |
---|
710 | DO k=1,NbandSW |
---|
711 | WRITE(14,950) (ss_w(1,irh,k),irh=1, Nrh) |
---|
712 | ENDDO |
---|
713 | CLOSE(14) |
---|
714 | |
---|
715 | OPEN (unit=14,file='G_sulfate_internal_mixture_6bands.txt') |
---|
716 | WRITE(14,*) ' !-- Sulfate Accumulation (BC content=0)' |
---|
717 | DO k=1,NbandSW |
---|
718 | WRITE(14,950) (ss_g(1,irh,k),irh=1, Nrh) |
---|
719 | ENDDO |
---|
720 | CLOSE(14) |
---|
721 | |
---|
722 | OPEN |
---|
723 | . (unit=14,file='SEXT_sulfate+2%bc_internal_mixture_6bands.txt') |
---|
724 | WRITE(14,*) ' !-- Sulfate Accumulation (BC content=2%)' |
---|
725 | DO k=1,NbandSW |
---|
726 | WRITE(14,950) (ss_a(4,irh,k),irh=1, Nrh) |
---|
727 | ENDDO |
---|
728 | CLOSE(14) |
---|
729 | |
---|
730 | OPEN |
---|
731 | . (unit=14,file='SSA_sulfate+2%bc_internal_mixture_6bands.txt') |
---|
732 | WRITE(14,*) ' !-- Sulfate Accumulation (BC content=2%)' |
---|
733 | DO k=1,NbandSW |
---|
734 | WRITE(14,950) (ss_w(4,irh,k),irh=1, Nrh) |
---|
735 | ENDDO |
---|
736 | CLOSE(14) |
---|
737 | |
---|
738 | OPEN |
---|
739 | . (unit=14,file='G_sulfate+2%bc_internal_mixture_6bands.txt') |
---|
740 | WRITE(14,*) ' !-- Sulfate Accumulation (BC content=2%)' |
---|
741 | DO k=1,NbandSW |
---|
742 | WRITE(14,950) (ss_g(4,irh,k),irh=1, Nrh) |
---|
743 | ENDDO |
---|
744 | CLOSE(14) |
---|
745 | |
---|
746 | c--saving MEC, g and SSA for equivalent BC the model two bands |
---|
747 | OPEN (unit=14,file='DATA_BC_internal_mixture_6bands.txt') |
---|
748 | WRITE(14,*) ' DATA alpha_MG_6bands/ &' |
---|
749 | DO class=2, Nclass |
---|
750 | WRITE(14,900) bc_content(class) |
---|
751 | DO k=1,NbandSW |
---|
752 | WRITE(14,951) (ss_a_bc(class,irh,k),irh=1, Nrh) |
---|
753 | ENDDO |
---|
754 | ENDDO |
---|
755 | |
---|
756 | WRITE(14,*) ' ' |
---|
757 | WRITE(14,*) ' DATA piz_MG_6bands/ &' |
---|
758 | DO class=2, Nclass |
---|
759 | WRITE(14,900) bc_content(class) |
---|
760 | DO k=1,NbandSW |
---|
761 | WRITE(14,951) (ss_w_bc(class,irh,k),irh=1,Nrh) |
---|
762 | ENDDO |
---|
763 | ENDDO |
---|
764 | |
---|
765 | WRITE(14,*) ' ' |
---|
766 | WRITE(14,*) ' DATA cg_MG_6bands/ &' |
---|
767 | DO class=2, Nclass |
---|
768 | WRITE(14,900) bc_content(class) |
---|
769 | DO k=1,NbandSW |
---|
770 | WRITE(14,951) (ss_g_bc(class,irh,k),irh=1,Nrh) |
---|
771 | ENDDO |
---|
772 | ENDDO |
---|
773 | CLOSE(14) |
---|
774 | c |
---|
775 | c--saving MEC and MAC for SUL for our reference wavelengths |
---|
776 | OPEN (unit=14, file='SEXT_sulfate_internal_mixture_5wave.txt') |
---|
777 | WRITE(14,*) |
---|
778 | . ' !-- Extinction Sulfate Accumulation (BC content=0)' |
---|
779 | DO k=NbandSW+1,NbandSW+nb_lambda |
---|
780 | WRITE(14,950) (ss_a(1,irh,k), irh=1,Nrh) |
---|
781 | ENDDO |
---|
782 | CLOSE(14) |
---|
783 | OPEN (unit=14, file='SABS_sulfate_internal_mixture_5wave.txt') |
---|
784 | WRITE(14,*) |
---|
785 | . ' !-- Absorption Sulfate Accumulation (BC content=0)' |
---|
786 | DO k=NbandSW+1,NbandSW+nb_lambda |
---|
787 | WRITE(14,950) ((1.0-ss_w(1,irh,k))*ss_a(1,irh,k), irh=1,Nrh) |
---|
788 | ENDDO |
---|
789 | CLOSE(14) |
---|
790 | |
---|
791 | OPEN |
---|
792 | . (unit=14, file='SEXT_sulfate+2%bc_internal_mixture_5wave.txt') |
---|
793 | WRITE(14,*) |
---|
794 | . ' !-- Extinction Sulfate Accumulation (BC content=2%)' |
---|
795 | DO k=NbandSW+1,NbandSW+nb_lambda |
---|
796 | WRITE(14,950) (ss_a(4,irh,k), irh=1,Nrh) |
---|
797 | ENDDO |
---|
798 | CLOSE(14) |
---|
799 | OPEN |
---|
800 | . (unit=14, file='SABS_sulfate+2%bc_internal_mixture_5wave.txt') |
---|
801 | WRITE(14,*) |
---|
802 | . ' !-- Absorption Sulfate Accumulation (BC content=2%)' |
---|
803 | DO k=NbandSW+1,NbandSW+nb_lambda |
---|
804 | WRITE(14,950) ((1.0-ss_w(4,irh,k))*ss_a(4,irh,k), irh=1,Nrh) |
---|
805 | ENDDO |
---|
806 | CLOSE(14) |
---|
807 | |
---|
808 | c OPEN (unit=14, file='SSA_sulfate_internal_mixture_5wave.txt') |
---|
809 | c WRITE(14,*) ' !-- Sulfate Accumulation (BC content=0)' |
---|
810 | c DO k=NbandSW+1,NbandSW+nb_lambda |
---|
811 | c WRITE(14,951) (ss_w(1,irh,k), irh=1,Nrh) |
---|
812 | c ENDDO |
---|
813 | c CLOSE(14) |
---|
814 | c |
---|
815 | c OPEN (unit=14, file='CG_sulfate_internal_mixture_5wave.txt') |
---|
816 | c WRITE(14,*) ' !-- Sulfate Accumulation (BC content=0)' |
---|
817 | c DO k=NbandSW+1,NbandSW+nb_lambda |
---|
818 | c WRITE(14,951) (ss_g(1,irh,k), irh=1,Nrh) |
---|
819 | c ENDDO |
---|
820 | c CLOSE(14) |
---|
821 | c |
---|
822 | c--saving MEC and MAC for equivalent BC for our reference wavelengths |
---|
823 | OPEN (unit=14, file='DATA_BC_internal_mixture_5wave.txt') |
---|
824 | WRITE(14,*) ' DATA alpha_MG_5wv/ &' |
---|
825 | DO class=2, Nclass |
---|
826 | WRITE(14,900) bc_content(class) |
---|
827 | DO k=NbandSW+1,NbandSW+nb_lambda |
---|
828 | WRITE(14,951) (ss_a_bc(class,irh,k),irh=1,Nrh) |
---|
829 | ENDDO |
---|
830 | ENDDO |
---|
831 | WRITE(14,*) ' ' |
---|
832 | WRITE(14,*) ' DATA abs_MG_5wv/ &' |
---|
833 | DO class=2, Nclass |
---|
834 | WRITE(14,900) bc_content(class) |
---|
835 | DO k=NbandSW+1,NbandSW+nb_lambda |
---|
836 | WRITE(14,951) |
---|
837 | . ((1.0-ss_w_bc(class,irh,k))*ss_a_bc(class,irh,k),irh=1,Nrh) |
---|
838 | ENDDO |
---|
839 | ENDDO |
---|
840 | CLOSE(14) |
---|
841 | |
---|
842 | c OPEN (unit=14, file='SSA_BC_internal_mixture_5wave.txt') |
---|
843 | c WRITE(14,*) ' DATA piz_MG_5wv/ &' |
---|
844 | c DO class=2, Nclass |
---|
845 | c WRITE(14,900) bc_content(class) |
---|
846 | c DO k=NbandSW+1,NbandSW+nb_lambda |
---|
847 | c WRITE(14,951) (ss_w_bc(class,irh,k),irh=1,Nrh) |
---|
848 | c ENDDO |
---|
849 | c ENDDO |
---|
850 | c CLOSE(14) |
---|
851 | c |
---|
852 | c OPEN (unit=14, file='G_BC_internal_mixture_5wave.txt') |
---|
853 | c WRITE(14,*) ' DATA cg_MG_5wv/ &' |
---|
854 | c DO class=2, Nclass |
---|
855 | c WRITE(14,900) bc_content(class) |
---|
856 | c DO k=NbandSW+1,NbandSW+nb_lambda |
---|
857 | c WRITE(14,951) (ss_g_bc(class,irh,k),irh=1,Nrh) |
---|
858 | c ENDDO |
---|
859 | c ENDDO |
---|
860 | c CLOSE(14) |
---|
861 | c |
---|
862 | 900 FORMAT(1X,'!--BC content=',F5.3) |
---|
863 | 950 FORMAT(1X,12(F6.3,','),' &') |
---|
864 | 951 FORMAT(1X,12(F7.3,','),' &') |
---|
865 | c |
---|
866 | END |
---|