Line data Source code
1 : !=======================================================================
2 : !
3 : ! The albedo and absorbed/transmitted flux parameterizations for
4 : ! snow over ice, bare ice and ponded ice.
5 : !
6 : ! Presently, two methods are included:
7 : ! (1) CCSM3
8 : ! (2) Delta-Eddington
9 : ! as two distinct routines.
10 : ! Either can be called from the ice driver.
11 : !
12 : ! The Delta-Eddington method is described here:
13 : !
14 : ! Briegleb, B. P., and B. Light (2007): A Delta-Eddington Multiple
15 : ! Scattering Parameterization for Solar Radiation in the Sea Ice
16 : ! Component of the Community Climate System Model, NCAR Technical
17 : ! Note NCAR/TN-472+STR February 2007
18 : !
19 : ! name: originally ice_albedo
20 : !
21 : ! authors: Bruce P. Briegleb, NCAR
22 : ! Elizabeth C. Hunke and William H. Lipscomb, LANL
23 : ! 2005, WHL: Moved absorbed_solar from icepack_therm_vertical to this
24 : ! module and changed name from ice_albedo
25 : ! 2006, WHL: Added Delta Eddington routines from Bruce Briegleb
26 : ! 2006, ECH: Changed data statements in Delta Eddington routines (no
27 : ! longer hardwired)
28 : ! Converted to free source form (F90)
29 : ! 2007, BPB: Completely updated Delta-Eddington code, so that:
30 : ! (1) multiple snow layers enabled (i.e. nslyr > 1)
31 : ! (2) included SSL for snow surface absorption
32 : ! (3) added Sswabs for internal snow layer absorption
33 : ! (4) variable sea ice layers allowed (i.e. not hardwired)
34 : ! (5) updated all inherent optical properties
35 : ! (6) included algae absorption for sea ice lowest layer
36 : ! (7) very complete internal documentation included
37 : ! 2007, ECH: Improved efficiency
38 : ! 2008, BPB: Added aerosols to Delta Eddington code
39 : ! 2013, ECH: merged with NCAR version, cleaned up
40 :
41 : module icepack_shortwave
42 :
43 : use icepack_kinds
44 : use icepack_parameters, only: c0, c1, c1p5, c2, c3, c4, c10
45 : use icepack_parameters, only: p01, p1, p15, p25, p5, p75, puny
46 : use icepack_parameters, only: albocn, Timelt, snowpatch, awtvdr, awtidr, awtvdf, awtidf
47 : use icepack_parameters, only: kappav, hs_min, rhofresh, rhos, nspint
48 : use icepack_parameters, only: hi_ssl, hs_ssl, min_bgc, sk_l
49 : use icepack_parameters, only: z_tracers, skl_bgc, calc_tsfc, shortwave, kalg, heat_capacity
50 : use icepack_parameters, only: r_ice, r_pnd, r_snw, dt_mlt, rsnw_mlt, hs0, hs1, hp1
51 : use icepack_parameters, only: pndaspect, albedo_type, albicev, albicei, albsnowv, albsnowi, ahmax
52 : use icepack_tracers, only: ntrcr, nbtrcr_sw
53 : use icepack_tracers, only: tr_pond_cesm, tr_pond_lvl, tr_pond_topo
54 : use icepack_tracers, only: tr_bgc_N, tr_aero
55 : use icepack_tracers, only: nt_bgc_N, nt_zaero, tr_bgc_N
56 : use icepack_tracers, only: tr_zaero, nlt_chl_sw, nlt_zaero_sw
57 : use icepack_tracers, only: n_algae, n_aero, n_zaero
58 : use icepack_warnings, only: warnstr, icepack_warnings_add
59 : use icepack_warnings, only: icepack_warnings_setabort, icepack_warnings_aborted
60 :
61 : use icepack_zbgc_shared,only: R_chl2N, F_abs_chl
62 : use icepack_zbgc_shared,only: remap_zbgc
63 : use icepack_orbital, only: compute_coszen
64 :
65 :
66 : implicit none
67 :
68 : private
69 : public :: run_dEdd, &
70 : shortwave_ccsm3, &
71 : compute_shortwave_trcr, &
72 : icepack_prep_radiation, &
73 : icepack_step_radiation
74 :
75 : real (kind=dbl_kind), parameter :: &
76 : hpmin = 0.005_dbl_kind, & ! minimum allowed melt pond depth (m)
77 : hp0 = 0.200_dbl_kind ! pond depth below which transition to bare ice
78 :
79 : real (kind=dbl_kind), parameter :: &
80 : exp_argmax = c10 ! maximum argument of exponential
81 :
82 : !=======================================================================
83 :
84 : contains
85 :
86 : !=======================================================================
87 : !
88 : ! Driver for basic solar radiation from CCSM3. Albedos and absorbed solar.
89 :
90 289620 : subroutine shortwave_ccsm3 (aicen, vicen, &
91 144810 : vsnon, Tsfcn, &
92 : swvdr, swvdf, &
93 : swidr, swidf, &
94 : heat_capacity, &
95 0 : albedo_type, &
96 : albicev, albicei, &
97 : albsnowv, albsnowi, &
98 : ahmax, &
99 144810 : alvdrn, alidrn, &
100 144810 : alvdfn, alidfn, &
101 144810 : fswsfc, fswint, &
102 144810 : fswthru, &
103 144810 : fswthru_vdr, &
104 144810 : fswthru_vdf, &
105 144810 : fswthru_idr, &
106 144810 : fswthru_idf, &
107 144810 : fswpenl, &
108 289620 : Iswabs, SSwabs, &
109 144810 : albin, albsn, &
110 : coszen, ncat, &
111 : nilyr)
112 :
113 : integer (kind=int_kind), intent(in) :: &
114 : nilyr , & ! number of ice layers
115 : ncat ! number of ice thickness categories
116 :
117 : real (kind=dbl_kind), dimension (:), intent(in) :: &
118 : aicen , & ! concentration of ice per category
119 : vicen , & ! volume of ice per category
120 : vsnon , & ! volume of ice per category
121 : Tsfcn ! surface temperature
122 :
123 : real (kind=dbl_kind), intent(in) :: &
124 : swvdr , & ! sw down, visible, direct (W/m^2)
125 : swvdf , & ! sw down, visible, diffuse (W/m^2)
126 : swidr , & ! sw down, near IR, direct (W/m^2)
127 : swidf ! sw down, near IR, diffuse (W/m^2)
128 :
129 : ! baseline albedos for ccsm3 shortwave, set in namelist
130 : real (kind=dbl_kind), intent(in) :: &
131 : albicev , & ! visible ice albedo for h > ahmax
132 : albicei , & ! near-ir ice albedo for h > ahmax
133 : albsnowv, & ! cold snow albedo, visible
134 : albsnowi, & ! cold snow albedo, near IR
135 : ahmax ! thickness above which ice albedo is constant (m)
136 :
137 : logical(kind=log_kind), intent(in) :: &
138 : heat_capacity! if true, ice has nonzero heat capacity
139 :
140 : character (len=char_len), intent(in) :: &
141 : albedo_type ! albedo parameterization, 'ccsm3' or 'constant'
142 :
143 : real (kind=dbl_kind), dimension (:), intent(inout) :: &
144 : alvdrn , & ! visible, direct, avg (fraction)
145 : alidrn , & ! near-ir, direct, avg (fraction)
146 : alvdfn , & ! visible, diffuse, avg (fraction)
147 : alidfn , & ! near-ir, diffuse, avg (fraction)
148 : fswsfc , & ! SW absorbed at ice/snow surface (W m-2)
149 : fswint , & ! SW absorbed in ice interior, below surface (W m-2)
150 : fswthru , & ! SW through ice to ocean (W m-2)
151 : albin , & ! bare ice albedo
152 : albsn ! snow albedo
153 :
154 : real (kind=dbl_kind), dimension (:), intent(out), optional :: &
155 : fswthru_vdr , & ! vis dir SW through ice to ocean (W m-2)
156 : fswthru_vdf , & ! vis dif SW through ice to ocean (W m-2)
157 : fswthru_idr , & ! nir dir SW through ice to ocean (W m-2)
158 : fswthru_idf ! nir dif SW through ice to ocean (W m-2)
159 :
160 : real (kind=dbl_kind), intent(inout) :: &
161 : coszen ! cosine(zenith angle)
162 :
163 : real (kind=dbl_kind), dimension (:,:), intent(inout) :: &
164 : fswpenl , & ! SW entering ice layers (W m-2)
165 : Iswabs , & ! SW absorbed in particular layer (W m-2)
166 : Sswabs ! SW absorbed in particular layer (W m-2)
167 :
168 : ! local variables
169 :
170 : integer (kind=int_kind) :: &
171 : n ! thickness category index
172 :
173 : ! ice and snow albedo for each category
174 :
175 : real (kind=dbl_kind) :: &
176 52566 : alvdrni, & ! visible, direct, ice (fraction)
177 52566 : alidrni, & ! near-ir, direct, ice (fraction)
178 52566 : alvdfni, & ! visible, diffuse, ice (fraction)
179 52566 : alidfni, & ! near-ir, diffuse, ice (fraction)
180 52566 : alvdrns, & ! visible, direct, snow (fraction)
181 52566 : alidrns, & ! near-ir, direct, snow (fraction)
182 52566 : alvdfns, & ! visible, diffuse, snow (fraction)
183 52566 : alidfns ! near-ir, diffuse, snow (fraction)
184 :
185 : real (kind=dbl_kind), dimension(:), allocatable :: &
186 144810 : l_fswthru_vdr , & ! vis dir SW through ice to ocean (W m-2)
187 144810 : l_fswthru_vdf , & ! vis dif SW through ice to ocean (W m-2)
188 144810 : l_fswthru_idr , & ! nir dir SW through ice to ocean (W m-2)
189 144810 : l_fswthru_idf ! nir dif SW through ice to ocean (W m-2)
190 :
191 : character(len=*),parameter :: subname='(shortwave_ccsm3)'
192 :
193 : !-----------------------------------------------------------------
194 : ! Solar radiation: albedo and absorbed shortwave
195 : !-----------------------------------------------------------------
196 :
197 144810 : allocate(l_fswthru_vdr(ncat))
198 144810 : allocate(l_fswthru_vdf(ncat))
199 144810 : allocate(l_fswthru_idr(ncat))
200 144810 : allocate(l_fswthru_idf(ncat))
201 :
202 : ! For basic shortwave, set coszen to a constant between 0 and 1.
203 144810 : coszen = p5 ! sun above the horizon
204 :
205 868860 : do n = 1, ncat
206 :
207 1448100 : Sswabs(:,n) = c0
208 :
209 724050 : alvdrni = albocn
210 724050 : alidrni = albocn
211 724050 : alvdfni = albocn
212 724050 : alidfni = albocn
213 :
214 724050 : alvdrns = albocn
215 724050 : alidrns = albocn
216 724050 : alvdfns = albocn
217 724050 : alidfns = albocn
218 :
219 724050 : alvdrn(n) = albocn
220 724050 : alidrn(n) = albocn
221 724050 : alvdfn(n) = albocn
222 724050 : alidfn(n) = albocn
223 :
224 724050 : albin(n) = c0
225 724050 : albsn(n) = c0
226 :
227 724050 : fswsfc(n) = c0
228 724050 : fswint(n) = c0
229 724050 : fswthru(n) = c0
230 4344300 : fswpenl(:,n) = c0
231 3620250 : Iswabs (:,n) = c0
232 :
233 868860 : if (aicen(n) > puny) then
234 :
235 : !-----------------------------------------------------------------
236 : ! Compute albedos for ice and snow.
237 : !-----------------------------------------------------------------
238 :
239 591299 : if (trim(albedo_type) == 'constant') then
240 :
241 81020 : call constant_albedos (aicen(n), &
242 81020 : vsnon(n), &
243 81020 : Tsfcn(n), &
244 : alvdrni, alidrni, &
245 : alvdfni, alidfni, &
246 : alvdrns, alidrns, &
247 : alvdfns, alidfns, &
248 81020 : alvdrn(n), &
249 81020 : alidrn(n), &
250 81020 : alvdfn(n), &
251 81020 : alidfn(n), &
252 81020 : albin(n), &
253 230918 : albsn(n))
254 230918 : if (icepack_warnings_aborted(subname)) return
255 :
256 360381 : elseif (trim(albedo_type) == 'ccsm3') then
257 :
258 130625 : call compute_albedos (aicen(n), &
259 130625 : vicen(n), &
260 130625 : vsnon(n), &
261 130625 : Tsfcn(n), &
262 : albicev, albicei, &
263 : albsnowv, albsnowi, &
264 : ahmax, &
265 : alvdrni, alidrni, &
266 : alvdfni, alidfni, &
267 : alvdrns, alidrns, &
268 : alvdfns, alidfns, &
269 130625 : alvdrn(n), &
270 130625 : alidrn(n), &
271 130625 : alvdfn(n), &
272 130625 : alidfn(n), &
273 130625 : albin(n), &
274 360381 : albsn(n))
275 360381 : if (icepack_warnings_aborted(subname)) return
276 :
277 : else
278 :
279 0 : call icepack_warnings_add(subname//' ERROR: albedo_type '//trim(albedo_type)//' unknown')
280 0 : call icepack_warnings_setabort(.true.,__FILE__,__LINE__)
281 0 : return
282 :
283 : endif
284 :
285 : !-----------------------------------------------------------------
286 : ! Compute solar radiation absorbed in ice and penetrating to ocean.
287 : !-----------------------------------------------------------------
288 :
289 : call absorbed_solar (heat_capacity, &
290 : nilyr, &
291 211645 : aicen(n), &
292 211645 : vicen(n), &
293 211645 : vsnon(n), &
294 : swvdr, swvdf, &
295 : swidr, swidf, &
296 : alvdrni, alvdfni, &
297 : alidrni, alidfni, &
298 : alvdrns, alvdfns, &
299 : alidrns, alidfns, &
300 211645 : fswsfc=fswsfc(n), &
301 211645 : fswint=fswint(n), &
302 211645 : fswthru=fswthru(n), &
303 0 : fswthru_vdr=l_fswthru_vdr(n),&
304 0 : fswthru_vdf=l_fswthru_vdf(n),&
305 0 : fswthru_idr=l_fswthru_idr(n),&
306 0 : fswthru_idf=l_fswthru_idf(n),&
307 0 : fswpenl=fswpenl(:,n), &
308 591299 : Iswabs=Iswabs(:,n))
309 :
310 591299 : if (icepack_warnings_aborted(subname)) return
311 :
312 : endif ! aicen > puny
313 :
314 : enddo ! ncat
315 :
316 868860 : if(present(fswthru_vdr)) fswthru_vdr = l_fswthru_vdr
317 868860 : if(present(fswthru_vdf)) fswthru_vdf = l_fswthru_vdf
318 868860 : if(present(fswthru_idr)) fswthru_idr = l_fswthru_idr
319 868860 : if(present(fswthru_idf)) fswthru_idf = l_fswthru_idf
320 :
321 144810 : deallocate(l_fswthru_vdr)
322 144810 : deallocate(l_fswthru_vdf)
323 144810 : deallocate(l_fswthru_idr)
324 144810 : deallocate(l_fswthru_idf)
325 :
326 144810 : end subroutine shortwave_ccsm3
327 :
328 : !=======================================================================
329 : !
330 : ! Compute albedos for each thickness category
331 :
332 360381 : subroutine compute_albedos (aicen, vicen, &
333 : vsnon, Tsfcn, &
334 : albicev, albicei, &
335 : albsnowv, albsnowi, &
336 : ahmax, &
337 : alvdrni, alidrni, &
338 : alvdfni, alidfni, &
339 : alvdrns, alidrns, &
340 : alvdfns, alidfns, &
341 : alvdrn, alidrn, &
342 : alvdfn, alidfn, &
343 : albin, albsn)
344 :
345 : real (kind=dbl_kind), intent(in) :: &
346 : aicen , & ! concentration of ice per category
347 : vicen , & ! volume of ice per category
348 : vsnon , & ! volume of ice per category
349 : Tsfcn ! surface temperature
350 :
351 : ! baseline albedos for ccsm3 shortwave, set in namelist
352 : real (kind=dbl_kind), intent(in) :: &
353 : albicev , & ! visible ice albedo for h > ahmax
354 : albicei , & ! near-ir ice albedo for h > ahmax
355 : albsnowv, & ! cold snow albedo, visible
356 : albsnowi, & ! cold snow albedo, near IR
357 : ahmax ! thickness above which ice albedo is constant (m)
358 :
359 : real (kind=dbl_kind), intent(out) :: &
360 : alvdrni , & ! visible, direct, ice (fraction)
361 : alidrni , & ! near-ir, direct, ice (fraction)
362 : alvdfni , & ! visible, diffuse, ice (fraction)
363 : alidfni , & ! near-ir, diffuse, ice (fraction)
364 : alvdrns , & ! visible, direct, snow (fraction)
365 : alidrns , & ! near-ir, direct, snow (fraction)
366 : alvdfns , & ! visible, diffuse, snow (fraction)
367 : alidfns , & ! near-ir, diffuse, snow (fraction)
368 : alvdrn , & ! visible, direct, avg (fraction)
369 : alidrn , & ! near-ir, direct, avg (fraction)
370 : alvdfn , & ! visible, diffuse, avg (fraction)
371 : alidfn , & ! near-ir, diffuse, avg (fraction)
372 : albin , & ! bare ice
373 : albsn ! snow
374 :
375 : ! local variables
376 :
377 : real (kind=dbl_kind), parameter :: &
378 : dT_melt = c1 , & ! change in temp to give dalb_mlt
379 : ! albedo change
380 : dalb_mlt = -0.075_dbl_kind, & ! albedo change per dT_melt change
381 : ! in temp for ice
382 : dalb_mltv = -p1 , & ! albedo vis change per dT_melt change
383 : ! in temp for snow
384 : dalb_mlti = -p15 ! albedo nir change per dT_melt change
385 : ! in temp for snow
386 :
387 : real (kind=dbl_kind) :: &
388 130625 : hi , & ! ice thickness (m)
389 130625 : hs , & ! snow thickness (m)
390 130625 : albo, & ! effective ocean albedo, function of ice thickness
391 130625 : fh , & ! piecewise linear function of thickness
392 130625 : fT , & ! piecewise linear function of surface temperature
393 130625 : dTs , & ! difference of Tsfc and Timelt
394 130625 : fhtan,& ! factor used in albedo dependence on ice thickness
395 130625 : asnow ! fractional area of snow cover
396 :
397 : character(len=*),parameter :: subname='(compute_albedos)'
398 :
399 360381 : fhtan = atan(ahmax*c4)
400 :
401 : !-----------------------------------------------------------------
402 : ! Compute albedo for each thickness category.
403 : !-----------------------------------------------------------------
404 :
405 360381 : hi = vicen / aicen
406 360381 : hs = vsnon / aicen
407 :
408 : ! bare ice, thickness dependence
409 360381 : fh = min(atan(hi*c4)/fhtan,c1)
410 360381 : albo = albocn*(c1-fh)
411 360381 : alvdfni = albicev*fh + albo
412 360381 : alidfni = albicei*fh + albo
413 :
414 : ! bare ice, temperature dependence
415 360381 : dTs = Timelt - Tsfcn
416 360381 : fT = min(dTs/dT_melt-c1,c0)
417 360381 : alvdfni = alvdfni - dalb_mlt*fT
418 360381 : alidfni = alidfni - dalb_mlt*fT
419 :
420 : ! avoid negative albedos for thin, bare, melting ice
421 360381 : alvdfni = max (alvdfni, albocn)
422 360381 : alidfni = max (alidfni, albocn)
423 :
424 360381 : if (hs > puny) then
425 :
426 341291 : alvdfns = albsnowv
427 341291 : alidfns = albsnowi
428 :
429 : ! snow on ice, temperature dependence
430 341291 : alvdfns = alvdfns - dalb_mltv*fT
431 341291 : alidfns = alidfns - dalb_mlti*fT
432 :
433 : endif ! hs > puny
434 :
435 : ! direct albedos (same as diffuse for now)
436 360381 : alvdrni = alvdfni
437 360381 : alidrni = alidfni
438 360381 : alvdrns = alvdfns
439 360381 : alidrns = alidfns
440 :
441 : ! fractional area of snow cover
442 360381 : if (hs > puny) then
443 341291 : asnow = hs / (hs + snowpatch)
444 : else
445 19090 : asnow = c0
446 : endif
447 :
448 : ! combine ice and snow albedos (for coupler)
449 : alvdfn = alvdfni*(c1-asnow) + &
450 360381 : alvdfns*asnow
451 : alidfn = alidfni*(c1-asnow) + &
452 360381 : alidfns*asnow
453 : alvdrn = alvdrni*(c1-asnow) + &
454 360381 : alvdrns*asnow
455 : alidrn = alidrni*(c1-asnow) + &
456 360381 : alidrns*asnow
457 :
458 : ! save ice and snow albedos (for history)
459 : albin = awtvdr*alvdrni + awtidr*alidrni &
460 360381 : + awtvdf*alvdfni + awtidf*alidfni
461 : albsn = awtvdr*alvdrns + awtidr*alidrns &
462 360381 : + awtvdf*alvdfns + awtidf*alidfns
463 :
464 360381 : end subroutine compute_albedos
465 :
466 : !=======================================================================
467 : !
468 : ! Compute albedos for each thickness category
469 :
470 230918 : subroutine constant_albedos (aicen, &
471 : vsnon, Tsfcn, &
472 : alvdrni, alidrni, &
473 : alvdfni, alidfni, &
474 : alvdrns, alidrns, &
475 : alvdfns, alidfns, &
476 : alvdrn, alidrn, &
477 : alvdfn, alidfn, &
478 : albin, albsn)
479 :
480 : real (kind=dbl_kind), intent(in) :: &
481 : aicen , & ! concentration of ice per category
482 : vsnon , & ! volume of ice per category
483 : Tsfcn ! surface temperature
484 :
485 : real (kind=dbl_kind), intent(out) :: &
486 : alvdrni , & ! visible, direct, ice (fraction)
487 : alidrni , & ! near-ir, direct, ice (fraction)
488 : alvdfni , & ! visible, diffuse, ice (fraction)
489 : alidfni , & ! near-ir, diffuse, ice (fraction)
490 : alvdrns , & ! visible, direct, snow (fraction)
491 : alidrns , & ! near-ir, direct, snow (fraction)
492 : alvdfns , & ! visible, diffuse, snow (fraction)
493 : alidfns , & ! near-ir, diffuse, snow (fraction)
494 : alvdrn , & ! visible, direct, avg (fraction)
495 : alidrn , & ! near-ir, direct, avg (fraction)
496 : alvdfn , & ! visible, diffuse, avg (fraction)
497 : alidfn , & ! near-ir, diffuse, avg (fraction)
498 : albin , & ! bare ice
499 : albsn ! snow
500 :
501 : ! local variables
502 :
503 : real (kind=dbl_kind), parameter :: &
504 : warmice = 0.68_dbl_kind, &
505 : coldice = 0.70_dbl_kind, &
506 : warmsnow = 0.77_dbl_kind, &
507 : coldsnow = 0.81_dbl_kind
508 :
509 : real (kind=dbl_kind) :: &
510 81020 : hs ! snow thickness (m)
511 :
512 : character(len=*),parameter :: subname='(constant_albedos)'
513 :
514 : !-----------------------------------------------------------------
515 : ! Compute albedo for each thickness category.
516 : !-----------------------------------------------------------------
517 :
518 230918 : hs = vsnon / aicen
519 :
520 230918 : if (hs > puny) then
521 : ! snow, temperature dependence
522 95564 : if (Tsfcn >= -c2*puny) then
523 0 : alvdfn = warmsnow
524 0 : alidfn = warmsnow
525 : else
526 95564 : alvdfn = coldsnow
527 95564 : alidfn = coldsnow
528 : endif
529 : else ! hs < puny
530 : ! bare ice, temperature dependence
531 135354 : if (Tsfcn >= -c2*puny) then
532 0 : alvdfn = warmice
533 0 : alidfn = warmice
534 : else
535 135354 : alvdfn = coldice
536 135354 : alidfn = coldice
537 : endif
538 : endif ! hs > puny
539 :
540 : ! direct albedos (same as diffuse for now)
541 230918 : alvdrn = alvdfn
542 230918 : alidrn = alidfn
543 :
544 230918 : alvdrni = alvdrn
545 230918 : alidrni = alidrn
546 230918 : alvdrns = alvdrn
547 230918 : alidrns = alidrn
548 230918 : alvdfni = alvdfn
549 230918 : alidfni = alidfn
550 230918 : alvdfns = alvdfn
551 230918 : alidfns = alidfn
552 :
553 : ! save ice and snow albedos (for history)
554 : albin = awtvdr*alvdrni + awtidr*alidrni &
555 230918 : + awtvdf*alvdfni + awtidf*alidfni
556 : albsn = awtvdr*alvdrns + awtidr*alidrns &
557 230918 : + awtvdf*alvdfns + awtidf*alidfns
558 :
559 230918 : end subroutine constant_albedos
560 :
561 : !=======================================================================
562 : !
563 : ! Compute solar radiation absorbed in ice and penetrating to ocean
564 : !
565 : ! authors William H. Lipscomb, LANL
566 : ! C. M. Bitz, UW
567 :
568 591299 : subroutine absorbed_solar (heat_capacity, &
569 : nilyr, aicen, &
570 : vicen, vsnon, &
571 : swvdr, swvdf, &
572 : swidr, swidf, &
573 : alvdrni, alvdfni, &
574 : alidrni, alidfni, &
575 : alvdrns, alvdfns, &
576 : alidrns, alidfns, &
577 : fswsfc, fswint, &
578 : fswthru, &
579 : fswthru_vdr, &
580 : fswthru_vdf, &
581 : fswthru_idr, &
582 : fswthru_idf, &
583 591299 : fswpenl, &
584 591299 : Iswabs)
585 :
586 : logical(kind=log_kind), intent(in) :: &
587 : heat_capacity ! if true, ice has nonzero heat capacity
588 :
589 : integer (kind=int_kind), intent(in) :: &
590 : nilyr ! number of ice layers
591 :
592 : real (kind=dbl_kind), intent(in) :: &
593 : aicen , & ! fractional ice area
594 : vicen , & ! ice volume
595 : vsnon , & ! snow volume
596 : swvdr , & ! sw down, visible, direct (W/m^2)
597 : swvdf , & ! sw down, visible, diffuse (W/m^2)
598 : swidr , & ! sw down, near IR, direct (W/m^2)
599 : swidf , & ! sw down, near IR, diffuse (W/m^2)
600 : alvdrni , & ! visible, direct albedo,ice
601 : alidrni , & ! near-ir, direct albedo,ice
602 : alvdfni , & ! visible, diffuse albedo,ice
603 : alidfni , & ! near-ir, diffuse albedo,ice
604 : alvdrns , & ! visible, direct albedo, snow
605 : alidrns , & ! near-ir, direct albedo, snow
606 : alvdfns , & ! visible, diffuse albedo, snow
607 : alidfns ! near-ir, diffuse albedo, snow
608 :
609 : real (kind=dbl_kind), intent(out):: &
610 : fswsfc , & ! SW absorbed at ice/snow surface (W m-2)
611 : fswint , & ! SW absorbed in ice interior, below surface (W m-2)
612 : fswthru ! SW through ice to ocean (W m-2)
613 :
614 : real (kind=dbl_kind), intent(out) :: &
615 : fswthru_vdr , & ! vis dir SW through ice to ocean (W m-2)
616 : fswthru_vdf , & ! vis dif SW through ice to ocean (W m-2)
617 : fswthru_idr , & ! nir dir SW through ice to ocean (W m-2)
618 : fswthru_idf ! nir dif SW through ice to ocean (W m-2)
619 :
620 : real (kind=dbl_kind), dimension (:), intent(out) :: &
621 : Iswabs , & ! SW absorbed in particular layer (W m-2)
622 : fswpenl ! visible SW entering ice layers (W m-2)
623 :
624 : ! local variables
625 :
626 : real (kind=dbl_kind), parameter :: &
627 : i0vis = 0.70_dbl_kind ! fraction of penetrating solar rad (visible)
628 :
629 : integer (kind=int_kind) :: &
630 : k ! ice layer index
631 :
632 : real (kind=dbl_kind) :: &
633 211645 : fswpen , & ! SW penetrating beneath surface (W m-2)
634 211645 : trantop , & ! transmitted frac of penetrating SW at layer top
635 211645 : tranbot ! transmitted frac of penetrating SW at layer bot
636 :
637 : real (kind=dbl_kind) :: &
638 211645 : swabs , & ! net SW down at surface (W m-2)
639 211645 : swabsv , & ! swabs in vis (wvlngth < 700nm) (W/m^2)
640 211645 : swabsi , & ! swabs in nir (wvlngth > 700nm) (W/m^2)
641 211645 : fswpenvdr , & ! penetrating SW, vis direct
642 211645 : fswpenvdf , & ! penetrating SW, vis diffuse
643 211645 : hi , & ! ice thickness (m)
644 211645 : hs , & ! snow thickness (m)
645 211645 : hilyr , & ! ice layer thickness
646 211645 : asnow ! fractional area of snow cover
647 :
648 : character(len=*),parameter :: subname='(absorbed_solar)'
649 :
650 : !-----------------------------------------------------------------
651 : ! Initialize
652 : !-----------------------------------------------------------------
653 :
654 591299 : trantop = c0
655 591299 : tranbot = c0
656 :
657 591299 : hs = vsnon / aicen
658 :
659 : !-----------------------------------------------------------------
660 : ! Fractional snow cover
661 : !-----------------------------------------------------------------
662 591299 : if (hs > puny) then
663 436855 : asnow = hs / (hs + snowpatch)
664 : else
665 154444 : asnow = c0
666 : endif
667 :
668 : !-----------------------------------------------------------------
669 : ! Shortwave flux absorbed at surface, absorbed internally,
670 : ! and penetrating to mixed layer.
671 : ! This parameterization assumes that all IR is absorbed at the
672 : ! surface; only visible is absorbed in the ice interior or
673 : ! transmitted to the ocean.
674 : !-----------------------------------------------------------------
675 :
676 : swabsv = swvdr * ( (c1-alvdrni)*(c1-asnow) &
677 : + (c1-alvdrns)*asnow ) &
678 : + swvdf * ( (c1-alvdfni)*(c1-asnow) &
679 591299 : + (c1-alvdfns)*asnow )
680 :
681 : swabsi = swidr * ( (c1-alidrni)*(c1-asnow) &
682 : + (c1-alidrns)*asnow ) &
683 : + swidf * ( (c1-alidfni)*(c1-asnow) &
684 591299 : + (c1-alidfns)*asnow )
685 :
686 591299 : swabs = swabsv + swabsi
687 :
688 591299 : fswpenvdr = swvdr * (c1-alvdrni) * (c1-asnow) * i0vis
689 591299 : fswpenvdf = swvdf * (c1-alvdfni) * (c1-asnow) * i0vis
690 :
691 : ! no penetrating radiation in near IR
692 : ! fswpenidr = swidr * (c1-alidrni) * (c1-asnow) * i0nir
693 : ! fswpenidf = swidf * (c1-alidfni) * (c1-asnow) * i0nir
694 :
695 591299 : fswpen = fswpenvdr + fswpenvdf
696 :
697 591299 : fswsfc = swabs - fswpen
698 :
699 591299 : trantop = c1 ! transmittance at top of ice
700 :
701 : !-----------------------------------------------------------------
702 : ! penetrating SW absorbed in each ice layer
703 : !-----------------------------------------------------------------
704 :
705 3344884 : do k = 1, nilyr
706 :
707 2753585 : hi = vicen / aicen
708 2753585 : hilyr = hi / real(nilyr,kind=dbl_kind)
709 :
710 2753585 : tranbot = exp (-kappav * hilyr * real(k,kind=dbl_kind))
711 2753585 : Iswabs(k) = fswpen * (trantop-tranbot)
712 :
713 : ! bottom of layer k = top of layer k+1
714 2753585 : trantop = tranbot
715 :
716 : ! bgc layer model
717 3344884 : if (k == 1) then ! surface flux
718 591299 : fswpenl(k) = fswpen
719 591299 : fswpenl(k+1) = fswpen * tranbot
720 : else
721 2162286 : fswpenl(k+1) = fswpen * tranbot
722 : endif
723 : enddo ! nilyr
724 :
725 : ! SW penetrating thru ice into ocean
726 591299 : fswthru = fswpen * tranbot
727 591299 : fswthru_vdr = fswpenvdr * tranbot
728 591299 : fswthru_vdf = fswpenvdf * tranbot
729 591299 : fswthru_idr = c0
730 591299 : fswthru_idf = c0
731 :
732 : ! SW absorbed in ice interior
733 591299 : fswint = fswpen - fswthru
734 :
735 : !----------------------------------------------------------------
736 : ! if zero-layer model (no heat capacity), no SW is absorbed in ice
737 : ! interior, so add to surface absorption
738 : !----------------------------------------------------------------
739 :
740 591299 : if (.not. heat_capacity) then
741 :
742 : ! SW absorbed at snow/ice surface
743 230918 : fswsfc = fswsfc + fswint
744 :
745 : ! SW absorbed in ice interior (nilyr = 1)
746 230918 : fswint = c0
747 230918 : Iswabs(1) = c0
748 :
749 : endif ! heat_capacity
750 :
751 591299 : end subroutine absorbed_solar
752 :
753 : ! End ccsm3 shortwave method
754 : !=======================================================================
755 : ! Begin Delta-Eddington shortwave method
756 :
757 : ! Compute initial data for Delta-Eddington method, specifically,
758 : ! the approximate exponential look-up table.
759 : !
760 : ! author: Bruce P. Briegleb, NCAR
761 : ! 2011 ECH modified for melt pond tracers
762 : ! 2013 ECH merged with NCAR version
763 :
764 909228 : subroutine run_dEdd(dt, ncat, &
765 : dEdd_algae, &
766 : nilyr, nslyr, &
767 1818456 : aicen, vicen, &
768 909228 : vsnon, Tsfcn, &
769 1818456 : alvln, apndn, &
770 1818456 : hpndn, ipndn, &
771 909228 : aeron, kalg, &
772 909228 : trcrn_bgcsw, &
773 : heat_capacity, &
774 : tlat, tlon, &
775 0 : calendar_type, &
776 : days_per_year, &
777 : nextsw_cday, yday, &
778 : sec, R_ice, &
779 : R_pnd, R_snw, &
780 : dT_mlt, rsnw_mlt, &
781 : hs0, hs1, hp1, &
782 : pndaspect, &
783 909228 : kaer_tab, waer_tab, &
784 909228 : gaer_tab, &
785 909228 : kaer_bc_tab, &
786 909228 : waer_bc_tab, &
787 909228 : gaer_bc_tab, &
788 909228 : bcenh, &
789 : modal_aero, &
790 : swvdr, swvdf, &
791 : swidr, swidf, &
792 : coszen, fsnow, &
793 909228 : alvdrn, alvdfn, &
794 909228 : alidrn, alidfn, &
795 909228 : fswsfcn, fswintn, &
796 909228 : fswthrun, &
797 909228 : fswthrun_vdr, &
798 909228 : fswthrun_vdf, &
799 909228 : fswthrun_idr, &
800 909228 : fswthrun_idf, &
801 909228 : fswpenln, &
802 909228 : Sswabsn, Iswabsn, &
803 909228 : albicen, albsnon, &
804 1818456 : albpndn, apeffn, &
805 909228 : snowfracn, &
806 909228 : dhsn, ffracn, &
807 : l_print_point, &
808 : initonly)
809 :
810 : integer (kind=int_kind), intent(in) :: &
811 : ncat , & ! number of ice thickness categories
812 : nilyr , & ! number of ice layers
813 : nslyr ! number of snow layers
814 :
815 : logical(kind=log_kind), intent(in) :: &
816 : heat_capacity,& ! if true, ice has nonzero heat capacity
817 : dEdd_algae, & ! .true. use prognostic chla in dEdd
818 : modal_aero ! .true. use modal aerosol treatment
819 :
820 : ! dEdd tuning parameters, set in namelist
821 : real (kind=dbl_kind), intent(in) :: &
822 : R_ice , & ! sea ice tuning parameter; +1 > 1sig increase in albedo
823 : R_pnd , & ! ponded ice tuning parameter; +1 > 1sig increase in albedo
824 : R_snw , & ! snow tuning parameter; +1 > ~.01 change in broadband albedo
825 : dT_mlt, & ! change in temp for non-melt to melt snow grain radius change (C)
826 : rsnw_mlt, & ! maximum melting snow grain radius (10^-6 m)
827 : hs0 , & ! snow depth for transition to bare sea ice (m)
828 : pndaspect, & ! ratio of pond depth to pond fraction
829 : hs1 , & ! tapering parameter for snow on pond ice
830 : hp1 , & ! critical parameter for pond ice thickness
831 : kalg ! algae absorption coefficient
832 :
833 : real (kind=dbl_kind), dimension(:,:), intent(in) :: &
834 : kaer_tab, & ! aerosol mass extinction cross section (m2/kg)
835 : waer_tab, & ! aerosol single scatter albedo (fraction)
836 : gaer_tab ! aerosol asymmetry parameter (cos(theta))
837 :
838 : real (kind=dbl_kind), dimension(:,:), intent(in) :: & ! Modal aerosol treatment
839 : kaer_bc_tab, & ! aerosol mass extinction cross section (m2/kg)
840 : waer_bc_tab, & ! aerosol single scatter albedo (fraction)
841 : gaer_bc_tab ! aerosol asymmetry parameter (cos(theta))
842 :
843 : real (kind=dbl_kind), dimension(:,:,:), intent(in) :: & ! Modal aerosol treatment
844 : bcenh ! BC absorption enhancement factor
845 :
846 : character (len=char_len), intent(in) :: &
847 : calendar_type ! differentiates Gregorian from other calendars
848 :
849 : integer (kind=int_kind), intent(in) :: &
850 : days_per_year, & ! number of days in one year
851 : sec ! elapsed seconds into date
852 :
853 : real (kind=dbl_kind), intent(in) :: &
854 : nextsw_cday , & ! julian day of next shortwave calculation
855 : yday ! day of the year
856 :
857 : real(kind=dbl_kind), intent(in) :: &
858 : dt, & ! time step (s)
859 : tlat, & ! latitude of temp pts (radians)
860 : tlon, & ! longitude of temp pts (radians)
861 : swvdr, & ! sw down, visible, direct (W/m^2)
862 : swvdf, & ! sw down, visible, diffuse (W/m^2)
863 : swidr, & ! sw down, near IR, direct (W/m^2)
864 : swidf, & ! sw down, near IR, diffuse (W/m^2)
865 : fsnow ! snowfall rate (kg/m^2 s)
866 :
867 : real(kind=dbl_kind), dimension(:), intent(in) :: &
868 : aicen, & ! concentration of ice
869 : vicen, & ! volume per unit area of ice (m)
870 : vsnon, & ! volume per unit area of snow (m)
871 : Tsfcn, & ! surface temperature (deg C)
872 : alvln, & ! level-ice area fraction
873 : apndn, & ! pond area fraction
874 : hpndn, & ! pond depth (m)
875 : ipndn ! pond refrozen lid thickness (m)
876 :
877 : real(kind=dbl_kind), dimension(:,:), intent(in) :: &
878 : aeron, & ! aerosols (kg/m^3)
879 : trcrn_bgcsw ! zaerosols (kg/m^3) + chlorophyll on shorthwave grid
880 :
881 : real(kind=dbl_kind), dimension(:), intent(inout) :: &
882 : ffracn,& ! fraction of fsurfn used to melt ipond
883 : dhsn ! depth difference for snow on sea ice and pond ice
884 :
885 : real(kind=dbl_kind), intent(inout) :: &
886 : coszen ! cosine solar zenith angle, < 0 for sun below horizon
887 :
888 : real(kind=dbl_kind), dimension(:), intent(inout) :: &
889 : alvdrn, & ! visible direct albedo (fraction)
890 : alvdfn, & ! near-ir direct albedo (fraction)
891 : alidrn, & ! visible diffuse albedo (fraction)
892 : alidfn, & ! near-ir diffuse albedo (fraction)
893 : fswsfcn, & ! SW absorbed at ice/snow surface (W m-2)
894 : fswintn, & ! SW absorbed in ice interior, below surface (W m-2)
895 : fswthrun, & ! SW through ice to ocean (W/m^2)
896 : albicen, & ! albedo bare ice
897 : albsnon, & ! albedo snow
898 : albpndn, & ! albedo pond
899 : apeffn, & ! effective pond area used for radiation calculation
900 : snowfracn ! snow fraction on each category used for radiation
901 :
902 : real(kind=dbl_kind), dimension(:), intent(out), optional :: &
903 : fswthrun_vdr, & ! vis dir SW through ice to ocean (W/m^2)
904 : fswthrun_vdf, & ! vis dif SW through ice to ocean (W/m^2)
905 : fswthrun_idr, & ! nir dir SW through ice to ocean (W/m^2)
906 : fswthrun_idf ! nir dif SW through ice to ocean (W/m^2)
907 :
908 : real(kind=dbl_kind), dimension(:,:), intent(inout) :: &
909 : Sswabsn , & ! SW radiation absorbed in snow layers (W m-2)
910 : Iswabsn , & ! SW radiation absorbed in ice layers (W m-2)
911 : fswpenln ! visible SW entering ice layers (W m-2)
912 :
913 : logical (kind=log_kind), intent(in) :: &
914 : l_print_point
915 :
916 : logical (kind=log_kind), optional :: &
917 : initonly ! flag to indicate init only, default is false
918 :
919 : ! local temporary variables
920 :
921 : ! other local variables
922 : ! snow variables for Delta-Eddington shortwave
923 : real (kind=dbl_kind) :: &
924 329481 : fsn , & ! snow horizontal fraction
925 329481 : hsn ! snow depth (m)
926 :
927 : real (kind=dbl_kind), dimension (nslyr) :: &
928 1923588 : rhosnwn , & ! snow density (kg/m3)
929 1923588 : rsnwn ! snow grain radius (micrometers)
930 :
931 : ! pond variables for Delta-Eddington shortwave
932 : real (kind=dbl_kind) :: &
933 329481 : fpn , & ! pond fraction of ice cover
934 329481 : hpn ! actual pond depth (m)
935 :
936 : integer (kind=int_kind) :: &
937 : n ! thickness category index
938 :
939 : real (kind=dbl_kind) :: &
940 329481 : ipn , & ! refrozen pond ice thickness (m), mean over ice fraction
941 329481 : hp , & ! pond depth
942 329481 : hs , & ! snow depth
943 329481 : asnow , & ! fractional area of snow cover
944 329481 : rp , & ! volume fraction of retained melt water to total liquid content
945 329481 : hmx , & ! maximum available snow infiltration equivalent depth
946 329481 : dhs , & ! local difference in snow depth on sea ice and pond ice
947 329481 : spn , & ! snow depth on refrozen pond (m)
948 329481 : tmp ! 0 or 1
949 :
950 : logical (kind=log_kind) :: &
951 : linitonly ! local initonly value
952 :
953 : real (kind=dbl_kind), dimension(:), allocatable :: &
954 909228 : l_fswthrun_vdr , & ! vis dir SW through ice to ocean (W m-2)
955 909228 : l_fswthrun_vdf , & ! vis dif SW through ice to ocean (W m-2)
956 909228 : l_fswthrun_idr , & ! nir dir SW through ice to ocean (W m-2)
957 909228 : l_fswthrun_idf ! nir dif SW through ice to ocean (W m-2)
958 :
959 : character(len=*),parameter :: subname='(run_dEdd)'
960 :
961 909228 : allocate(l_fswthrun_vdr(ncat))
962 909228 : allocate(l_fswthrun_vdf(ncat))
963 909228 : allocate(l_fswthrun_idr(ncat))
964 909228 : allocate(l_fswthrun_idf(ncat))
965 :
966 909228 : linitonly = .false.
967 909228 : if (present(initonly)) then
968 909228 : linitonly = initonly
969 : endif
970 :
971 : ! cosine of the zenith angle
972 : #ifdef CESMCOUPLED
973 : call compute_coszen (tlat, tlon, &
974 : yday, sec, coszen, &
975 : days_per_year, nextsw_cday, calendar_type)
976 : #else
977 : call compute_coszen (tlat, tlon, &
978 909228 : yday, sec, coszen)
979 : #endif
980 909228 : if (icepack_warnings_aborted(subname)) return
981 :
982 5165748 : do n = 1, ncat
983 :
984 : ! note that rhoswn, rsnw, fp, hp and Sswabs ARE NOT dimensioned with ncat
985 : ! BPB 19 Dec 2006
986 :
987 : ! set snow properties
988 4256520 : fsn = c0
989 4256520 : hsn = c0
990 9961140 : rhosnwn(:) = c0
991 9961140 : rsnwn(:) = c0
992 4256520 : apeffn(n) = c0 ! for history
993 4256520 : snowfracn(n) = c0 ! for history
994 :
995 5165748 : if (aicen(n) > puny) then
996 :
997 : call shortwave_dEdd_set_snow(nslyr, R_snw, &
998 : dT_mlt, rsnw_mlt, &
999 1405899 : aicen(n), vsnon(n), &
1000 1405899 : Tsfcn(n), fsn, &
1001 : hs0, hsn, &
1002 3900730 : rhosnwn, rsnwn)
1003 3900730 : if (icepack_warnings_aborted(subname)) return
1004 :
1005 : ! set pond properties
1006 3900730 : if (tr_pond_cesm) then
1007 : ! fraction of ice area
1008 229795 : fpn = apndn(n)
1009 : ! pond depth over fraction fpn
1010 229795 : hpn = hpndn(n)
1011 : ! snow infiltration
1012 229795 : if (hsn >= hs_min .and. hs0 > puny) then
1013 0 : asnow = min(hsn/hs0, c1) ! delta-Eddington formulation
1014 0 : fpn = (c1 - asnow) * fpn
1015 0 : hpn = pndaspect * fpn
1016 : endif
1017 : ! Zero out fraction of thin ponds for radiation only
1018 229795 : if (hpn < hpmin) fpn = c0
1019 229795 : fsn = min(fsn, c1-fpn)
1020 229795 : apeffn(n) = fpn ! for history
1021 3670935 : elseif (tr_pond_lvl) then
1022 3141455 : fpn = c0 ! fraction of ice covered in pond
1023 3141455 : hpn = c0 ! pond depth over fpn
1024 : ! refrozen pond lid thickness avg over ice
1025 : ! allow snow to cover pond ice
1026 3141455 : ipn = alvln(n) * apndn(n) * ipndn(n)
1027 3141455 : dhs = dhsn(n) ! snow depth difference, sea ice - pond
1028 : if (.not. linitonly .and. ipn > puny .and. &
1029 3141455 : dhs < puny .and. fsnow*dt > hs_min) &
1030 10971 : dhs = hsn - fsnow*dt ! initialize dhs>0
1031 3141455 : spn = hsn - dhs ! snow depth on pond ice
1032 3141455 : if (.not. linitonly .and. ipn*spn < puny) dhs = c0
1033 3141455 : dhsn(n) = dhs ! save: constant until reset to 0
1034 :
1035 : ! not using ipn assumes that lid ice is perfectly clear
1036 : ! if (ipn <= 0.3_dbl_kind) then
1037 :
1038 : ! fraction of ice area
1039 3141455 : fpn = apndn(n) * alvln(n)
1040 : ! pond depth over fraction fpn
1041 3141455 : hpn = hpndn(n)
1042 :
1043 : ! reduce effective pond area absorbing surface heat flux
1044 : ! due to flux already having been used to melt pond ice
1045 3141455 : fpn = (c1 - ffracn(n)) * fpn
1046 :
1047 : ! taper pond area with snow on pond ice
1048 3141455 : if (dhs > puny .and. spn >= puny .and. hs1 > puny) then
1049 18602 : asnow = min(spn/hs1, c1)
1050 18602 : fpn = (c1 - asnow) * fpn
1051 : endif
1052 :
1053 : ! infiltrate snow
1054 3141455 : hp = hpn
1055 3141455 : if (hp > puny) then
1056 1499717 : hs = hsn
1057 1499717 : rp = rhofresh*hp/(rhofresh*hp + rhos*hs)
1058 1499717 : if (rp < p15) then
1059 1198804 : fpn = c0
1060 1198804 : hpn = c0
1061 : else
1062 300913 : hmx = hs*(rhofresh - rhos)/rhofresh
1063 300913 : tmp = max(c0, sign(c1, hp-hmx)) ! 1 if hp>=hmx, else 0
1064 : hp = (rhofresh*hp + rhos*hs*tmp) &
1065 300913 : / (rhofresh - rhos*(c1-tmp))
1066 300913 : hsn = hs - hp*fpn*(c1-tmp)
1067 300913 : hpn = hp * tmp
1068 300913 : fpn = fpn * tmp
1069 : endif
1070 : endif ! hp > puny
1071 :
1072 : ! Zero out fraction of thin ponds for radiation only
1073 3141455 : if (hpn < hpmin) fpn = c0
1074 3141455 : fsn = min(fsn, c1-fpn)
1075 :
1076 : ! endif ! masking by lid ice
1077 3141455 : apeffn(n) = fpn ! for history
1078 :
1079 529480 : elseif (tr_pond_topo) then
1080 : ! Lid effective if thicker than hp1
1081 457081 : if (apndn(n)*aicen(n) > puny .and. ipndn(n) < hp1) then
1082 148413 : fpn = apndn(n)
1083 : else
1084 308668 : fpn = c0
1085 : endif
1086 457081 : if (apndn(n) > puny) then
1087 184923 : hpn = hpndn(n)
1088 : else
1089 272158 : fpn = c0
1090 272158 : hpn = c0
1091 : endif
1092 :
1093 : ! Zero out fraction of thin ponds for radiation only
1094 457081 : if (hpn < hpmin) fpn = c0
1095 :
1096 : ! If ponds are present snow fraction reduced to
1097 : ! non-ponded part dEdd scheme
1098 457081 : fsn = min(fsn, c1-fpn)
1099 :
1100 457081 : apeffn(n) = fpn
1101 : else
1102 72399 : fpn = c0
1103 72399 : hpn = c0
1104 26280 : call shortwave_dEdd_set_pond(Tsfcn(n), &
1105 : fsn, fpn, &
1106 72399 : hpn)
1107 72399 : if (icepack_warnings_aborted(subname)) return
1108 :
1109 72399 : apeffn(n) = fpn ! for history
1110 72399 : fpn = c0
1111 72399 : hpn = c0
1112 : endif ! pond type
1113 :
1114 3900730 : snowfracn(n) = fsn ! for history
1115 :
1116 : call shortwave_dEdd(dEdd_algae, &
1117 : nslyr, nilyr, &
1118 : coszen, heat_capacity, &
1119 1405899 : aicen(n), vicen(n), &
1120 : hsn, fsn, &
1121 0 : rhosnwn, rsnwn, &
1122 : fpn, hpn, &
1123 0 : aeron(:,n), &
1124 : R_ice, R_pnd, &
1125 0 : kaer_tab, waer_tab, &
1126 0 : gaer_tab, &
1127 0 : kaer_bc_tab, &
1128 0 : waer_bc_tab, &
1129 0 : gaer_bc_tab, &
1130 0 : bcenh, modal_aero, &
1131 : kalg, &
1132 : swvdr, swvdf, &
1133 : swidr, swidf, &
1134 1405899 : alvdrn(n), alvdfn(n), &
1135 1405899 : alidrn(n), alidfn(n), &
1136 1405899 : fswsfcn(n), fswintn(n), &
1137 1405899 : fswthru=fswthrun(n), &
1138 0 : fswthru_vdr=l_fswthrun_vdr(n), &
1139 0 : fswthru_vdf=l_fswthrun_vdf(n), &
1140 0 : fswthru_idr=l_fswthrun_idr(n), &
1141 0 : fswthru_idf=l_fswthrun_idf(n), &
1142 0 : Sswabs=Sswabsn(:,n), &
1143 0 : Iswabs=Iswabsn(:,n), &
1144 1405899 : albice=albicen(n), &
1145 1405899 : albsno=albsnon(n), &
1146 1405899 : albpnd=albpndn(n), &
1147 0 : fswpenl=fswpenln(:,n), &
1148 0 : zbio=trcrn_bgcsw(:,n), &
1149 6712528 : l_print_point=l_print_point)
1150 :
1151 3900730 : if (icepack_warnings_aborted(subname)) return
1152 :
1153 : endif ! aicen > puny
1154 :
1155 : enddo ! ncat
1156 :
1157 5165748 : if(present(fswthrun_vdr)) fswthrun_vdr = l_fswthrun_vdr
1158 5165748 : if(present(fswthrun_vdf)) fswthrun_vdf = l_fswthrun_vdf
1159 5165748 : if(present(fswthrun_idr)) fswthrun_idr = l_fswthrun_idr
1160 5165748 : if(present(fswthrun_idf)) fswthrun_idf = l_fswthrun_idf
1161 :
1162 909228 : deallocate(l_fswthrun_vdr)
1163 909228 : deallocate(l_fswthrun_vdf)
1164 909228 : deallocate(l_fswthrun_idr)
1165 909228 : deallocate(l_fswthrun_idf)
1166 :
1167 909228 : end subroutine run_dEdd
1168 :
1169 : !=======================================================================
1170 : !
1171 : ! Compute snow/bare ice/ponded ice shortwave albedos, absorbed and transmitted
1172 : ! flux using the Delta-Eddington solar radiation method as described in:
1173 : !
1174 : ! A Delta-Eddington Multiple Scattering Parameterization for Solar Radiation
1175 : ! in the Sea Ice Component of the Community Climate System Model
1176 : ! B.P.Briegleb and B.Light NCAR/TN-472+STR February 2007
1177 : !
1178 : ! Compute shortwave albedos and fluxes for three surface types:
1179 : ! snow over ice, bare ice and ponded ice.
1180 : !
1181 : ! Albedos and fluxes are output for later use by thermodynamic routines.
1182 : ! Invokes three calls to compute_dEdd, which sets inherent optical properties
1183 : ! appropriate for the surface type. Within compute_dEdd, a call to solution_dEdd
1184 : ! evaluates the Delta-Eddington solution. The final albedos and fluxes are then
1185 : ! evaluated in compute_dEdd. Albedos and fluxes are transferred to output in
1186 : ! this routine.
1187 : !
1188 : ! NOTE regarding albedo diagnostics: This method yields zero albedo values
1189 : ! if there is no incoming solar and thus the albedo diagnostics are masked
1190 : ! out when the sun is below the horizon. To estimate albedo from the history
1191 : ! output (post-processing), compute ice albedo using
1192 : ! (1 - albedo)*swdn = swabs. -ECH
1193 : !
1194 : ! author: Bruce P. Briegleb, NCAR
1195 : ! 2013: E Hunke merged with NCAR version
1196 : !
1197 3900730 : subroutine shortwave_dEdd (dEdd_algae, &
1198 : nslyr, nilyr, &
1199 : coszen, heat_capacity,&
1200 : aice, vice, &
1201 : hs, fs, &
1202 3900730 : rhosnw, rsnw, &
1203 : fp, hp, &
1204 3900730 : aero, &
1205 : R_ice, R_pnd, &
1206 3900730 : kaer_tab, waer_tab, &
1207 3900730 : gaer_tab, &
1208 3900730 : kaer_bc_tab, &
1209 3900730 : waer_bc_tab, &
1210 3900730 : gaer_bc_tab, &
1211 3900730 : bcenh, modal_aero, &
1212 : kalg, &
1213 : swvdr, swvdf, &
1214 : swidr, swidf, &
1215 : alvdr, alvdf, &
1216 : alidr, alidf, &
1217 : fswsfc, fswint, &
1218 : fswthru, &
1219 : fswthru_vdr, &
1220 : fswthru_vdf, &
1221 : fswthru_idr, &
1222 : fswthru_idf, &
1223 3900730 : Sswabs, &
1224 3900730 : Iswabs, albice, &
1225 : albsno, albpnd, &
1226 7801460 : fswpenl, zbio, &
1227 : l_print_point)
1228 :
1229 : integer (kind=int_kind), intent(in) :: &
1230 : nilyr , & ! number of ice layers
1231 : nslyr ! number of snow layers
1232 :
1233 : logical (kind=log_kind), intent(in) :: &
1234 : heat_capacity, & ! if true, ice has nonzero heat capacity
1235 : dEdd_algae, & ! .true. use prognostic chla in dEdd
1236 : modal_aero ! .true. use modal aerosol treatment
1237 :
1238 : real (kind=dbl_kind), dimension(:,:), intent(in) :: & ! Modal aerosol treatment
1239 : kaer_bc_tab, & ! aerosol mass extinction cross section (m2/kg)
1240 : waer_bc_tab, & ! aerosol single scatter albedo (fraction)
1241 : gaer_bc_tab ! aerosol asymmetry parameter (cos(theta))
1242 :
1243 : real (kind=dbl_kind), dimension(:,:,:), intent(in) :: & ! Modal aerosol treatment
1244 : bcenh ! BC absorption enhancement factor
1245 :
1246 : real (kind=dbl_kind), dimension(:,:), intent(in) :: &
1247 : kaer_tab, & ! aerosol mass extinction cross section (m2/kg)
1248 : waer_tab, & ! aerosol single scatter albedo (fraction)
1249 : gaer_tab ! aerosol asymmetry parameter (cos(theta))
1250 :
1251 : real (kind=dbl_kind), intent(in) :: &
1252 : kalg , & ! algae absorption coefficient
1253 : R_ice , & ! sea ice tuning parameter; +1 > 1sig increase in albedo
1254 : R_pnd , & ! ponded ice tuning parameter; +1 > 1sig increase in albedo
1255 : aice , & ! concentration of ice
1256 : vice , & ! volume of ice
1257 : hs , & ! snow depth
1258 : fs ! horizontal coverage of snow
1259 :
1260 : real (kind=dbl_kind), dimension (:), intent(in) :: &
1261 : rhosnw , & ! density in snow layer (kg/m3)
1262 : rsnw , & ! grain radius in snow layer (m)
1263 : aero , & ! aerosol tracers
1264 : zbio ! shortwave tracers (zaero+chla)
1265 :
1266 : real (kind=dbl_kind), intent(in) :: &
1267 : fp , & ! pond fractional coverage (0 to 1)
1268 : hp , & ! pond depth (m)
1269 : swvdr , & ! sw down, visible, direct (W/m^2)
1270 : swvdf , & ! sw down, visible, diffuse (W/m^2)
1271 : swidr , & ! sw down, near IR, direct (W/m^2)
1272 : swidf ! sw down, near IR, diffuse (W/m^2)
1273 :
1274 : real (kind=dbl_kind), intent(inout) :: &
1275 : coszen , & ! cosine of solar zenith angle
1276 : alvdr , & ! visible, direct, albedo (fraction)
1277 : alvdf , & ! visible, diffuse, albedo (fraction)
1278 : alidr , & ! near-ir, direct, albedo (fraction)
1279 : alidf , & ! near-ir, diffuse, albedo (fraction)
1280 : fswsfc , & ! SW absorbed at snow/bare ice/pondedi ice surface (W m-2)
1281 : fswint , & ! SW interior absorption (below surface, above ocean,W m-2)
1282 : fswthru ! SW through snow/bare ice/ponded ice into ocean (W m-2)
1283 :
1284 : real (kind=dbl_kind), intent(out) :: &
1285 : fswthru_vdr , & ! vis dir SW through snow/bare ice/ponded ice into ocean (W m-2)
1286 : fswthru_vdf , & ! vis dif SW through snow/bare ice/ponded ice into ocean (W m-2)
1287 : fswthru_idr , & ! nir dir SW through snow/bare ice/ponded ice into ocean (W m-2)
1288 : fswthru_idf ! nir dif SW through snow/bare ice/ponded ice into ocean (W m-2)
1289 :
1290 : real (kind=dbl_kind), dimension (:), intent(inout) :: &
1291 : fswpenl , & ! visible SW entering ice layers (W m-2)
1292 : Sswabs , & ! SW absorbed in snow layer (W m-2)
1293 : Iswabs ! SW absorbed in ice layer (W m-2)
1294 :
1295 : real (kind=dbl_kind), intent(out) :: &
1296 : albice , & ! bare ice albedo, for history
1297 : albsno , & ! snow albedo, for history
1298 : albpnd ! pond albedo, for history
1299 :
1300 : logical (kind=log_kind) , intent(in) :: &
1301 : l_print_point
1302 :
1303 : ! local variables
1304 :
1305 : real (kind=dbl_kind) :: &
1306 1405899 : netsw , & ! net shortwave
1307 1405899 : fnidr , & ! fraction of direct to total down surface flux in nir
1308 1405899 : hstmp , & ! snow thickness (set to 0 for bare ice case)
1309 1405899 : hi , & ! ice thickness (all sea ice layers, m)
1310 1405899 : fi ! snow/bare ice fractional coverage (0 to 1)
1311 :
1312 : real (kind=dbl_kind), dimension (4*n_aero) :: &
1313 10704761 : aero_mp ! aerosol mass path in kg/m2
1314 :
1315 : integer (kind=int_kind) :: &
1316 : srftyp ! surface type over ice: (0=air, 1=snow, 2=pond)
1317 :
1318 : integer (kind=int_kind) :: &
1319 : k , & ! level index
1320 : na , & ! aerosol index
1321 : klev , & ! number of radiation layers - 1
1322 : klevp ! number of radiation interfaces - 1
1323 : ! (0 layer is included also)
1324 :
1325 : real (kind=dbl_kind) :: &
1326 1405899 : vsno ! volume of snow
1327 :
1328 : real (kind=dbl_kind) :: &
1329 1405899 : swdn , & ! swvdr(i,j)+swvdf(i,j)+swidr(i,j)+swidf(i,j)
1330 1405899 : swab , & ! fswsfc(i,j)+fswint(i,j)+fswthru(i,j)
1331 1405899 : swalb ! (1.-swab/(swdn+.0001))
1332 :
1333 : ! for history
1334 : real (kind=dbl_kind) :: &
1335 1405899 : avdrl , & ! visible, direct, albedo (fraction)
1336 1405899 : avdfl , & ! visible, diffuse, albedo (fraction)
1337 1405899 : aidrl , & ! near-ir, direct, albedo (fraction)
1338 1405899 : aidfl ! near-ir, diffuse, albedo (fraction)
1339 :
1340 : character(len=*),parameter :: subname='(shortwave_dEdd)'
1341 :
1342 : !-----------------------------------------------------------------------
1343 :
1344 3900730 : klev = nslyr + nilyr + 1 ! number of radiation layers - 1
1345 3900730 : klevp = klev + 1 ! number of radiation interfaces - 1
1346 : ! (0 layer is included also)
1347 :
1348 : ! zero storage albedos and fluxes for accumulation over surface types:
1349 3900730 : hstmp = c0
1350 3900730 : hi = c0
1351 3900730 : fi = c0
1352 3900730 : alvdr = c0
1353 3900730 : alvdf = c0
1354 3900730 : alidr = c0
1355 3900730 : alidf = c0
1356 3900730 : avdrl = c0
1357 3900730 : avdfl = c0
1358 3900730 : aidrl = c0
1359 3900730 : aidfl = c0
1360 3900730 : fswsfc = c0
1361 3900730 : fswint = c0
1362 3900730 : fswthru = c0
1363 3900730 : fswthru_vdr = c0
1364 3900730 : fswthru_vdf = c0
1365 3900730 : fswthru_idr = c0
1366 3900730 : fswthru_idf = c0
1367 : ! compute fraction of nir down direct to total over all points:
1368 3900730 : fnidr = c0
1369 3900730 : if( swidr + swidf > puny ) then
1370 3018431 : fnidr = swidr/(swidr+swidf)
1371 : endif
1372 3900730 : albice = c0
1373 3900730 : albsno = c0
1374 3900730 : albpnd = c0
1375 34672176 : fswpenl(:) = c0
1376 8710492 : Sswabs(:) = c0
1377 30771446 : Iswabs(:) = c0
1378 :
1379 : ! compute aerosol mass path
1380 :
1381 18671934 : aero_mp(:) = c0
1382 3900730 : if( tr_aero ) then
1383 : ! check 4 layers for each aerosol, a snow SSL, snow below SSL,
1384 : ! sea ice SSL, and sea ice below SSL, in that order.
1385 229795 : if (size(aero) < 4*n_aero) then
1386 0 : call icepack_warnings_add(subname//' ERROR: size(aero) too small')
1387 0 : call icepack_warnings_setabort(.true.,__FILE__,__LINE__)
1388 0 : return
1389 : endif
1390 459590 : do na = 1, 4*n_aero, 4
1391 229795 : vsno = hs * aice
1392 229795 : netsw = swvdr + swidr + swvdf + swidf
1393 459590 : if (netsw > puny) then ! sun above horizon
1394 181316 : aero_mp(na ) = aero(na )*vsno
1395 181316 : aero_mp(na+1) = aero(na+1)*vsno
1396 181316 : aero_mp(na+2) = aero(na+2)*vice
1397 181316 : aero_mp(na+3) = aero(na+3)*vice
1398 : endif ! aice > 0 and netsw > 0
1399 : enddo ! na
1400 : endif ! if aerosols
1401 :
1402 : ! compute shortwave radiation accounting for snow/ice (both snow over
1403 : ! ice and bare ice) and ponded ice (if any):
1404 :
1405 : ! sea ice points with sun above horizon
1406 3900730 : netsw = swvdr + swidr + swvdf + swidf
1407 3900730 : if (netsw > puny) then ! sun above horizon
1408 3018431 : coszen = max(puny,coszen)
1409 : ! evaluate sea ice thickness and fraction
1410 3018431 : hi = vice / aice
1411 3018431 : fi = c1 - fs - fp
1412 : ! bare sea ice points
1413 3018431 : if(fi > c0) then
1414 : ! calculate bare sea ice
1415 :
1416 856792 : srftyp = 0
1417 : call compute_dEdd(nilyr, nslyr, klev, klevp, &
1418 0 : zbio, dEdd_algae, &
1419 : heat_capacity, fnidr, coszen, &
1420 : R_ice, R_pnd, &
1421 0 : kaer_tab, waer_tab, gaer_tab, &
1422 0 : kaer_bc_tab, waer_bc_tab, gaer_bc_tab, &
1423 0 : bcenh, modal_aero, kalg, &
1424 : swvdr, swvdf, swidr, swidf, srftyp, &
1425 0 : hstmp, rhosnw, rsnw, hi, hp, &
1426 0 : fi, aero_mp, avdrl, avdfl, &
1427 : aidrl, aidfl, &
1428 : fswsfc, fswint, &
1429 : fswthru, &
1430 : fswthru_vdr, &
1431 : fswthru_vdf, &
1432 : fswthru_idr, &
1433 : fswthru_idf, &
1434 0 : Sswabs, &
1435 856792 : Iswabs, fswpenl)
1436 856792 : if (icepack_warnings_aborted(subname)) return
1437 :
1438 856792 : alvdr = alvdr + avdrl *fi
1439 856792 : alvdf = alvdf + avdfl *fi
1440 856792 : alidr = alidr + aidrl *fi
1441 856792 : alidf = alidf + aidfl *fi
1442 : ! for history
1443 : albice = albice &
1444 : + awtvdr*avdrl + awtidr*aidrl &
1445 856792 : + awtvdf*avdfl + awtidf*aidfl
1446 : endif
1447 : endif
1448 :
1449 : ! sea ice points with sun above horizon
1450 3900730 : netsw = swvdr + swidr + swvdf + swidf
1451 3900730 : if (netsw > puny) then ! sun above horizon
1452 3018431 : coszen = max(puny,coszen)
1453 : ! snow-covered sea ice points
1454 3018431 : if(fs > c0) then
1455 : ! calculate snow covered sea ice
1456 :
1457 2174093 : srftyp = 1
1458 : call compute_dEdd(nilyr, nslyr, klev, klevp, &
1459 0 : zbio, dEdd_algae, &
1460 : heat_capacity, fnidr, coszen, &
1461 : R_ice, R_pnd, &
1462 0 : kaer_tab, waer_tab, gaer_tab, &
1463 0 : kaer_bc_tab, waer_bc_tab, gaer_bc_tab, &
1464 0 : bcenh, modal_aero, kalg, &
1465 : swvdr, swvdf, swidr, swidf, srftyp, &
1466 0 : hs, rhosnw, rsnw, hi, hp, &
1467 0 : fs, aero_mp, avdrl, avdfl, &
1468 : aidrl, aidfl, &
1469 : fswsfc, fswint, &
1470 : fswthru, &
1471 : fswthru_vdr, &
1472 : fswthru_vdf, &
1473 : fswthru_idr, &
1474 : fswthru_idf, &
1475 0 : Sswabs, &
1476 2174093 : Iswabs, fswpenl)
1477 2174093 : if (icepack_warnings_aborted(subname)) return
1478 :
1479 2174093 : alvdr = alvdr + avdrl *fs
1480 2174093 : alvdf = alvdf + avdfl *fs
1481 2174093 : alidr = alidr + aidrl *fs
1482 2174093 : alidf = alidf + aidfl *fs
1483 : ! for history
1484 : albsno = albsno &
1485 : + awtvdr*avdrl + awtidr*aidrl &
1486 2174093 : + awtvdf*avdfl + awtidf*aidfl
1487 : endif
1488 : endif
1489 :
1490 3900730 : hi = c0
1491 :
1492 : ! sea ice points with sun above horizon
1493 3900730 : netsw = swvdr + swidr + swvdf + swidf
1494 3900730 : if (netsw > puny) then ! sun above horizon
1495 3018431 : coszen = max(puny,coszen)
1496 3018431 : hi = vice / aice
1497 : ! if nonzero pond fraction and sufficient pond depth
1498 : ! if( fp > puny .and. hp > hpmin ) then
1499 3018431 : if (fp > puny) then
1500 :
1501 : ! calculate ponded ice
1502 :
1503 306827 : srftyp = 2
1504 : call compute_dEdd(nilyr, nslyr, klev, klevp, &
1505 0 : zbio, dEdd_algae, &
1506 : heat_capacity, fnidr, coszen, &
1507 : R_ice, R_pnd, &
1508 0 : kaer_tab, waer_tab, gaer_tab, &
1509 0 : kaer_bc_tab, waer_bc_tab, gaer_bc_tab, &
1510 0 : bcenh, modal_aero, kalg, &
1511 : swvdr, swvdf, swidr, swidf, srftyp, &
1512 0 : hs, rhosnw, rsnw, hi, hp, &
1513 0 : fp, aero_mp, avdrl, avdfl, &
1514 : aidrl, aidfl, &
1515 : fswsfc, fswint, &
1516 : fswthru, &
1517 : fswthru_vdr, &
1518 : fswthru_vdf, &
1519 : fswthru_idr, &
1520 : fswthru_idf, &
1521 0 : Sswabs, &
1522 306827 : Iswabs, fswpenl)
1523 306827 : if (icepack_warnings_aborted(subname)) return
1524 :
1525 306827 : alvdr = alvdr + avdrl *fp
1526 306827 : alvdf = alvdf + avdfl *fp
1527 306827 : alidr = alidr + aidrl *fp
1528 306827 : alidf = alidf + aidfl *fp
1529 : ! for history
1530 : albpnd = albpnd &
1531 : + awtvdr*avdrl + awtidr*aidrl &
1532 306827 : + awtvdf*avdfl + awtidf*aidfl
1533 : endif
1534 : endif
1535 :
1536 : ! if no incoming shortwave, set albedos to 1
1537 3900730 : netsw = swvdr + swidr + swvdf + swidf
1538 3900730 : if (netsw <= puny) then ! sun above horizon
1539 882299 : alvdr = c1
1540 882299 : alvdf = c1
1541 882299 : alidr = c1
1542 882299 : alidf = c1
1543 : endif
1544 :
1545 3900730 : if (l_print_point .and. netsw > puny) then
1546 :
1547 0 : write(warnstr,*) subname, ' printing point'
1548 0 : call icepack_warnings_add(warnstr)
1549 0 : write(warnstr,*) subname, ' coszen = ', &
1550 0 : coszen
1551 0 : call icepack_warnings_add(warnstr)
1552 0 : write(warnstr,*) subname, ' swvdr swvdf = ', &
1553 0 : swvdr,swvdf
1554 0 : call icepack_warnings_add(warnstr)
1555 0 : write(warnstr,*) subname, ' swidr swidf = ', &
1556 0 : swidr,swidf
1557 0 : call icepack_warnings_add(warnstr)
1558 0 : write(warnstr,*) subname, ' aice = ', &
1559 0 : aice
1560 0 : call icepack_warnings_add(warnstr)
1561 0 : write(warnstr,*) subname, ' hs = ', &
1562 0 : hs
1563 0 : call icepack_warnings_add(warnstr)
1564 0 : write(warnstr,*) subname, ' hp = ', &
1565 0 : hp
1566 0 : call icepack_warnings_add(warnstr)
1567 0 : write(warnstr,*) subname, ' fs = ', &
1568 0 : fs
1569 0 : call icepack_warnings_add(warnstr)
1570 0 : write(warnstr,*) subname, ' fi = ', &
1571 0 : fi
1572 0 : call icepack_warnings_add(warnstr)
1573 0 : write(warnstr,*) subname, ' fp = ', &
1574 0 : fp
1575 0 : call icepack_warnings_add(warnstr)
1576 0 : write(warnstr,*) subname, ' hi = ', &
1577 0 : hi
1578 0 : call icepack_warnings_add(warnstr)
1579 0 : write(warnstr,*) subname, ' alvdr alvdf = ', &
1580 0 : alvdr,alvdf
1581 0 : call icepack_warnings_add(warnstr)
1582 0 : write(warnstr,*) subname, ' alidr alidf = ', &
1583 0 : alidr,alidf
1584 0 : call icepack_warnings_add(warnstr)
1585 0 : write(warnstr,*) subname, ' fswsfc fswint fswthru = ', &
1586 0 : fswsfc,fswint,fswthru
1587 0 : call icepack_warnings_add(warnstr)
1588 0 : swdn = swvdr+swvdf+swidr+swidf
1589 0 : swab = fswsfc+fswint+fswthru
1590 0 : swalb = (1.-swab/(swdn+.0001))
1591 0 : write(warnstr,*) subname, ' swdn swab swalb = ',swdn,swab,swalb
1592 0 : do k = 1, nslyr
1593 0 : write(warnstr,*) subname, ' snow layer k = ', k, &
1594 0 : ' rhosnw = ', &
1595 0 : rhosnw(k), &
1596 0 : ' rsnw = ', &
1597 0 : rsnw(k)
1598 0 : call icepack_warnings_add(warnstr)
1599 : enddo
1600 0 : do k = 1, nslyr
1601 0 : write(warnstr,*) subname, ' snow layer k = ', k, &
1602 0 : ' Sswabs(k) = ', Sswabs(k)
1603 0 : call icepack_warnings_add(warnstr)
1604 : enddo
1605 0 : do k = 1, nilyr
1606 0 : write(warnstr,*) subname, ' sea ice layer k = ', k, &
1607 0 : ' Iswabs(k) = ', Iswabs(k)
1608 0 : call icepack_warnings_add(warnstr)
1609 : enddo
1610 :
1611 : endif ! l_print_point .and. coszen > .01
1612 :
1613 : end subroutine shortwave_dEdd
1614 :
1615 : !=======================================================================
1616 : !
1617 : ! Evaluate snow/ice/ponded ice inherent optical properties (IOPs), and
1618 : ! then calculate the multiple scattering solution by calling solution_dEdd.
1619 : !
1620 : ! author: Bruce P. Briegleb, NCAR
1621 : ! 2013: E Hunke merged with NCAR version
1622 :
1623 3337712 : subroutine compute_dEdd (nilyr, nslyr, klev, klevp, &
1624 3337712 : zbio, dEdd_algae, &
1625 : heat_capacity, fnidr, coszen, &
1626 : R_ice, R_pnd, &
1627 3337712 : kaer_tab, waer_tab, gaer_tab, &
1628 3337712 : kaer_bc_tab, waer_bc_tab, gaer_bc_tab, &
1629 3337712 : bcenh, modal_aero, kalg, &
1630 : swvdr, swvdf, swidr, swidf, srftyp, &
1631 6675424 : hs, rhosnw, rsnw, hi, hp, &
1632 3337712 : fi, aero_mp, alvdr, alvdf, &
1633 : alidr, alidf, &
1634 : fswsfc, fswint, &
1635 : fswthru, &
1636 : fswthru_vdr, &
1637 : fswthru_vdf, &
1638 : fswthru_idr, &
1639 : fswthru_idf, &
1640 3337712 : Sswabs, &
1641 3337712 : Iswabs, fswpenl)
1642 :
1643 : integer (kind=int_kind), intent(in) :: &
1644 : nilyr , & ! number of ice layers
1645 : nslyr , & ! number of snow layers
1646 : klev , & ! number of radiation layers - 1
1647 : klevp ! number of radiation interfaces - 1
1648 : ! (0 layer is included also)
1649 :
1650 : logical (kind=log_kind), intent(in) :: &
1651 : heat_capacity,& ! if true, ice has nonzero heat capacity
1652 : dEdd_algae, & ! .true. use prognostic chla in dEdd
1653 : modal_aero ! .true. use modal aerosol treatment
1654 :
1655 : real (kind=dbl_kind), dimension(:,:), intent(in) :: & ! Modal aerosol treatment
1656 : kaer_bc_tab, & ! aerosol mass extinction cross section (m2/kg)
1657 : waer_bc_tab, & ! aerosol single scatter albedo (fraction)
1658 : gaer_bc_tab ! aerosol asymmetry parameter (cos(theta))
1659 :
1660 : real (kind=dbl_kind), dimension(:,:,:), intent(in) :: & ! Modal aerosol treatment
1661 : bcenh ! BC absorption enhancement factor
1662 :
1663 : ! dEdd tuning parameters, set in namelist
1664 : real (kind=dbl_kind), intent(in) :: &
1665 : R_ice , & ! sea ice tuning parameter; +1 > 1sig increase in albedo
1666 : R_pnd ! ponded ice tuning parameter; +1 > 1sig increase in albedo
1667 :
1668 : real (kind=dbl_kind), dimension(:,:), intent(in) :: &
1669 : kaer_tab, & ! aerosol mass extinction cross section (m2/kg)
1670 : waer_tab, & ! aerosol single scatter albedo (fraction)
1671 : gaer_tab ! aerosol asymmetry parameter (cos(theta))
1672 :
1673 : real (kind=dbl_kind), intent(in) :: &
1674 : kalg , & ! algae absorption coefficient
1675 : fnidr , & ! fraction of direct to total down flux in nir
1676 : coszen , & ! cosine solar zenith angle
1677 : swvdr , & ! shortwave down at surface, visible, direct (W/m^2)
1678 : swvdf , & ! shortwave down at surface, visible, diffuse (W/m^2)
1679 : swidr , & ! shortwave down at surface, near IR, direct (W/m^2)
1680 : swidf ! shortwave down at surface, near IR, diffuse (W/m^2)
1681 :
1682 : integer (kind=int_kind), intent(in) :: &
1683 : srftyp ! surface type over ice: (0=air, 1=snow, 2=pond)
1684 :
1685 : real (kind=dbl_kind), intent(in) :: &
1686 : hs ! snow thickness (m)
1687 :
1688 : real (kind=dbl_kind), dimension (:), intent(in) :: &
1689 : rhosnw , & ! snow density in snow layer (kg/m3)
1690 : rsnw , & ! snow grain radius in snow layer (m)
1691 : zbio , & ! zaerosol + chla shortwave tracers kg/m^3
1692 : aero_mp ! aerosol mass path in kg/m2
1693 :
1694 : real (kind=dbl_kind), intent(in) :: &
1695 : hi , & ! ice thickness (m)
1696 : hp , & ! pond depth (m)
1697 : fi ! snow/bare ice fractional coverage (0 to 1)
1698 :
1699 : real (kind=dbl_kind), intent(inout) :: &
1700 : alvdr , & ! visible, direct, albedo (fraction)
1701 : alvdf , & ! visible, diffuse, albedo (fraction)
1702 : alidr , & ! near-ir, direct, albedo (fraction)
1703 : alidf , & ! near-ir, diffuse, albedo (fraction)
1704 : fswsfc , & ! SW absorbed at snow/bare ice/pondedi ice surface (W m-2)
1705 : fswint , & ! SW interior absorption (below surface, above ocean,W m-2)
1706 : fswthru ! SW through snow/bare ice/ponded ice into ocean (W m-2)
1707 :
1708 : real (kind=dbl_kind), intent(inout) :: &
1709 : fswthru_vdr , & ! vis dir SW through snow/bare ice/ponded ice into ocean (W m-2)
1710 : fswthru_vdf , & ! vis dif SW through snow/bare ice/ponded ice into ocean (W m-2)
1711 : fswthru_idr , & ! nir dir SW through snow/bare ice/ponded ice into ocean (W m-2)
1712 : fswthru_idf ! nir dif SW through snow/bare ice/ponded ice into ocean (W m-2)
1713 :
1714 : real (kind=dbl_kind), dimension (:), intent(inout) :: &
1715 : fswpenl , & ! visible SW entering ice layers (W m-2)
1716 : Sswabs , & ! SW absorbed in snow layer (W m-2)
1717 : Iswabs ! SW absorbed in ice layer (W m-2)
1718 :
1719 : !-----------------------------------------------------------------------
1720 : !
1721 : ! Set up optical property profiles, based on snow, sea ice and ponded
1722 : ! ice IOPs from:
1723 : !
1724 : ! Briegleb, B. P., and B. Light (2007): A Delta-Eddington Multiple
1725 : ! Scattering Parameterization for Solar Radiation in the Sea Ice
1726 : ! Component of the Community Climate System Model, NCAR Technical
1727 : ! Note NCAR/TN-472+STR February 2007
1728 : !
1729 : ! Computes column Delta-Eddington radiation solution for specific
1730 : ! surface type: either snow over sea ice, bare sea ice, or ponded sea ice.
1731 : !
1732 : ! Divides solar spectrum into 3 intervals: 0.2-0.7, 0.7-1.19, and
1733 : ! 1.19-5.0 micro-meters. The latter two are added (using an assumed
1734 : ! partition of incident shortwave in the 0.7-5.0 micro-meter band between
1735 : ! the 0.7-1.19 and 1.19-5.0 micro-meter band) to give the final output
1736 : ! of 0.2-0.7 visible and 0.7-5.0 near-infrared albedos and fluxes.
1737 : !
1738 : ! Specifies vertical layer optical properties based on input snow depth,
1739 : ! density and grain radius, along with ice and pond depths, then computes
1740 : ! layer by layer Delta-Eddington reflectivity, transmissivity and combines
1741 : ! layers (done by calling routine solution_dEdd). Finally, surface albedos
1742 : ! and internal fluxes/flux divergences are evaluated.
1743 : !
1744 : ! Description of the level and layer index conventions. This is
1745 : ! for the standard case of one snow layer and four sea ice layers.
1746 : !
1747 : ! Please read the following; otherwise, there is 99.9% chance you
1748 : ! will be confused about indices at some point in time........ :)
1749 : !
1750 : ! CICE4.0 snow treatment has one snow layer above the sea ice. This
1751 : ! snow layer has finite heat capacity, so that surface absorption must
1752 : ! be distinguished from internal. The Delta-Eddington solar radiation
1753 : ! thus adds extra surface scattering layers to both snow and sea ice.
1754 : ! Note that in the following, we assume a fixed vertical layer structure
1755 : ! for the radiation calculation. In other words, we always have the
1756 : ! structure shown below for one snow and four sea ice layers, but for
1757 : ! ponded ice the pond fills "snow" layer 1 over the sea ice, and for
1758 : ! bare sea ice the top layers over sea ice are treated as transparent air.
1759 : !
1760 : ! SSL = surface scattering layer for either snow or sea ice
1761 : ! DL = drained layer for sea ice immediately under sea ice SSL
1762 : ! INT = interior layers for sea ice below the drained layer.
1763 : !
1764 : ! Notice that the radiation level starts with 0 at the top. Thus,
1765 : ! the total number radiation layers is klev+1, where klev is the
1766 : ! sum of nslyr, the number of CCSM snow layers, and nilyr, the
1767 : ! number of CCSM sea ice layers, plus the sea ice SSL:
1768 : ! klev = 1 + nslyr + nilyr
1769 : !
1770 : ! For the standard case illustrated below, nslyr=1, nilyr=4,
1771 : ! and klev=6, with the number of layer interfaces klevp=klev+1.
1772 : ! Layer interfaces are the surfaces on which reflectivities,
1773 : ! transmissivities and fluxes are evaluated.
1774 : !
1775 : ! CCSM3 Sea Ice Model Delta-Eddington Solar Radiation
1776 : ! Layers and Interfaces
1777 : ! Layer Index Interface Index
1778 : ! --------------------- --------------------- 0
1779 : ! 0 \\\ snow SSL \\\
1780 : ! snow layer 1 --------------------- 1
1781 : ! 1 rest of snow layer
1782 : ! +++++++++++++++++++++ +++++++++++++++++++++ 2
1783 : ! 2 \\\ sea ice SSL \\\
1784 : ! sea ice layer 1 --------------------- 3
1785 : ! 3 sea ice DL
1786 : ! --------------------- --------------------- 4
1787 : !
1788 : ! sea ice layer 2 4 sea ice INT
1789 : !
1790 : ! --------------------- --------------------- 5
1791 : !
1792 : ! sea ice layer 3 5 sea ice INT
1793 : !
1794 : ! --------------------- --------------------- 6
1795 : !
1796 : ! sea ice layer 4 6 sea ice INT
1797 : !
1798 : ! --------------------- --------------------- 7
1799 : !
1800 : ! When snow lies over sea ice, the radiation absorbed in the
1801 : ! snow SSL is used for surface heating, and that in the rest
1802 : ! of the snow layer for its internal heating. For sea ice in
1803 : ! this case, all of the radiant heat absorbed in both the
1804 : ! sea ice SSL and the DL are used for sea ice layer 1 heating.
1805 : !
1806 : ! When pond lies over sea ice, and for bare sea ice, all of the
1807 : ! radiant heat absorbed within and above the sea ice SSL is used
1808 : ! for surface heating, and that absorbed in the sea ice DL is
1809 : ! used for sea ice layer 1 heating.
1810 : !
1811 : ! Basically, vertical profiles of the layer extinction optical depth (tau),
1812 : ! single scattering albedo (w0) and asymmetry parameter (g) are required over
1813 : ! the klev+1 layers, where klev+1 = 2 + nslyr + nilyr. All of the surface type
1814 : ! information and snow/ice iop properties are evaulated in this routine, so
1815 : ! the tau,w0,g profiles can be passed to solution_dEdd for multiple scattering
1816 : ! evaluation. Snow, bare ice and ponded ice iops are contained in data arrays
1817 : ! in this routine.
1818 : !
1819 : !-----------------------------------------------------------------------
1820 :
1821 : ! local variables
1822 :
1823 : integer (kind=int_kind) :: &
1824 : k , & ! level index
1825 : ns , & ! spectral index
1826 : nr , & ! index for grain radius tables
1827 : ki , & ! index for internal absorption
1828 : km , & ! k starting index for snow, sea ice internal absorption
1829 : kp , & ! k+1 or k+2 index for snow, sea ice internal absorption
1830 : ksrf , & ! level index for surface absorption
1831 : ksnow , & ! level index for snow density and grain size
1832 : kii ! level starting index for sea ice (nslyr+1)
1833 :
1834 : integer (kind=int_kind), parameter :: &
1835 : nmbrad = 32 ! number of snow grain radii in tables
1836 :
1837 : real (kind=dbl_kind) :: &
1838 1261575 : avdr , & ! visible albedo, direct (fraction)
1839 1261575 : avdf , & ! visible albedo, diffuse (fraction)
1840 1261575 : aidr , & ! near-ir albedo, direct (fraction)
1841 1261575 : aidf ! near-ir albedo, diffuse (fraction)
1842 :
1843 : real (kind=dbl_kind) :: &
1844 1261575 : fsfc , & ! shortwave absorbed at snow/bare ice/ponded ice surface (W m-2)
1845 1261575 : fint , & ! shortwave absorbed in interior (W m-2)
1846 1261575 : fthru , & ! shortwave through snow/bare ice/ponded ice to ocean (W/m^2)
1847 1261575 : fthruvdr, & ! vis dir shortwave through snow/bare ice/ponded ice to ocean (W/m^2)
1848 1261575 : fthruvdf, & ! vis dif shortwave through snow/bare ice/ponded ice to ocean (W/m^2)
1849 1261575 : fthruidr, & ! nir dir shortwave through snow/bare ice/ponded ice to ocean (W/m^2)
1850 1261575 : fthruidf ! nir dif shortwave through snow/bare ice/ponded ice to ocean (W/m^2)
1851 :
1852 : real (kind=dbl_kind), dimension(nslyr) :: &
1853 7108496 : Sabs ! shortwave absorbed in snow layer (W m-2)
1854 :
1855 : real (kind=dbl_kind), dimension(nilyr) :: &
1856 14244874 : Iabs ! shortwave absorbed in ice layer (W m-2)
1857 :
1858 : real (kind=dbl_kind), dimension(nilyr+1) :: &
1859 15506449 : fthrul ! shortwave through to ice layers (W m-2)
1860 :
1861 : real (kind=dbl_kind), dimension (nspint) :: &
1862 5046300 : wghtns ! spectral weights
1863 :
1864 : real (kind=dbl_kind), parameter :: &
1865 : cp67 = 0.67_dbl_kind , & ! nir band weight parameter
1866 : cp78 = 0.78_dbl_kind , & ! nir band weight parameter
1867 : cp01 = 0.01_dbl_kind ! for ocean visible albedo
1868 :
1869 : real (kind=dbl_kind), dimension (0:klev) :: &
1870 18462671 : tau , & ! layer extinction optical depth
1871 18462671 : w0 , & ! layer single scattering albedo
1872 18462671 : g ! layer asymmetry parameter
1873 :
1874 : ! following arrays are defined at model interfaces; 0 is the top of the
1875 : ! layer above the sea ice; klevp is the sea ice/ocean interface.
1876 : real (kind=dbl_kind), dimension (0:klevp) :: &
1877 19724246 : trndir , & ! solar beam down transmission from top
1878 19724246 : trntdr , & ! total transmission to direct beam for layers above
1879 19724246 : trndif , & ! diffuse transmission to diffuse beam for layers above
1880 19724246 : rupdir , & ! reflectivity to direct radiation for layers below
1881 19724246 : rupdif , & ! reflectivity to diffuse radiation for layers below
1882 19724246 : rdndif ! reflectivity to diffuse radiation for layers above
1883 :
1884 : real (kind=dbl_kind), dimension (0:klevp) :: &
1885 19724246 : dfdir , & ! down-up flux at interface due to direct beam at top surface
1886 22247396 : dfdif ! down-up flux at interface due to diffuse beam at top surface
1887 :
1888 : real (kind=dbl_kind) :: &
1889 1261575 : refk , & ! interface k multiple scattering term
1890 1261575 : delr , & ! snow grain radius interpolation parameter
1891 : ! inherent optical properties (iop) for snow
1892 1261575 : Qs , & ! Snow extinction efficiency
1893 1261575 : ks , & ! Snow extinction coefficient (/m)
1894 1261575 : ws , & ! Snow single scattering albedo
1895 1261575 : gs ! Snow asymmetry parameter
1896 :
1897 : real (kind=dbl_kind), dimension(nslyr) :: &
1898 7108496 : frsnw ! snow grain radius in snow layer * adjustment factor (m)
1899 :
1900 : ! actual used ice and ponded ice IOPs, allowing for tuning
1901 : ! modifications of the above "_mn" value
1902 : real (kind=dbl_kind), dimension (nspint) :: &
1903 5046300 : ki_ssl , & ! Surface-scattering-layer ice extinction coefficient (/m)
1904 5046300 : wi_ssl , & ! Surface-scattering-layer ice single scattering albedo
1905 5046300 : gi_ssl , & ! Surface-scattering-layer ice asymmetry parameter
1906 5046300 : ki_dl , & ! Drained-layer ice extinction coefficient (/m)
1907 5046300 : wi_dl , & ! Drained-layer ice single scattering albedo
1908 5046300 : gi_dl , & ! Drained-layer ice asymmetry parameter
1909 5046300 : ki_int , & ! Interior-layer ice extinction coefficient (/m)
1910 5046300 : wi_int , & ! Interior-layer ice single scattering albedo
1911 5046300 : gi_int , & ! Interior-layer ice asymmetry parameter
1912 5046300 : ki_p_ssl , & ! Ice under pond srf scat layer extinction coefficient (/m)
1913 5046300 : wi_p_ssl , & ! Ice under pond srf scat layer single scattering albedo
1914 5046300 : gi_p_ssl , & ! Ice under pond srf scat layer asymmetry parameter
1915 5046300 : ki_p_int , & ! Ice under pond extinction coefficient (/m)
1916 5046300 : wi_p_int , & ! Ice under pond single scattering albedo
1917 5046300 : gi_p_int ! Ice under pond asymmetry parameter
1918 :
1919 : real (kind=dbl_kind), dimension(0:klev) :: &
1920 18462671 : dzk ! layer thickness
1921 :
1922 : real (kind=dbl_kind) :: &
1923 1261575 : dz , & ! snow, sea ice or pond water layer thickness
1924 1261575 : dz_ssl , & ! snow or sea ice surface scattering layer thickness
1925 1261575 : fs ! scaling factor to reduce (nilyr<4) or increase (nilyr>4) DL
1926 : ! extinction coefficient to maintain DL optical depth constant
1927 : ! with changing number of sea ice layers, to approximately
1928 : ! conserve computed albedo for constant physical depth of sea
1929 : ! ice when the number of sea ice layers vary
1930 : real (kind=dbl_kind) :: &
1931 1261575 : sig , & ! scattering coefficient for tuning
1932 1261575 : kabs , & ! absorption coefficient for tuning
1933 1261575 : sigp ! modified scattering coefficient for tuning
1934 :
1935 : real (kind=dbl_kind), dimension(nspint, 0:klev) :: &
1936 57609137 : kabs_chl , & ! absorption coefficient for chlorophyll (/m)
1937 57609137 : tzaer , & ! total aerosol extinction optical depth
1938 57609137 : wzaer , & ! total aerosol single scatter albedo
1939 57609137 : gzaer ! total aerosol asymmetry parameter
1940 :
1941 : real (kind=dbl_kind) :: &
1942 1261575 : albodr , & ! spectral ocean albedo to direct rad
1943 1261575 : albodf ! spectral ocean albedo to diffuse rad
1944 :
1945 : ! for melt pond transition to bare sea ice for small pond depths
1946 : real (kind=dbl_kind) :: &
1947 1261575 : sig_i , & ! ice scattering coefficient (/m)
1948 1261575 : sig_p , & ! pond scattering coefficient (/m)
1949 1261575 : kext ! weighted extinction coefficient (/m)
1950 :
1951 : ! aerosol optical properties from Mark Flanner, 26 June 2008
1952 : ! order assumed: hydrophobic black carbon, hydrophilic black carbon,
1953 : ! four dust aerosols by particle size range:
1954 : ! dust1(.05-0.5 micron), dust2(0.5-1.25 micron),
1955 : ! dust3(1.25-2.5 micron), dust4(2.5-5.0 micron)
1956 : ! spectral bands same as snow/sea ice: (0.3-0.7 micron, 0.7-1.19 micron
1957 : ! and 1.19-5.0 micron in wavelength)
1958 :
1959 : integer (kind=int_kind) :: &
1960 : na , n ! aerosol index
1961 :
1962 : real (kind=dbl_kind) :: &
1963 1261575 : taer , & ! total aerosol extinction optical depth
1964 1261575 : waer , & ! total aerosol single scatter albedo
1965 1261575 : gaer , & ! total aerosol asymmetry parameter
1966 1261575 : swdr , & ! shortwave down at surface, direct (W/m^2)
1967 1261575 : swdf , & ! shortwave down at surface, diffuse (W/m^2)
1968 1261575 : rnilyr , & ! real(nilyr)
1969 1261575 : rnslyr , & ! real(nslyr)
1970 1261575 : rns , & ! real(ns)
1971 2523150 : tmp_0, tmp_ks, tmp_kl ! temp variables
1972 :
1973 : integer(kind=int_kind), dimension(0:klev) :: &
1974 6675424 : k_bcini , & !
1975 6675424 : k_bcins , &
1976 4599287 : k_bcexs
1977 : real(kind=dbl_kind):: &
1978 1261575 : tmp_gs, tmp1 ! temp variables
1979 :
1980 : ! snow grain radii (micro-meters) for table
1981 : real (kind=dbl_kind), dimension(nmbrad), parameter :: &
1982 : rsnw_tab = (/ & ! snow grain radius for each table entry (micro-meters)
1983 : 5._dbl_kind, 7._dbl_kind, 10._dbl_kind, 15._dbl_kind, &
1984 : 20._dbl_kind, 30._dbl_kind, 40._dbl_kind, 50._dbl_kind, &
1985 : 65._dbl_kind, 80._dbl_kind, 100._dbl_kind, 120._dbl_kind, &
1986 : 140._dbl_kind, 170._dbl_kind, 200._dbl_kind, 240._dbl_kind, &
1987 : 290._dbl_kind, 350._dbl_kind, 420._dbl_kind, 500._dbl_kind, &
1988 : 570._dbl_kind, 660._dbl_kind, 760._dbl_kind, 870._dbl_kind, &
1989 : 1000._dbl_kind, 1100._dbl_kind, 1250._dbl_kind, 1400._dbl_kind, &
1990 : 1600._dbl_kind, 1800._dbl_kind, 2000._dbl_kind, 2500._dbl_kind/)
1991 :
1992 : ! snow extinction efficiency (unitless)
1993 : real (kind=dbl_kind), dimension (nspint,nmbrad), parameter :: &
1994 : Qs_tab = reshape((/ &
1995 : 2.131798_dbl_kind, 2.187756_dbl_kind, 2.267358_dbl_kind, &
1996 : 2.104499_dbl_kind, 2.148345_dbl_kind, 2.236078_dbl_kind, &
1997 : 2.081580_dbl_kind, 2.116885_dbl_kind, 2.175067_dbl_kind, &
1998 : 2.062595_dbl_kind, 2.088937_dbl_kind, 2.130242_dbl_kind, &
1999 : 2.051403_dbl_kind, 2.072422_dbl_kind, 2.106610_dbl_kind, &
2000 : 2.039223_dbl_kind, 2.055389_dbl_kind, 2.080586_dbl_kind, &
2001 : 2.032383_dbl_kind, 2.045751_dbl_kind, 2.066394_dbl_kind, &
2002 : 2.027920_dbl_kind, 2.039388_dbl_kind, 2.057224_dbl_kind, &
2003 : 2.023444_dbl_kind, 2.033137_dbl_kind, 2.048055_dbl_kind, &
2004 : 2.020412_dbl_kind, 2.028840_dbl_kind, 2.041874_dbl_kind, &
2005 : 2.017608_dbl_kind, 2.024863_dbl_kind, 2.036046_dbl_kind, &
2006 : 2.015592_dbl_kind, 2.022021_dbl_kind, 2.031954_dbl_kind, &
2007 : 2.014083_dbl_kind, 2.019887_dbl_kind, 2.028853_dbl_kind, &
2008 : 2.012368_dbl_kind, 2.017471_dbl_kind, 2.025353_dbl_kind, &
2009 : 2.011092_dbl_kind, 2.015675_dbl_kind, 2.022759_dbl_kind, &
2010 : 2.009837_dbl_kind, 2.013897_dbl_kind, 2.020168_dbl_kind, &
2011 : 2.008668_dbl_kind, 2.012252_dbl_kind, 2.017781_dbl_kind, &
2012 : 2.007627_dbl_kind, 2.010813_dbl_kind, 2.015678_dbl_kind, &
2013 : 2.006764_dbl_kind, 2.009577_dbl_kind, 2.013880_dbl_kind, &
2014 : 2.006037_dbl_kind, 2.008520_dbl_kind, 2.012382_dbl_kind, &
2015 : 2.005528_dbl_kind, 2.007807_dbl_kind, 2.011307_dbl_kind, &
2016 : 2.005025_dbl_kind, 2.007079_dbl_kind, 2.010280_dbl_kind, &
2017 : 2.004562_dbl_kind, 2.006440_dbl_kind, 2.009333_dbl_kind, &
2018 : 2.004155_dbl_kind, 2.005898_dbl_kind, 2.008523_dbl_kind, &
2019 : 2.003794_dbl_kind, 2.005379_dbl_kind, 2.007795_dbl_kind, &
2020 : 2.003555_dbl_kind, 2.005041_dbl_kind, 2.007329_dbl_kind, &
2021 : 2.003264_dbl_kind, 2.004624_dbl_kind, 2.006729_dbl_kind, &
2022 : 2.003037_dbl_kind, 2.004291_dbl_kind, 2.006230_dbl_kind, &
2023 : 2.002776_dbl_kind, 2.003929_dbl_kind, 2.005700_dbl_kind, &
2024 : 2.002590_dbl_kind, 2.003627_dbl_kind, 2.005276_dbl_kind, &
2025 : 2.002395_dbl_kind, 2.003391_dbl_kind, 2.004904_dbl_kind, &
2026 : 2.002071_dbl_kind, 2.002922_dbl_kind, 2.004241_dbl_kind/), &
2027 : (/nspint,nmbrad/))
2028 :
2029 : ! snow single scattering albedo (unitless)
2030 : real (kind=dbl_kind), dimension (nspint,nmbrad), parameter :: &
2031 : ws_tab = reshape((/ &
2032 : 0.9999994_dbl_kind, 0.9999673_dbl_kind, 0.9954589_dbl_kind, &
2033 : 0.9999992_dbl_kind, 0.9999547_dbl_kind, 0.9938576_dbl_kind, &
2034 : 0.9999990_dbl_kind, 0.9999382_dbl_kind, 0.9917989_dbl_kind, &
2035 : 0.9999985_dbl_kind, 0.9999123_dbl_kind, 0.9889724_dbl_kind, &
2036 : 0.9999979_dbl_kind, 0.9998844_dbl_kind, 0.9866190_dbl_kind, &
2037 : 0.9999970_dbl_kind, 0.9998317_dbl_kind, 0.9823021_dbl_kind, &
2038 : 0.9999960_dbl_kind, 0.9997800_dbl_kind, 0.9785269_dbl_kind, &
2039 : 0.9999951_dbl_kind, 0.9997288_dbl_kind, 0.9751601_dbl_kind, &
2040 : 0.9999936_dbl_kind, 0.9996531_dbl_kind, 0.9706974_dbl_kind, &
2041 : 0.9999922_dbl_kind, 0.9995783_dbl_kind, 0.9667577_dbl_kind, &
2042 : 0.9999903_dbl_kind, 0.9994798_dbl_kind, 0.9621007_dbl_kind, &
2043 : 0.9999885_dbl_kind, 0.9993825_dbl_kind, 0.9579541_dbl_kind, &
2044 : 0.9999866_dbl_kind, 0.9992862_dbl_kind, 0.9541924_dbl_kind, &
2045 : 0.9999838_dbl_kind, 0.9991434_dbl_kind, 0.9490959_dbl_kind, &
2046 : 0.9999810_dbl_kind, 0.9990025_dbl_kind, 0.9444940_dbl_kind, &
2047 : 0.9999772_dbl_kind, 0.9988171_dbl_kind, 0.9389141_dbl_kind, &
2048 : 0.9999726_dbl_kind, 0.9985890_dbl_kind, 0.9325819_dbl_kind, &
2049 : 0.9999670_dbl_kind, 0.9983199_dbl_kind, 0.9256405_dbl_kind, &
2050 : 0.9999605_dbl_kind, 0.9980117_dbl_kind, 0.9181533_dbl_kind, &
2051 : 0.9999530_dbl_kind, 0.9976663_dbl_kind, 0.9101540_dbl_kind, &
2052 : 0.9999465_dbl_kind, 0.9973693_dbl_kind, 0.9035031_dbl_kind, &
2053 : 0.9999382_dbl_kind, 0.9969939_dbl_kind, 0.8953134_dbl_kind, &
2054 : 0.9999289_dbl_kind, 0.9965848_dbl_kind, 0.8865789_dbl_kind, &
2055 : 0.9999188_dbl_kind, 0.9961434_dbl_kind, 0.8773350_dbl_kind, &
2056 : 0.9999068_dbl_kind, 0.9956323_dbl_kind, 0.8668233_dbl_kind, &
2057 : 0.9998975_dbl_kind, 0.9952464_dbl_kind, 0.8589990_dbl_kind, &
2058 : 0.9998837_dbl_kind, 0.9946782_dbl_kind, 0.8476493_dbl_kind, &
2059 : 0.9998699_dbl_kind, 0.9941218_dbl_kind, 0.8367318_dbl_kind, &
2060 : 0.9998515_dbl_kind, 0.9933966_dbl_kind, 0.8227881_dbl_kind, &
2061 : 0.9998332_dbl_kind, 0.9926888_dbl_kind, 0.8095131_dbl_kind, &
2062 : 0.9998148_dbl_kind, 0.9919968_dbl_kind, 0.7968620_dbl_kind, &
2063 : 0.9997691_dbl_kind, 0.9903277_dbl_kind, 0.7677887_dbl_kind/), &
2064 : (/nspint,nmbrad/))
2065 :
2066 : ! snow asymmetry parameter (unitless)
2067 : real (kind=dbl_kind), dimension (nspint,nmbrad), parameter :: &
2068 : gs_tab = reshape((/ &
2069 : 0.859913_dbl_kind, 0.848003_dbl_kind, 0.824415_dbl_kind, &
2070 : 0.867130_dbl_kind, 0.858150_dbl_kind, 0.848445_dbl_kind, &
2071 : 0.873381_dbl_kind, 0.867221_dbl_kind, 0.861714_dbl_kind, &
2072 : 0.878368_dbl_kind, 0.874879_dbl_kind, 0.874036_dbl_kind, &
2073 : 0.881462_dbl_kind, 0.879661_dbl_kind, 0.881299_dbl_kind, &
2074 : 0.884361_dbl_kind, 0.883903_dbl_kind, 0.890184_dbl_kind, &
2075 : 0.885937_dbl_kind, 0.886256_dbl_kind, 0.895393_dbl_kind, &
2076 : 0.886931_dbl_kind, 0.887769_dbl_kind, 0.899072_dbl_kind, &
2077 : 0.887894_dbl_kind, 0.889255_dbl_kind, 0.903285_dbl_kind, &
2078 : 0.888515_dbl_kind, 0.890236_dbl_kind, 0.906588_dbl_kind, &
2079 : 0.889073_dbl_kind, 0.891127_dbl_kind, 0.910152_dbl_kind, &
2080 : 0.889452_dbl_kind, 0.891750_dbl_kind, 0.913100_dbl_kind, &
2081 : 0.889730_dbl_kind, 0.892213_dbl_kind, 0.915621_dbl_kind, &
2082 : 0.890026_dbl_kind, 0.892723_dbl_kind, 0.918831_dbl_kind, &
2083 : 0.890238_dbl_kind, 0.893099_dbl_kind, 0.921540_dbl_kind, &
2084 : 0.890441_dbl_kind, 0.893474_dbl_kind, 0.924581_dbl_kind, &
2085 : 0.890618_dbl_kind, 0.893816_dbl_kind, 0.927701_dbl_kind, &
2086 : 0.890762_dbl_kind, 0.894123_dbl_kind, 0.930737_dbl_kind, &
2087 : 0.890881_dbl_kind, 0.894397_dbl_kind, 0.933568_dbl_kind, &
2088 : 0.890975_dbl_kind, 0.894645_dbl_kind, 0.936148_dbl_kind, &
2089 : 0.891035_dbl_kind, 0.894822_dbl_kind, 0.937989_dbl_kind, &
2090 : 0.891097_dbl_kind, 0.895020_dbl_kind, 0.939949_dbl_kind, &
2091 : 0.891147_dbl_kind, 0.895212_dbl_kind, 0.941727_dbl_kind, &
2092 : 0.891189_dbl_kind, 0.895399_dbl_kind, 0.943339_dbl_kind, &
2093 : 0.891225_dbl_kind, 0.895601_dbl_kind, 0.944915_dbl_kind, &
2094 : 0.891248_dbl_kind, 0.895745_dbl_kind, 0.945950_dbl_kind, &
2095 : 0.891277_dbl_kind, 0.895951_dbl_kind, 0.947288_dbl_kind, &
2096 : 0.891299_dbl_kind, 0.896142_dbl_kind, 0.948438_dbl_kind, &
2097 : 0.891323_dbl_kind, 0.896388_dbl_kind, 0.949762_dbl_kind, &
2098 : 0.891340_dbl_kind, 0.896623_dbl_kind, 0.950916_dbl_kind, &
2099 : 0.891356_dbl_kind, 0.896851_dbl_kind, 0.951945_dbl_kind, &
2100 : 0.891386_dbl_kind, 0.897399_dbl_kind, 0.954156_dbl_kind/), &
2101 : (/nspint,nmbrad/))
2102 :
2103 : ! inherent optical property (iop) arrays for ice and ponded ice
2104 : ! mn = specified mean (or base) value
2105 : ! ki = extinction coefficient (/m)
2106 : ! wi = single scattering albedo
2107 : ! gi = asymmetry parameter
2108 :
2109 : ! ice surface scattering layer (ssl) iops
2110 : real (kind=dbl_kind), dimension (nspint), parameter :: &
2111 : ki_ssl_mn = (/ 1000.1_dbl_kind, 1003.7_dbl_kind, 7042._dbl_kind/), &
2112 : wi_ssl_mn = (/ .9999_dbl_kind, .9963_dbl_kind, .9088_dbl_kind/), &
2113 : gi_ssl_mn = (/ .94_dbl_kind, .94_dbl_kind, .94_dbl_kind/)
2114 :
2115 : ! ice drained layer (dl) iops
2116 : real (kind=dbl_kind), dimension (nspint), parameter :: &
2117 : ki_dl_mn = (/ 100.2_dbl_kind, 107.7_dbl_kind, 1309._dbl_kind /), &
2118 : wi_dl_mn = (/ .9980_dbl_kind, .9287_dbl_kind, .0305_dbl_kind /), &
2119 : gi_dl_mn = (/ .94_dbl_kind, .94_dbl_kind, .94_dbl_kind /)
2120 :
2121 : ! ice interior layer (int) iops
2122 : real (kind=dbl_kind), dimension (nspint), parameter :: &
2123 : ki_int_mn = (/ 20.2_dbl_kind, 27.7_dbl_kind, 1445._dbl_kind /), &
2124 : wi_int_mn = (/ .9901_dbl_kind, .7223_dbl_kind, .0277_dbl_kind /), &
2125 : gi_int_mn = (/ .94_dbl_kind, .94_dbl_kind, .94_dbl_kind /)
2126 :
2127 : ! ponded ice surface scattering layer (ssl) iops
2128 : real (kind=dbl_kind), dimension (nspint), parameter :: &
2129 : ki_p_ssl_mn = (/ 70.2_dbl_kind, 77.7_dbl_kind, 1309._dbl_kind/), &
2130 : wi_p_ssl_mn = (/ .9972_dbl_kind, .9009_dbl_kind, .0305_dbl_kind/), &
2131 : gi_p_ssl_mn = (/ .94_dbl_kind, .94_dbl_kind, .94_dbl_kind /)
2132 :
2133 : ! ponded ice interior layer (int) iops
2134 : real (kind=dbl_kind), dimension (nspint), parameter :: &
2135 : ki_p_int_mn = (/ 20.2_dbl_kind, 27.7_dbl_kind, 1445._dbl_kind/), &
2136 : wi_p_int_mn = (/ .9901_dbl_kind, .7223_dbl_kind, .0277_dbl_kind/), &
2137 : gi_p_int_mn = (/ .94_dbl_kind, .94_dbl_kind, .94_dbl_kind /)
2138 :
2139 : ! inherent optical property (iop) arrays for pond water and underlying ocean
2140 : ! kw = Pond water extinction coefficient (/m)
2141 : ! ww = Pond water single scattering albedo
2142 : ! gw = Pond water asymmetry parameter
2143 : real (kind=dbl_kind), dimension (nspint), parameter :: &
2144 : kw = (/ 0.20_dbl_kind, 12.0_dbl_kind, 729._dbl_kind /), &
2145 : ww = (/ 0.00_dbl_kind, 0.00_dbl_kind, 0.00_dbl_kind /), &
2146 : gw = (/ 0.00_dbl_kind, 0.00_dbl_kind, 0.00_dbl_kind /)
2147 :
2148 : real (kind=dbl_kind), parameter :: &
2149 : rhoi = 917.0_dbl_kind,& ! pure ice mass density (kg/m3)
2150 : fr_max = 1.00_dbl_kind, & ! snow grain adjustment factor max
2151 : fr_min = 0.80_dbl_kind, & ! snow grain adjustment factor min
2152 : ! tuning parameters
2153 : ! ice and pond scat coeff fractional change for +- one-sigma in albedo
2154 : fp_ice = 0.15_dbl_kind, & ! ice fraction of scat coeff for + stn dev in alb
2155 : fm_ice = 0.15_dbl_kind, & ! ice fraction of scat coeff for - stn dev in alb
2156 : fp_pnd = 2.00_dbl_kind, & ! ponded ice fraction of scat coeff for + stn dev in alb
2157 : fm_pnd = 0.50_dbl_kind ! ponded ice fraction of scat coeff for - stn dev in alb
2158 :
2159 : real (kind=dbl_kind), parameter :: & !chla-specific absorption coefficient
2160 : kchl_tab = 0.01 !0.0023-0.0029 Perovich 1993, also 0.0067 m^2 (mg Chl)^-1
2161 : ! found values of 0.006 to 0.023 m^2/ mg (676 nm) Neukermans 2014
2162 : ! and averages over the 300-700nm of 0.0075 m^2/mg in ice Fritsen (2011)
2163 : ! at 440nm values as high as 0.2 m^2/mg in under ice bloom (Balch 2014)
2164 : ! Grenfell 1991 uses 0.004 (m^2/mg) which is (0.0078 * spectral weighting)
2165 : !chlorophyll mass extinction cross section (m^2/mg chla)
2166 :
2167 : character(len=*),parameter :: subname='(compute_dEdd)'
2168 :
2169 : !-----------------------------------------------------------------------
2170 : ! Initialize and tune bare ice/ponded ice iops
2171 :
2172 37945348 : k_bcini(:) = c0
2173 37945348 : k_bcins(:) = c0
2174 37945348 : k_bcexs(:) = c0
2175 :
2176 3337712 : rnilyr = c1/real(nilyr,kind=dbl_kind)
2177 3337712 : rnslyr = c1/real(nslyr,kind=dbl_kind)
2178 3337712 : kii = nslyr + 1
2179 :
2180 : ! initialize albedos and fluxes to 0
2181 30039408 : fthrul = c0
2182 26701696 : Iabs = c0
2183 141768256 : kabs_chl(:,:) = c0
2184 141768256 : tzaer(:,:) = c0
2185 141768256 : wzaer(:,:) = c0
2186 141768256 : gzaer(:,:) = c0
2187 :
2188 3337712 : avdr = c0
2189 3337712 : avdf = c0
2190 3337712 : aidr = c0
2191 3337712 : aidf = c0
2192 3337712 : fsfc = c0
2193 3337712 : fint = c0
2194 3337712 : fthru = c0
2195 3337712 : fthruvdr = c0
2196 3337712 : fthruvdf = c0
2197 3337712 : fthruidr = c0
2198 3337712 : fthruidf = c0
2199 :
2200 : ! spectral weights
2201 : ! weights 2 (0.7-1.19 micro-meters) and 3 (1.19-5.0 micro-meters)
2202 : ! are chosen based on 1D calculations using ratio of direct to total
2203 : ! near-infrared solar (0.7-5.0 micro-meter) which indicates clear/cloudy
2204 : ! conditions: more cloud, the less 1.19-5.0 relative to the
2205 : ! 0.7-1.19 micro-meter due to cloud absorption.
2206 3337712 : wghtns(1) = c1
2207 3337712 : wghtns(2) = cp67 + (cp78-cp67)*(c1-fnidr)
2208 : ! wghtns(3) = cp33 + (cp22-cp33)*(c1-fnidr)
2209 3337712 : wghtns(3) = c1 - wghtns(2)
2210 :
2211 : ! find snow grain adjustment factor, dependent upon clear/overcast sky
2212 : ! estimate. comparisons with SNICAR show better agreement with DE when
2213 : ! this factor is included (clear sky near 1 and overcast near 0.8 give
2214 : ! best agreement). Multiply by rnsw here for efficiency.
2215 7905940 : do k = 1, nslyr
2216 4568228 : frsnw(k) = (fr_max*fnidr + fr_min*(c1-fnidr))*rsnw(k)
2217 7905940 : Sabs(k) = c0
2218 : enddo
2219 :
2220 : ! layer thicknesses
2221 : ! snow
2222 3337712 : dz = hs*rnslyr
2223 : ! for small enough snow thickness, ssl thickness half of top snow layer
2224 : !ech: note this is highly resolution dependent!
2225 3337712 : dzk(0) = min(hs_ssl, dz/c2)
2226 3337712 : dzk(1) = dz - dzk(0)
2227 3337712 : if (nslyr > 1) then
2228 1538145 : do k = 2, nslyr
2229 1538145 : dzk(k) = dz
2230 : enddo
2231 : endif
2232 :
2233 : ! ice
2234 3337712 : dz = hi*rnilyr
2235 : ! empirical reduction in sea ice ssl thickness for ice thinner than 1.5m;
2236 : ! factor of 30 gives best albedo comparison with limited observations
2237 3337712 : dz_ssl = hi_ssl
2238 : !ech: note hardwired parameters
2239 : ! if( hi < 1.5_dbl_kind ) dz_ssl = hi/30._dbl_kind
2240 3337712 : dz_ssl = min(hi_ssl, hi/30._dbl_kind)
2241 : ! set sea ice ssl thickness to half top layer if sea ice thin enough
2242 : !ech: note this is highly resolution dependent!
2243 3337712 : dz_ssl = min(dz_ssl, dz/c2)
2244 :
2245 3337712 : dzk(kii) = dz_ssl
2246 3337712 : dzk(kii+1) = dz - dz_ssl
2247 3337712 : if (kii+2 <= klev) then
2248 23363984 : do k = kii+2, klev
2249 23363984 : dzk(k) = dz
2250 : enddo
2251 : endif
2252 :
2253 : ! adjust sea ice iops with tuning parameters; tune only the
2254 : ! scattering coefficient by factors of R_ice, R_pnd, where
2255 : ! R values of +1 correspond approximately to +1 sigma changes in albedo, and
2256 : ! R values of -1 correspond approximately to -1 sigma changes in albedo
2257 : ! Note: the albedo change becomes non-linear for R values > +1 or < -1
2258 3337712 : if( R_ice >= c0 ) then
2259 13350848 : do ns = 1, nspint
2260 10013136 : sigp = ki_ssl_mn(ns)*wi_ssl_mn(ns)*(c1+fp_ice*R_ice)
2261 10013136 : ki_ssl(ns) = sigp+ki_ssl_mn(ns)*(c1-wi_ssl_mn(ns))
2262 10013136 : wi_ssl(ns) = sigp/ki_ssl(ns)
2263 10013136 : gi_ssl(ns) = gi_ssl_mn(ns)
2264 :
2265 10013136 : sigp = ki_dl_mn(ns)*wi_dl_mn(ns)*(c1+fp_ice*R_ice)
2266 10013136 : ki_dl(ns) = sigp+ki_dl_mn(ns)*(c1-wi_dl_mn(ns))
2267 10013136 : wi_dl(ns) = sigp/ki_dl(ns)
2268 10013136 : gi_dl(ns) = gi_dl_mn(ns)
2269 :
2270 10013136 : sigp = ki_int_mn(ns)*wi_int_mn(ns)*(c1+fp_ice*R_ice)
2271 10013136 : ki_int(ns) = sigp+ki_int_mn(ns)*(c1-wi_int_mn(ns))
2272 10013136 : wi_int(ns) = sigp/ki_int(ns)
2273 13350848 : gi_int(ns) = gi_int_mn(ns)
2274 : enddo
2275 : else !if( R_ice < c0 ) then
2276 0 : do ns = 1, nspint
2277 0 : sigp = ki_ssl_mn(ns)*wi_ssl_mn(ns)*(c1+fm_ice*R_ice)
2278 0 : sigp = max(sigp, c0)
2279 0 : ki_ssl(ns) = sigp+ki_ssl_mn(ns)*(c1-wi_ssl_mn(ns))
2280 0 : wi_ssl(ns) = sigp/ki_ssl(ns)
2281 0 : gi_ssl(ns) = gi_ssl_mn(ns)
2282 :
2283 0 : sigp = ki_dl_mn(ns)*wi_dl_mn(ns)*(c1+fm_ice*R_ice)
2284 0 : sigp = max(sigp, c0)
2285 0 : ki_dl(ns) = sigp+ki_dl_mn(ns)*(c1-wi_dl_mn(ns))
2286 0 : wi_dl(ns) = sigp/ki_dl(ns)
2287 0 : gi_dl(ns) = gi_dl_mn(ns)
2288 :
2289 0 : sigp = ki_int_mn(ns)*wi_int_mn(ns)*(c1+fm_ice*R_ice)
2290 0 : sigp = max(sigp, c0)
2291 0 : ki_int(ns) = sigp+ki_int_mn(ns)*(c1-wi_int_mn(ns))
2292 0 : wi_int(ns) = sigp/ki_int(ns)
2293 0 : gi_int(ns) = gi_int_mn(ns)
2294 : enddo
2295 : endif ! adjust ice iops
2296 :
2297 : ! adjust ponded ice iops with tuning parameters
2298 3337712 : if( R_pnd >= c0 ) then
2299 13350848 : do ns = 1, nspint
2300 10013136 : sigp = ki_p_ssl_mn(ns)*wi_p_ssl_mn(ns)*(c1+fp_pnd*R_pnd)
2301 10013136 : ki_p_ssl(ns) = sigp+ki_p_ssl_mn(ns)*(c1-wi_p_ssl_mn(ns))
2302 10013136 : wi_p_ssl(ns) = sigp/ki_p_ssl(ns)
2303 10013136 : gi_p_ssl(ns) = gi_p_ssl_mn(ns)
2304 :
2305 10013136 : sigp = ki_p_int_mn(ns)*wi_p_int_mn(ns)*(c1+fp_pnd*R_pnd)
2306 10013136 : ki_p_int(ns) = sigp+ki_p_int_mn(ns)*(c1-wi_p_int_mn(ns))
2307 10013136 : wi_p_int(ns) = sigp/ki_p_int(ns)
2308 13350848 : gi_p_int(ns) = gi_p_int_mn(ns)
2309 : enddo
2310 : else !if( R_pnd < c0 ) then
2311 0 : do ns = 1, nspint
2312 0 : sigp = ki_p_ssl_mn(ns)*wi_p_ssl_mn(ns)*(c1+fm_pnd*R_pnd)
2313 0 : sigp = max(sigp, c0)
2314 0 : ki_p_ssl(ns) = sigp+ki_p_ssl_mn(ns)*(c1-wi_p_ssl_mn(ns))
2315 0 : wi_p_ssl(ns) = sigp/ki_p_ssl(ns)
2316 0 : gi_p_ssl(ns) = gi_p_ssl_mn(ns)
2317 :
2318 0 : sigp = ki_p_int_mn(ns)*wi_p_int_mn(ns)*(c1+fm_pnd*R_pnd)
2319 0 : sigp = max(sigp, c0)
2320 0 : ki_p_int(ns) = sigp+ki_p_int_mn(ns)*(c1-wi_p_int_mn(ns))
2321 0 : wi_p_int(ns) = sigp/ki_p_int(ns)
2322 0 : gi_p_int(ns) = gi_p_int_mn(ns)
2323 : enddo
2324 : endif ! adjust ponded ice iops
2325 :
2326 : ! use srftyp to determine interface index of surface absorption
2327 3337712 : if (srftyp == 1) then
2328 : ! snow covered sea ice
2329 2174093 : ksrf = 1
2330 : else
2331 : ! bare sea ice or ponded ice
2332 1163619 : ksrf = nslyr + 2
2333 : endif
2334 :
2335 3337712 : if (tr_bgc_N .and. dEdd_algae) then ! compute kabs_chl for chlorophyll
2336 0 : do k = 0, klev
2337 0 : kabs_chl(1,k) = kchl_tab*zbio(nlt_chl_sw+k)
2338 : enddo
2339 : else
2340 3337712 : k = klev
2341 3337712 : kabs_chl(1,k) = kalg*(0.50_dbl_kind/dzk(k))
2342 : endif ! kabs_chl
2343 :
2344 : !mgf++
2345 3337712 : if (modal_aero) then
2346 0 : do k=0,klev
2347 0 : if (k < nslyr+1) then ! define indices for snow layer
2348 : ! use top rsnw, rhosnw for snow ssl and rest of top layer
2349 0 : ksnow = k - min(k-1,0)
2350 0 : tmp_gs = frsnw(ksnow)
2351 :
2352 : ! get grain size index:
2353 : ! works for 25 < snw_rds < 1625 um:
2354 0 : if (tmp_gs < 125) then
2355 0 : tmp1 = tmp_gs/50
2356 0 : k_bcini(k) = nint(tmp1)
2357 0 : elseif (tmp_gs < 175) then
2358 0 : k_bcini(k) = 2
2359 : else
2360 0 : tmp1 = (tmp_gs/250)+2
2361 0 : k_bcini(k) = nint(tmp1)
2362 : endif
2363 : else ! use the largest snow grain size for ice
2364 0 : k_bcini(k) = 8
2365 : endif
2366 : ! Set index corresponding to BC effective radius. Here,
2367 : ! asssume constant BC effective radius of 100nm
2368 : ! (corresponding to index 2)
2369 0 : k_bcins(k) = 2
2370 0 : k_bcexs(k) = 2
2371 :
2372 : ! check bounds:
2373 0 : if (k_bcini(k) < 1) k_bcini(k) = 1
2374 0 : if (k_bcini(k) > 8) k_bcini(k) = 8
2375 0 : if (k_bcins(k) < 1) k_bcins(k) = 1
2376 0 : if (k_bcins(k) > 10) k_bcins(k) = 10
2377 0 : if (k_bcexs(k) < 1) k_bcexs(k) = 1
2378 0 : if (k_bcexs(k) > 10) k_bcexs(k) = 10
2379 :
2380 : ! print ice radius index:
2381 : ! write(warnstr,*) subname, "MGFICE2:k, ice index= ",k, k_bcini(k)
2382 : ! call icepack_warnings_add(warnstr)
2383 : enddo ! k
2384 :
2385 0 : if (tr_zaero .and. dEdd_algae) then ! compute kzaero for chlorophyll
2386 0 : do n = 1,n_zaero
2387 0 : if (n == 1) then ! interstitial BC
2388 0 : do k = 0, klev
2389 0 : do ns = 1,nspint ! not weighted by aice
2390 0 : tzaer(ns,k) = tzaer(ns,k)+kaer_bc_tab(ns,k_bcexs(k))* &
2391 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2392 0 : wzaer(ns,k) = wzaer(ns,k)+kaer_bc_tab(ns,k_bcexs(k))* &
2393 0 : waer_bc_tab(ns,k_bcexs(k))* &
2394 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2395 0 : gzaer(ns,k) = gzaer(ns,k)+kaer_bc_tab(ns,k_bcexs(k))* &
2396 0 : waer_bc_tab(ns,k_bcexs(k))* &
2397 0 : gaer_bc_tab(ns,k_bcexs(k))*zbio(nlt_zaero_sw(n)+k)*dzk(k)
2398 : enddo ! nspint
2399 : enddo
2400 0 : elseif (n==2) then ! within-ice BC
2401 0 : do k = 0, klev
2402 0 : do ns = 1,nspint
2403 0 : tzaer(ns,k) = tzaer(ns,k)+kaer_bc_tab(ns,k_bcins(k)) * &
2404 0 : bcenh(ns,k_bcins(k),k_bcini(k))* &
2405 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2406 0 : wzaer(ns,k) = wzaer(ns,k)+kaer_bc_tab(ns,k_bcins(k))* &
2407 0 : waer_bc_tab(ns,k_bcins(k))* &
2408 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2409 0 : gzaer(ns,k) = gzaer(ns,k)+kaer_bc_tab(ns,k_bcins(k))* &
2410 0 : waer_bc_tab(ns,k_bcins(k))* &
2411 0 : gaer_bc_tab(ns,k_bcins(k))*zbio(nlt_zaero_sw(n)+k)*dzk(k)
2412 : enddo ! nspint
2413 : enddo
2414 : else ! dust
2415 0 : do k = 0, klev
2416 0 : do ns = 1,nspint ! not weighted by aice
2417 0 : tzaer(ns,k) = tzaer(ns,k)+kaer_tab(ns,n)* &
2418 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2419 0 : wzaer(ns,k) = wzaer(ns,k)+kaer_tab(ns,n)*waer_tab(ns,n)* &
2420 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2421 0 : gzaer(ns,k) = gzaer(ns,k)+kaer_tab(ns,n)*waer_tab(ns,n)* &
2422 0 : gaer_tab(ns,n)*zbio(nlt_zaero_sw(n)+k)*dzk(k)
2423 : enddo ! nspint
2424 : enddo
2425 : endif !(n=1)
2426 : enddo ! n_zaero
2427 : endif ! tr_zaero and dEdd_algae
2428 :
2429 : else ! Bulk aerosol treatment
2430 3337712 : if (tr_zaero .and. dEdd_algae) then ! compute kzaero for chlorophyll
2431 0 : do n = 1,n_zaero ! multiply by aice?
2432 0 : do k = 0, klev
2433 0 : do ns = 1,nspint ! not weighted by aice
2434 0 : tzaer(ns,k) = tzaer(ns,k)+kaer_tab(ns,n)* &
2435 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2436 0 : wzaer(ns,k) = wzaer(ns,k)+kaer_tab(ns,n)*waer_tab(ns,n)* &
2437 0 : zbio(nlt_zaero_sw(n)+k)*dzk(k)
2438 0 : gzaer(ns,k) = gzaer(ns,k)+kaer_tab(ns,n)*waer_tab(ns,n)* &
2439 0 : gaer_tab(ns,n)*zbio(nlt_zaero_sw(n)+k)*dzk(k)
2440 : enddo ! nspint
2441 : enddo
2442 : enddo
2443 : endif !tr_zaero
2444 :
2445 : endif ! modal_aero
2446 :
2447 : !-----------------------------------------------------------------------
2448 :
2449 : ! begin spectral loop
2450 13350848 : do ns = 1, nspint
2451 :
2452 : ! set optical properties of air/snow/pond overlying sea ice
2453 : ! air
2454 10013136 : if( srftyp == 0 ) then
2455 10054704 : do k=0,nslyr
2456 7484328 : tau(k) = c0
2457 7484328 : w0(k) = c0
2458 10054704 : g(k) = c0
2459 : enddo
2460 : ! snow
2461 7442760 : else if( srftyp == 1 ) then
2462 : ! interpolate snow iops using input snow grain radius,
2463 : ! snow density and tabular data
2464 19950357 : do k=0,nslyr
2465 : ! use top rsnw, rhosnw for snow ssl and rest of top layer
2466 13428078 : ksnow = k - min(k-1,0)
2467 : ! find snow iops using input snow density and snow grain radius:
2468 13428078 : if( frsnw(ksnow) < rsnw_tab(1) ) then
2469 0 : Qs = Qs_tab(ns,1)
2470 0 : ws = ws_tab(ns,1)
2471 0 : gs = gs_tab(ns,1)
2472 13428078 : else if( frsnw(ksnow) >= rsnw_tab(nmbrad) ) then
2473 0 : Qs = Qs_tab(ns,nmbrad)
2474 0 : ws = ws_tab(ns,nmbrad)
2475 0 : gs = gs_tab(ns,nmbrad)
2476 : else
2477 : ! linear interpolation in rsnw
2478 429698496 : do nr=2,nmbrad
2479 570118272 : if( rsnw_tab(nr-1) <= frsnw(ksnow) .and. &
2480 167275932 : frsnw(ksnow) < rsnw_tab(nr)) then
2481 9925668 : delr = (frsnw(ksnow) - rsnw_tab(nr-1)) / &
2482 18390912 : (rsnw_tab(nr) - rsnw_tab(nr-1))
2483 4962834 : Qs = Qs_tab(ns,nr-1)*(c1-delr) + &
2484 18390912 : Qs_tab(ns,nr)*delr
2485 4962834 : ws = ws_tab(ns,nr-1)*(c1-delr) + &
2486 18390912 : ws_tab(ns,nr)*delr
2487 4962834 : gs = gs_tab(ns,nr-1)*(c1-delr) + &
2488 18390912 : gs_tab(ns,nr)*delr
2489 : endif
2490 : enddo ! nr
2491 : endif
2492 4962834 : ks = Qs*((rhosnw(ksnow)/rhoi)*3._dbl_kind / &
2493 13428078 : (4._dbl_kind*frsnw(ksnow)*1.0e-6_dbl_kind))
2494 :
2495 13428078 : tau(k) = (ks + kabs_chl(ns,k))*dzk(k)
2496 13428078 : w0(k) = ks/(ks + kabs_chl(ns,k)) *ws
2497 19950357 : g(k) = gs
2498 : enddo ! k
2499 :
2500 :
2501 : ! aerosol in snow
2502 6522279 : if (tr_zaero .and. dEdd_algae) then
2503 0 : do k = 0,nslyr
2504 0 : gzaer(ns,k) = gzaer(ns,k)/(wzaer(ns,k)+puny)
2505 0 : wzaer(ns,k) = wzaer(ns,k)/(tzaer(ns,k)+puny)
2506 0 : g(k) = (g(k)*w0(k)*tau(k) + gzaer(ns,k)*wzaer(ns,k)*tzaer(ns,k)) / &
2507 0 : (w0(k)*tau(k) + wzaer(ns,k)*tzaer(ns,k))
2508 0 : w0(k) = (w0(k)*tau(k) + wzaer(ns,k)*tzaer(ns,k)) / &
2509 0 : (tau(k) + tzaer(ns,k))
2510 0 : tau(k) = tau(k) + tzaer(ns,k)
2511 : enddo
2512 6522279 : elseif (tr_aero) then
2513 440610 : k = 0 ! snow SSL
2514 440610 : taer = c0
2515 440610 : waer = c0
2516 440610 : gaer = c0
2517 :
2518 881220 : do na=1,4*n_aero,4
2519 : ! mgf++
2520 881220 : if (modal_aero) then
2521 0 : if (na == 1) then
2522 : !interstitial BC
2523 : taer = taer + &
2524 0 : aero_mp(na)*kaer_bc_tab(ns,k_bcexs(k))
2525 : waer = waer + &
2526 0 : aero_mp(na)*kaer_bc_tab(ns,k_bcexs(k))* &
2527 0 : waer_bc_tab(ns,k_bcexs(k))
2528 : gaer = gaer + &
2529 0 : aero_mp(na)*kaer_bc_tab(ns,k_bcexs(k))* &
2530 0 : waer_bc_tab(ns,k_bcexs(k))*gaer_bc_tab(ns,k_bcexs(k))
2531 0 : elseif (na == 5)then
2532 : !within-ice BC
2533 : taer = taer + &
2534 0 : aero_mp(na)*kaer_bc_tab(ns,k_bcins(k))* &
2535 0 : bcenh(ns,k_bcins(k),k_bcini(k))
2536 : waer = waer + &
2537 0 : aero_mp(na)*kaer_bc_tab(ns,k_bcins(k))* &
2538 0 : waer_bc_tab(ns,k_bcins(k))
2539 : gaer = gaer + &
2540 0 : aero_mp(na)*kaer_bc_tab(ns,k_bcins(k))* &
2541 0 : waer_bc_tab(ns,k_bcins(k))*gaer_bc_tab(ns,k_bcins(k))
2542 : else
2543 : ! other species (dust)
2544 : taer = taer + &
2545 0 : aero_mp(na)*kaer_tab(ns,(1+(na-1)/4))
2546 : waer = waer + &
2547 0 : aero_mp(na)*kaer_tab(ns,(1+(na-1)/4))* &
2548 0 : waer_tab(ns,(1+(na-1)/4))
2549 : gaer = gaer + &
2550 0 : aero_mp(na)*kaer_tab(ns,(1+(na-1)/4))* &
2551 0 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2552 : endif
2553 : else
2554 : taer = taer + &
2555 440610 : aero_mp(na)*kaer_tab(ns,(1+(na-1)/4))
2556 : waer = waer + &
2557 0 : aero_mp(na)*kaer_tab(ns,(1+(na-1)/4))* &
2558 440610 : waer_tab(ns,(1+(na-1)/4))
2559 : gaer = gaer + &
2560 0 : aero_mp(na)*kaer_tab(ns,(1+(na-1)/4))* &
2561 440610 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2562 : endif !modal_aero
2563 : !mgf--
2564 : enddo ! na
2565 440610 : gaer = gaer/(waer+puny)
2566 440610 : waer = waer/(taer+puny)
2567 :
2568 881220 : do k=1,nslyr
2569 440610 : taer = c0
2570 440610 : waer = c0
2571 440610 : gaer = c0
2572 881220 : do na=1,4*n_aero,4
2573 881220 : if (modal_aero) then
2574 : !mgf++
2575 0 : if (na==1) then
2576 : ! interstitial BC
2577 : taer = taer + &
2578 0 : (aero_mp(na+1)/rnslyr)*kaer_bc_tab(ns,k_bcexs(k))
2579 : waer = waer + &
2580 0 : (aero_mp(na+1)/rnslyr)*kaer_bc_tab(ns,k_bcexs(k))* &
2581 0 : waer_bc_tab(ns,k_bcexs(k))
2582 : gaer = gaer + &
2583 0 : (aero_mp(na+1)/rnslyr)*kaer_bc_tab(ns,k_bcexs(k))* &
2584 0 : waer_bc_tab(ns,k_bcexs(k))*gaer_bc_tab(ns,k_bcexs(k))
2585 0 : elseif (na==5) then
2586 : ! within-ice BC
2587 : taer = taer + &
2588 0 : (aero_mp(na+1)/rnslyr)*kaer_bc_tab(ns,k_bcins(k))*&
2589 0 : bcenh(ns,k_bcins(k),k_bcini(k))
2590 : waer = waer + &
2591 0 : (aero_mp(na+1)/rnslyr)*kaer_bc_tab(ns,k_bcins(k))* &
2592 0 : waer_bc_tab(ns,k_bcins(k))
2593 : gaer = gaer + &
2594 0 : (aero_mp(na+1)/rnslyr)*kaer_bc_tab(ns,k_bcins(k))* &
2595 0 : waer_bc_tab(ns,k_bcins(k))*gaer_bc_tab(ns,k_bcins(k))
2596 :
2597 : else
2598 : ! other species (dust)
2599 : taer = taer + &
2600 0 : (aero_mp(na+1)/rnslyr)*kaer_tab(ns,(1+(na-1)/4))
2601 : waer = waer + &
2602 0 : (aero_mp(na+1)/rnslyr)*kaer_tab(ns,(1+(na-1)/4))* &
2603 0 : waer_tab(ns,(1+(na-1)/4))
2604 : gaer = gaer + &
2605 0 : (aero_mp(na+1)/rnslyr)*kaer_tab(ns,(1+(na-1)/4))* &
2606 0 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2607 : endif !(na==1)
2608 :
2609 : else
2610 : taer = taer + &
2611 440610 : (aero_mp(na+1)*rnslyr)*kaer_tab(ns,(1+(na-1)/4))
2612 : waer = waer + &
2613 0 : (aero_mp(na+1)*rnslyr)*kaer_tab(ns,(1+(na-1)/4))* &
2614 440610 : waer_tab(ns,(1+(na-1)/4))
2615 : gaer = gaer + &
2616 0 : (aero_mp(na+1)*rnslyr)*kaer_tab(ns,(1+(na-1)/4))* &
2617 440610 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2618 : endif ! modal_aero
2619 : !mgf--
2620 : enddo ! na
2621 440610 : gaer = gaer/(waer+puny)
2622 440610 : waer = waer/(taer+puny)
2623 0 : g(k) = (g(k)*w0(k)*tau(k) + gaer*waer*taer) / &
2624 440610 : (w0(k)*tau(k) + waer*taer)
2625 0 : w0(k) = (w0(k)*tau(k) + waer*taer) / &
2626 440610 : (tau(k) + taer)
2627 881220 : tau(k) = tau(k) + taer
2628 : enddo ! k
2629 : endif ! tr_aero
2630 :
2631 : ! pond
2632 : else !if( srftyp == 2 ) then
2633 : ! pond water layers evenly spaced
2634 920481 : dz = hp/(c1/rnslyr+c1)
2635 3725895 : do k=0,nslyr
2636 2805414 : tau(k) = kw(ns)*dz
2637 2805414 : w0(k) = ww(ns)
2638 3725895 : g(k) = gw(ns)
2639 : ! no aerosol in pond
2640 : enddo ! k
2641 : endif ! srftyp
2642 :
2643 : ! set optical properties of sea ice
2644 :
2645 : ! bare or snow-covered sea ice layers
2646 10013136 : if( srftyp <= 1 ) then
2647 : ! ssl
2648 9092655 : k = kii
2649 9092655 : tau(k) = (ki_ssl(ns)+kabs_chl(ns,k))*dzk(k)
2650 9092655 : w0(k) = ki_ssl(ns)/(ki_ssl(ns) + kabs_chl(ns,k))*wi_ssl(ns)
2651 9092655 : g(k) = gi_ssl(ns)
2652 : ! dl
2653 9092655 : k = kii + 1
2654 : ! scale dz for dl relative to 4 even-layer-thickness 1.5m case
2655 9092655 : fs = p25/rnilyr
2656 9092655 : tau(k) = (ki_dl(ns) + kabs_chl(ns,k)) *dzk(k)*fs
2657 9092655 : w0(k) = ki_dl(ns)/(ki_dl(ns) + kabs_chl(ns,k)) *wi_dl(ns)
2658 9092655 : g(k) = gi_dl(ns)
2659 : ! int above lowest layer
2660 9092655 : if (kii+2 <= klev-1) then
2661 54555930 : do k = kii+2, klev-1
2662 45463275 : tau(k) = (ki_int(ns) + kabs_chl(ns,k))*dzk(k)
2663 45463275 : w0(k) = ki_int(ns)/(ki_int(ns) + kabs_chl(ns,k)) *wi_int(ns)
2664 54555930 : g(k) = gi_int(ns)
2665 : enddo
2666 : endif
2667 : ! lowest layer
2668 9092655 : k = klev
2669 : ! add algae to lowest sea ice layer, visible only:
2670 9092655 : kabs = ki_int(ns)*(c1-wi_int(ns))
2671 9092655 : if( ns == 1 ) then
2672 : ! total layer absorption optical depth fixed at value
2673 : ! of kalg*0.50m, independent of actual layer thickness
2674 3030885 : kabs = kabs + kabs_chl(ns,k)
2675 : endif
2676 9092655 : sig = ki_int(ns)*wi_int(ns)
2677 9092655 : tau(k) = (kabs+sig)*dzk(k)
2678 9092655 : w0(k) = (sig/(sig+kabs))
2679 9092655 : g(k) = gi_int(ns)
2680 : ! aerosol in sea ice
2681 9092655 : if (tr_zaero .and. dEdd_algae) then
2682 0 : do k = kii, klev
2683 0 : gzaer(ns,k) = gzaer(ns,k)/(wzaer(ns,k)+puny)
2684 0 : wzaer(ns,k) = wzaer(ns,k)/(tzaer(ns,k)+puny)
2685 0 : g(k) = (g(k)*w0(k)*tau(k) + gzaer(ns,k)*wzaer(ns,k)*tzaer(ns,k)) / &
2686 0 : (w0(k)*tau(k) + wzaer(ns,k)*tzaer(ns,k))
2687 0 : w0(k) = (w0(k)*tau(k) + wzaer(ns,k)*tzaer(ns,k)) / &
2688 0 : (tau(k) + tzaer(ns,k))
2689 0 : tau(k) = tau(k) + tzaer(ns,k)
2690 : enddo
2691 9092655 : elseif (tr_aero) then
2692 551421 : k = kii ! sea ice SSL
2693 551421 : taer = c0
2694 551421 : waer = c0
2695 551421 : gaer = c0
2696 1102842 : do na=1,4*n_aero,4
2697 : !mgf++
2698 1102842 : if (modal_aero) then
2699 0 : if (na==1) then
2700 : ! interstitial BC
2701 : taer = taer + &
2702 0 : aero_mp(na+2)*kaer_bc_tab(ns,k_bcexs(k))
2703 : waer = waer + &
2704 0 : aero_mp(na+2)*kaer_bc_tab(ns,k_bcexs(k))* &
2705 0 : waer_bc_tab(ns,k_bcexs(k))
2706 : gaer = gaer + &
2707 0 : aero_mp(na+2)*kaer_bc_tab(ns,k_bcexs(k))* &
2708 0 : waer_bc_tab(ns,k_bcexs(k))*gaer_bc_tab(ns,k_bcexs(k))
2709 0 : elseif (na==5) then
2710 : ! within-ice BC
2711 : taer = taer + &
2712 0 : aero_mp(na+2)*kaer_bc_tab(ns,k_bcins(k))* &
2713 0 : bcenh(ns,k_bcins(k),k_bcini(k))
2714 : waer = waer + &
2715 0 : aero_mp(na+2)*kaer_bc_tab(ns,k_bcins(k))* &
2716 0 : waer_bc_tab(ns,k_bcins(k))
2717 : gaer = gaer + &
2718 0 : aero_mp(na+2)*kaer_bc_tab(ns,k_bcins(k))* &
2719 0 : waer_bc_tab(ns,k_bcins(k))*gaer_bc_tab(ns,k_bcins(k))
2720 : else
2721 : ! other species (dust)
2722 : taer = taer + &
2723 0 : aero_mp(na+2)*kaer_tab(ns,(1+(na-1)/4))
2724 : waer = waer + &
2725 0 : aero_mp(na+2)*kaer_tab(ns,(1+(na-1)/4))* &
2726 0 : waer_tab(ns,(1+(na-1)/4))
2727 : gaer = gaer + &
2728 0 : aero_mp(na+2)*kaer_tab(ns,(1+(na-1)/4))* &
2729 0 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2730 : endif
2731 : else !bulk
2732 : taer = taer + &
2733 551421 : aero_mp(na+2)*kaer_tab(ns,(1+(na-1)/4))
2734 : waer = waer + &
2735 0 : aero_mp(na+2)*kaer_tab(ns,(1+(na-1)/4))* &
2736 551421 : waer_tab(ns,(1+(na-1)/4))
2737 : gaer = gaer + &
2738 0 : aero_mp(na+2)*kaer_tab(ns,(1+(na-1)/4))* &
2739 551421 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2740 : endif ! modal_aero
2741 : !mgf--
2742 : enddo ! na
2743 :
2744 551421 : gaer = gaer/(waer+puny)
2745 551421 : waer = waer/(taer+puny)
2746 0 : g(k) = (g(k)*w0(k)*tau(k) + gaer*waer*taer) / &
2747 551421 : (w0(k)*tau(k) + waer*taer)
2748 0 : w0(k) = (w0(k)*tau(k) + waer*taer) / &
2749 551421 : (tau(k) + taer)
2750 551421 : tau(k) = tau(k) + taer
2751 4411368 : do k = kii+1, klev
2752 3859947 : taer = c0
2753 3859947 : waer = c0
2754 3859947 : gaer = c0
2755 7719894 : do na=1,4*n_aero,4
2756 : !mgf++
2757 7719894 : if (modal_aero) then
2758 0 : if (na==1) then
2759 : ! interstitial BC
2760 : taer = taer + &
2761 0 : (aero_mp(na+3)/rnilyr)*kaer_bc_tab(ns,k_bcexs(k))
2762 : waer = waer + &
2763 0 : (aero_mp(na+3)/rnilyr)*kaer_bc_tab(ns,k_bcexs(k))* &
2764 0 : waer_bc_tab(ns,k_bcexs(k))
2765 : gaer = gaer + &
2766 0 : (aero_mp(na+3)/rnilyr)*kaer_bc_tab(ns,k_bcexs(k))* &
2767 0 : waer_bc_tab(ns,k_bcexs(k))*gaer_bc_tab(ns,k_bcexs(k))
2768 0 : elseif (na==5) then
2769 : ! within-ice BC
2770 : taer = taer + &
2771 0 : (aero_mp(na+3)/rnilyr)*kaer_bc_tab(ns,k_bcins(k))* &
2772 0 : bcenh(ns,k_bcins(k),k_bcini(k))
2773 : waer = waer + &
2774 0 : (aero_mp(na+3)/rnilyr)*kaer_bc_tab(ns,k_bcins(k))* &
2775 0 : waer_bc_tab(ns,k_bcins(k))
2776 : gaer = gaer + &
2777 0 : (aero_mp(na+3)/rnilyr)*kaer_bc_tab(ns,k_bcins(k))* &
2778 0 : waer_bc_tab(ns,k_bcins(k))*gaer_bc_tab(ns,k_bcins(k))
2779 :
2780 : else
2781 : ! other species (dust)
2782 : taer = taer + &
2783 0 : (aero_mp(na+3)/rnilyr)*kaer_tab(ns,(1+(na-1)/4))
2784 : waer = waer + &
2785 0 : (aero_mp(na+3)/rnilyr)*kaer_tab(ns,(1+(na-1)/4))* &
2786 0 : waer_tab(ns,(1+(na-1)/4))
2787 : gaer = gaer + &
2788 0 : (aero_mp(na+3)/rnilyr)*kaer_tab(ns,(1+(na-1)/4))* &
2789 0 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2790 : endif
2791 : else !bulk
2792 :
2793 : taer = taer + &
2794 3859947 : (aero_mp(na+3)*rnilyr)*kaer_tab(ns,(1+(na-1)/4))
2795 : waer = waer + &
2796 0 : (aero_mp(na+3)*rnilyr)*kaer_tab(ns,(1+(na-1)/4))* &
2797 3859947 : waer_tab(ns,(1+(na-1)/4))
2798 : gaer = gaer + &
2799 0 : (aero_mp(na+3)*rnilyr)*kaer_tab(ns,(1+(na-1)/4))* &
2800 3859947 : waer_tab(ns,(1+(na-1)/4))*gaer_tab(ns,(1+(na-1)/4))
2801 : endif ! modal_aero
2802 : !mgf--
2803 : enddo ! na
2804 3859947 : gaer = gaer/(waer+puny)
2805 3859947 : waer = waer/(taer+puny)
2806 0 : g(k) = (g(k)*w0(k)*tau(k) + gaer*waer*taer) / &
2807 3859947 : (w0(k)*tau(k) + waer*taer)
2808 0 : w0(k) = (w0(k)*tau(k) + waer*taer) / &
2809 3859947 : (tau(k) + taer)
2810 4411368 : tau(k) = tau(k) + taer
2811 : enddo ! k
2812 : endif ! tr_aero
2813 :
2814 : ! sea ice layers under ponds
2815 : else !if( srftyp == 2 ) then
2816 920481 : k = kii
2817 920481 : tau(k) = ki_p_ssl(ns)*dzk(k)
2818 920481 : w0(k) = wi_p_ssl(ns)
2819 920481 : g(k) = gi_p_ssl(ns)
2820 920481 : k = kii + 1
2821 920481 : tau(k) = ki_p_int(ns)*dzk(k)
2822 920481 : w0(k) = wi_p_int(ns)
2823 920481 : g(k) = gi_p_int(ns)
2824 920481 : if (kii+2 <= klev) then
2825 6443367 : do k = kii+2, klev
2826 5522886 : tau(k) = ki_p_int(ns)*dzk(k)
2827 5522886 : w0(k) = wi_p_int(ns)
2828 6443367 : g(k) = gi_p_int(ns)
2829 : enddo ! k
2830 : endif
2831 : ! adjust pond iops if pond depth within specified range
2832 920481 : if( hpmin <= hp .and. hp <= hp0 ) then
2833 679386 : k = kii
2834 679386 : sig_i = ki_ssl(ns)*wi_ssl(ns)
2835 679386 : sig_p = ki_p_ssl(ns)*wi_p_ssl(ns)
2836 679386 : sig = sig_i + (sig_p-sig_i)*(hp/hp0)
2837 679386 : kext = sig + ki_p_ssl(ns)*(c1-wi_p_ssl(ns))
2838 679386 : tau(k) = kext*dzk(k)
2839 679386 : w0(k) = sig/kext
2840 679386 : g(k) = gi_p_int(ns)
2841 679386 : k = kii + 1
2842 : ! scale dz for dl relative to 4 even-layer-thickness 1.5m case
2843 679386 : fs = p25/rnilyr
2844 679386 : sig_i = ki_dl(ns)*wi_dl(ns)*fs
2845 679386 : sig_p = ki_p_int(ns)*wi_p_int(ns)
2846 679386 : sig = sig_i + (sig_p-sig_i)*(hp/hp0)
2847 679386 : kext = sig + ki_p_int(ns)*(c1-wi_p_int(ns))
2848 679386 : tau(k) = kext*dzk(k)
2849 679386 : w0(k) = sig/kext
2850 679386 : g(k) = gi_p_int(ns)
2851 679386 : if (kii+2 <= klev) then
2852 4755702 : do k = kii+2, klev
2853 4076316 : sig_i = ki_int(ns)*wi_int(ns)
2854 4076316 : sig_p = ki_p_int(ns)*wi_p_int(ns)
2855 4076316 : sig = sig_i + (sig_p-sig_i)*(hp/hp0)
2856 4076316 : kext = sig + ki_p_int(ns)*(c1-wi_p_int(ns))
2857 4076316 : tau(k) = kext*dzk(k)
2858 4076316 : w0(k) = sig/kext
2859 4755702 : g(k) = gi_p_int(ns)
2860 : enddo ! k
2861 : endif
2862 : endif ! small pond depth transition to bare sea ice
2863 : endif ! srftyp
2864 :
2865 : ! set reflectivities for ocean underlying sea ice
2866 10013136 : rns = real(ns-1, kind=dbl_kind)
2867 10013136 : albodr = cp01 * (c1 - min(rns, c1))
2868 10013136 : albodf = cp01 * (c1 - min(rns, c1))
2869 :
2870 : ! layer input properties now completely specified: tau, w0, g,
2871 : ! albodr, albodf; now compute the Delta-Eddington solution
2872 : ! reflectivities and transmissivities for each layer; then,
2873 : ! combine the layers going downwards accounting for multiple
2874 : ! scattering between layers, and finally start from the
2875 : ! underlying ocean and combine successive layers upwards to
2876 : ! the surface; see comments in solution_dEdd for more details.
2877 :
2878 : call solution_dEdd &
2879 : (coszen, srftyp, klev, klevp, nslyr, &
2880 : tau, w0, g, albodr, albodf, &
2881 : trndir, trntdr, trndif, rupdir, rupdif, &
2882 10013136 : rdndif)
2883 10013136 : if (icepack_warnings_aborted(subname)) return
2884 :
2885 : ! the interface reflectivities and transmissivities required
2886 : ! to evaluate interface fluxes are returned from solution_dEdd;
2887 : ! now compute up and down fluxes for each interface, using the
2888 : ! combined layer properties at each interface:
2889 : !
2890 : ! layers interface
2891 : !
2892 : ! --------------------- k
2893 : ! k
2894 : ! ---------------------
2895 :
2896 123849180 : do k = 0, klevp
2897 : ! interface scattering
2898 113836044 : refk = c1/(c1 - rdndif(k)*rupdif(k))
2899 : ! dir tran ref from below times interface scattering, plus diff
2900 : ! tran and ref from below times interface scattering
2901 : ! fdirup(k) = (trndir(k)*rupdir(k) + &
2902 : ! (trntdr(k)-trndir(k)) &
2903 : ! *rupdif(k))*refk
2904 : ! dir tran plus total diff trans times interface scattering plus
2905 : ! dir tran with up dir ref and down dif ref times interface scattering
2906 : ! fdirdn(k) = trndir(k) + (trntdr(k) &
2907 : ! - trndir(k) + trndir(k) &
2908 : ! *rupdir(k)*rdndif(k))*refk
2909 : ! diffuse tran ref from below times interface scattering
2910 : ! fdifup(k) = trndif(k)*rupdif(k)*refk
2911 : ! diffuse tran times interface scattering
2912 : ! fdifdn(k) = trndif(k)*refk
2913 :
2914 : ! dfdir = fdirdn - fdirup
2915 42931191 : dfdir(k) = trndir(k) &
2916 42931191 : + (trntdr(k)-trndir(k)) * (c1 - rupdif(k)) * refk &
2917 113836044 : - trndir(k)*rupdir(k) * (c1 - rdndif(k)) * refk
2918 113836044 : if (dfdir(k) < puny) dfdir(k) = c0 !echmod necessary?
2919 : ! dfdif = fdifdn - fdifup
2920 113836044 : dfdif(k) = trndif(k) * (c1 - rupdif(k)) * refk
2921 123849180 : if (dfdif(k) < puny) dfdif(k) = c0 !echmod necessary?
2922 : enddo ! k
2923 :
2924 : ! calculate final surface albedos and fluxes-
2925 : ! all absorbed flux above ksrf is included in surface absorption
2926 :
2927 13350848 : if( ns == 1) then ! visible
2928 :
2929 3337712 : swdr = swvdr
2930 3337712 : swdf = swvdf
2931 3337712 : avdr = rupdir(0)
2932 3337712 : avdf = rupdif(0)
2933 :
2934 3337712 : tmp_0 = dfdir(0 )*swdr + dfdif(0 )*swdf
2935 3337712 : tmp_ks = dfdir(ksrf )*swdr + dfdif(ksrf )*swdf
2936 3337712 : tmp_kl = dfdir(klevp)*swdr + dfdif(klevp)*swdf
2937 :
2938 : ! for layer biology: save visible only
2939 30039408 : do k = nslyr+2, klevp ! Start at DL layer of ice after SSL scattering
2940 30039408 : fthrul(k-nslyr-1) = dfdir(k)*swdr + dfdif(k)*swdf
2941 : enddo
2942 :
2943 3337712 : fsfc = fsfc + tmp_0 - tmp_ks
2944 3337712 : fint = fint + tmp_ks - tmp_kl
2945 3337712 : fthru = fthru + tmp_kl
2946 3337712 : fthruvdr = fthruvdr + dfdir(klevp)*swdr
2947 3337712 : fthruvdf = fthruvdf + dfdif(klevp)*swdf
2948 :
2949 : ! if snow covered ice, set snow internal absorption; else, Sabs=0
2950 3337712 : if( srftyp == 1 ) then
2951 2174093 : ki = 0
2952 4476026 : do k=1,nslyr
2953 : ! skip snow SSL, since SSL absorption included in the surface
2954 : ! absorption fsfc above
2955 2301933 : km = k
2956 2301933 : kp = km + 1
2957 2301933 : ki = ki + 1
2958 859099 : Sabs(ki) = Sabs(ki) &
2959 859099 : + dfdir(km)*swdr + dfdif(km)*swdf &
2960 4476026 : - (dfdir(kp)*swdr + dfdif(kp)*swdf)
2961 : enddo ! k
2962 : endif
2963 :
2964 : ! complex indexing to insure proper absorptions for sea ice
2965 3337712 : ki = 0
2966 26701696 : do k=nslyr+2,nslyr+1+nilyr
2967 : ! for bare ice, DL absorption for sea ice layer 1
2968 23363984 : km = k
2969 23363984 : kp = km + 1
2970 : ! modify for top sea ice layer for snow over sea ice
2971 23363984 : if( srftyp == 1 ) then
2972 : ! must add SSL and DL absorption for sea ice layer 1
2973 15218651 : if( k == nslyr+2 ) then
2974 2174093 : km = k - 1
2975 2174093 : kp = km + 2
2976 : endif
2977 : endif
2978 23363984 : ki = ki + 1
2979 8831025 : Iabs(ki) = Iabs(ki) &
2980 8831025 : + dfdir(km)*swdr + dfdif(km)*swdf &
2981 26701696 : - (dfdir(kp)*swdr + dfdif(kp)*swdf)
2982 : enddo ! k
2983 :
2984 : else !if(ns > 1) then ! near IR
2985 :
2986 6675424 : swdr = swidr
2987 6675424 : swdf = swidf
2988 :
2989 : ! let fr1 = alb_1*swd*wght1 and fr2 = alb_2*swd*wght2 be the ns=2,3
2990 : ! reflected fluxes respectively, where alb_1, alb_2 are the band
2991 : ! albedos, swd = nir incident shortwave flux, and wght1, wght2 are
2992 : ! the 2,3 band weights. thus, the total reflected flux is:
2993 : ! fr = fr1 + fr2 = alb_1*swd*wght1 + alb_2*swd*wght2 hence, the
2994 : ! 2,3 nir band albedo is alb = fr/swd = alb_1*wght1 + alb_2*wght2
2995 :
2996 6675424 : aidr = aidr + rupdir(0)*wghtns(ns)
2997 6675424 : aidf = aidf + rupdif(0)*wghtns(ns)
2998 :
2999 6675424 : tmp_0 = dfdir(0 )*swdr + dfdif(0 )*swdf
3000 6675424 : tmp_ks = dfdir(ksrf )*swdr + dfdif(ksrf )*swdf
3001 6675424 : tmp_kl = dfdir(klevp)*swdr + dfdif(klevp)*swdf
3002 :
3003 6675424 : tmp_0 = tmp_0 * wghtns(ns)
3004 6675424 : tmp_ks = tmp_ks * wghtns(ns)
3005 6675424 : tmp_kl = tmp_kl * wghtns(ns)
3006 :
3007 6675424 : fsfc = fsfc + tmp_0 - tmp_ks
3008 6675424 : fint = fint + tmp_ks - tmp_kl
3009 6675424 : fthru = fthru + tmp_kl
3010 6675424 : fthruidr = fthruidr + dfdir(klevp)*swdr*wghtns(ns)
3011 6675424 : fthruidf = fthruidf + dfdif(klevp)*swdf*wghtns(ns)
3012 :
3013 : ! if snow covered ice, set snow internal absorption; else, Sabs=0
3014 6675424 : if( srftyp == 1 ) then
3015 4348186 : ki = 0
3016 8952052 : do k=1,nslyr
3017 : ! skip snow SSL, since SSL absorption included in the surface
3018 : ! absorption fsfc above
3019 4603866 : km = k
3020 4603866 : kp = km + 1
3021 4603866 : ki = ki + 1
3022 1718198 : Sabs(ki) = Sabs(ki) &
3023 1718198 : + (dfdir(km)*swdr + dfdif(km)*swdf &
3024 1718198 : - (dfdir(kp)*swdr + dfdif(kp)*swdf)) &
3025 8952052 : * wghtns(ns)
3026 : enddo ! k
3027 : endif
3028 :
3029 : ! complex indexing to insure proper absorptions for sea ice
3030 6675424 : ki = 0
3031 53403392 : do k=nslyr+2,nslyr+1+nilyr
3032 : ! for bare ice, DL absorption for sea ice layer 1
3033 46727968 : km = k
3034 46727968 : kp = km + 1
3035 : ! modify for top sea ice layer for snow over sea ice
3036 46727968 : if( srftyp == 1 ) then
3037 : ! must add SSL and DL absorption for sea ice layer 1
3038 30437302 : if( k == nslyr+2 ) then
3039 4348186 : km = k - 1
3040 4348186 : kp = km + 2
3041 : endif
3042 : endif
3043 46727968 : ki = ki + 1
3044 17662050 : Iabs(ki) = Iabs(ki) &
3045 17662050 : + (dfdir(km)*swdr + dfdif(km)*swdf &
3046 17662050 : - (dfdir(kp)*swdr + dfdif(kp)*swdf)) &
3047 53403392 : * wghtns(ns)
3048 : enddo ! k
3049 :
3050 : endif ! ns = 1, ns > 1
3051 :
3052 : enddo ! end spectral loop ns
3053 :
3054 : ! accumulate fluxes over bare sea ice
3055 3337712 : alvdr = avdr
3056 3337712 : alvdf = avdf
3057 3337712 : alidr = aidr
3058 3337712 : alidf = aidf
3059 3337712 : fswsfc = fswsfc + fsfc *fi
3060 3337712 : fswint = fswint + fint *fi
3061 3337712 : fswthru = fswthru + fthru*fi
3062 3337712 : fswthru_vdr = fswthru_vdr + fthruvdr*fi
3063 3337712 : fswthru_vdf = fswthru_vdf + fthruvdf*fi
3064 3337712 : fswthru_idr = fswthru_idr + fthruidr*fi
3065 3337712 : fswthru_idf = fswthru_idf + fthruidf*fi
3066 :
3067 7905940 : do k = 1, nslyr
3068 7905940 : Sswabs(k) = Sswabs(k) + Sabs(k)*fi
3069 : enddo ! k
3070 :
3071 26701696 : do k = 1, nilyr
3072 23363984 : Iswabs(k) = Iswabs(k) + Iabs(k)*fi
3073 :
3074 : ! bgc layer
3075 23363984 : fswpenl(k) = fswpenl(k) + fthrul(k)* fi
3076 26701696 : if (k == nilyr) then
3077 3337712 : fswpenl(k+1) = fswpenl(k+1) + fthrul(k+1)*fi
3078 : endif
3079 : enddo ! k
3080 :
3081 : !----------------------------------------------------------------
3082 : ! if ice has zero heat capacity, no SW can be absorbed
3083 : ! in the ice/snow interior, so add to surface absorption.
3084 : ! Note: nilyr = nslyr = 1 for this case
3085 : !----------------------------------------------------------------
3086 :
3087 3337712 : if (.not. heat_capacity) then
3088 :
3089 : ! SW absorbed at snow/ice surface
3090 0 : fswsfc = fswsfc + Iswabs(1) + Sswabs(1)
3091 :
3092 : ! SW absorbed in ice interior
3093 0 : fswint = c0
3094 0 : Iswabs(1) = c0
3095 0 : Sswabs(1) = c0
3096 :
3097 : endif ! heat_capacity
3098 :
3099 : end subroutine compute_dEdd
3100 :
3101 : !=======================================================================
3102 : !
3103 : ! Given input vertical profiles of optical properties, evaluate the
3104 : ! monochromatic Delta-Eddington solution.
3105 : !
3106 : ! author: Bruce P. Briegleb, NCAR
3107 : ! 2013: E Hunke merged with NCAR version
3108 10013136 : subroutine solution_dEdd &
3109 : (coszen, srftyp, klev, klevp, nslyr, &
3110 10013136 : tau, w0, g, albodr, albodf, &
3111 10013136 : trndir, trntdr, trndif, rupdir, rupdif, &
3112 10013136 : rdndif)
3113 :
3114 : real (kind=dbl_kind), intent(in) :: &
3115 : coszen ! cosine solar zenith angle
3116 :
3117 : integer (kind=int_kind), intent(in) :: &
3118 : srftyp , & ! surface type over ice: (0=air, 1=snow, 2=pond)
3119 : klev , & ! number of radiation layers - 1
3120 : klevp , & ! number of radiation interfaces - 1
3121 : ! (0 layer is included also)
3122 : nslyr ! number of snow layers
3123 :
3124 : real (kind=dbl_kind), dimension(0:klev), intent(in) :: &
3125 : tau , & ! layer extinction optical depth
3126 : w0 , & ! layer single scattering albedo
3127 : g ! layer asymmetry parameter
3128 :
3129 : real (kind=dbl_kind), intent(in) :: &
3130 : albodr , & ! ocean albedo to direct rad
3131 : albodf ! ocean albedo to diffuse rad
3132 :
3133 : ! following arrays are defined at model interfaces; 0 is the top of the
3134 : ! layer above the sea ice; klevp is the sea ice/ocean interface.
3135 : real (kind=dbl_kind), dimension (0:klevp), intent(out) :: &
3136 : trndir , & ! solar beam down transmission from top
3137 : trntdr , & ! total transmission to direct beam for layers above
3138 : trndif , & ! diffuse transmission to diffuse beam for layers above
3139 : rupdir , & ! reflectivity to direct radiation for layers below
3140 : rupdif , & ! reflectivity to diffuse radiation for layers below
3141 : rdndif ! reflectivity to diffuse radiation for layers above
3142 :
3143 : !-----------------------------------------------------------------------
3144 : !
3145 : ! Delta-Eddington solution for snow/air/pond over sea ice
3146 : !
3147 : ! Generic solution for a snow/air/pond input column of klev+1 layers,
3148 : ! with srftyp determining at what interface fresnel refraction occurs.
3149 : !
3150 : ! Computes layer reflectivities and transmissivities, from the top down
3151 : ! to the lowest interface using the Delta-Eddington solutions for each
3152 : ! layer; combines layers from top down to lowest interface, and from the
3153 : ! lowest interface (underlying ocean) up to the top of the column.
3154 : !
3155 : ! Note that layer diffuse reflectivity and transmissivity are computed
3156 : ! by integrating the direct over several gaussian angles. This is
3157 : ! because the diffuse reflectivity expression sometimes is negative,
3158 : ! but the direct reflectivity is always well-behaved. We assume isotropic
3159 : ! radiation in the upward and downward hemispheres for this integration.
3160 : !
3161 : ! Assumes monochromatic (spectrally uniform) properties across a band
3162 : ! for the input optical parameters.
3163 : !
3164 : ! If total transmission of the direct beam to the interface above a particular
3165 : ! layer is less than trmin, then no further Delta-Eddington solutions are
3166 : ! evaluated for layers below.
3167 : !
3168 : ! The following describes how refraction is handled in the calculation.
3169 : !
3170 : ! First, we assume that radiation is refracted when entering either
3171 : ! sea ice at the base of the surface scattering layer, or water (i.e. melt
3172 : ! pond); we assume that radiation does not refract when entering snow, nor
3173 : ! upon entering sea ice from a melt pond, nor upon entering the underlying
3174 : ! ocean from sea ice.
3175 : !
3176 : ! To handle refraction, we define a "fresnel" layer, which physically
3177 : ! is of neglible thickness and is non-absorbing, which can be combined to
3178 : ! any sea ice layer or top of melt pond. The fresnel layer accounts for
3179 : ! refraction of direct beam and associated reflection and transmission for
3180 : ! solar radiation. A fresnel layer is combined with the top of a melt pond
3181 : ! or to the surface scattering layer of sea ice if no melt pond lies over it.
3182 : !
3183 : ! Some caution must be exercised for the fresnel layer, because any layer
3184 : ! to which it is combined is no longer a homogeneous layer, as are all other
3185 : ! individual layers. For all other layers for example, the direct and diffuse
3186 : ! reflectivities/transmissivities (R/T) are the same for radiation above or
3187 : ! below the layer. This is the meaning of homogeneous! But for the fresnel
3188 : ! layer this is not so. Thus, the R/T for this layer must be distinguished
3189 : ! for radiation above from that from radiation below. For generality, we
3190 : ! treat all layers to be combined as inhomogeneous.
3191 : !
3192 : !-----------------------------------------------------------------------
3193 :
3194 : ! local variables
3195 :
3196 : integer (kind=int_kind) :: &
3197 : kfrsnl ! radiation interface index for fresnel layer
3198 :
3199 : ! following variables are defined for each layer; 0 refers to the top
3200 : ! layer. In general we must distinguish directions above and below in
3201 : ! the diffuse reflectivity and transmissivity, as layers are not assumed
3202 : ! to be homogeneous (apart from the single layer Delta-Edd solutions);
3203 : ! the direct is always from above.
3204 : real (kind=dbl_kind), dimension (0:klev) :: &
3205 55388013 : rdir , & ! layer reflectivity to direct radiation
3206 55388013 : rdif_a , & ! layer reflectivity to diffuse radiation from above
3207 55388013 : rdif_b , & ! layer reflectivity to diffuse radiation from below
3208 55388013 : tdir , & ! layer transmission to direct radiation (solar beam + diffuse)
3209 55388013 : tdif_a , & ! layer transmission to diffuse radiation from above
3210 55388013 : tdif_b , & ! layer transmission to diffuse radiation from below
3211 55388013 : trnlay ! solar beam transm for layer (direct beam only)
3212 :
3213 : integer (kind=int_kind) :: &
3214 : k ! level index
3215 :
3216 : real (kind=dbl_kind), parameter :: &
3217 : trmin = 0.001_dbl_kind ! minimum total transmission allowed
3218 : ! total transmission is that due to the direct beam; i.e. it includes
3219 : ! both the directly transmitted solar beam and the diffuse downwards
3220 : ! transmitted radiation resulting from scattering out of the direct beam
3221 : real (kind=dbl_kind) :: &
3222 3784725 : tautot , & ! layer optical depth
3223 3784725 : wtot , & ! layer single scattering albedo
3224 3784725 : gtot , & ! layer asymmetry parameter
3225 3784725 : ftot , & ! layer forward scattering fraction
3226 3784725 : ts , & ! layer scaled extinction optical depth
3227 3784725 : ws , & ! layer scaled single scattering albedo
3228 3784725 : gs , & ! layer scaled asymmetry parameter
3229 3784725 : rintfc , & ! reflection (multiple) at an interface
3230 3784725 : refkp1 , & ! interface multiple scattering for k+1
3231 3784725 : refkm1 , & ! interface multiple scattering for k-1
3232 3784725 : tdrrdir , & ! direct tran times layer direct ref
3233 3784725 : tdndif ! total down diffuse = tot tran - direct tran
3234 :
3235 : ! perpendicular and parallel relative to plane of incidence and scattering
3236 : real (kind=dbl_kind) :: &
3237 3784725 : R1 , & ! perpendicular polarization reflection amplitude
3238 3784725 : R2 , & ! parallel polarization reflection amplitude
3239 3784725 : T1 , & ! perpendicular polarization transmission amplitude
3240 3784725 : T2 , & ! parallel polarization transmission amplitude
3241 3784725 : Rf_dir_a , & ! fresnel reflection to direct radiation
3242 3784725 : Tf_dir_a , & ! fresnel transmission to direct radiation
3243 3784725 : Rf_dif_a , & ! fresnel reflection to diff radiation from above
3244 3784725 : Rf_dif_b , & ! fresnel reflection to diff radiation from below
3245 3784725 : Tf_dif_a , & ! fresnel transmission to diff radiation from above
3246 3784725 : Tf_dif_b ! fresnel transmission to diff radiation from below
3247 :
3248 : ! refractive index for sea ice, water; pre-computed, band-independent,
3249 : ! diffuse fresnel reflectivities
3250 : real (kind=dbl_kind), parameter :: &
3251 : refindx = 1.310_dbl_kind , & ! refractive index of sea ice (water also)
3252 : cp063 = 0.063_dbl_kind , & ! diffuse fresnel reflectivity from above
3253 : cp455 = 0.455_dbl_kind ! diffuse fresnel reflectivity from below
3254 :
3255 : real (kind=dbl_kind) :: &
3256 3784725 : mu0 , & ! cosine solar zenith angle incident
3257 3784725 : mu0nij ! cosine solar zenith angle in medium below fresnel level
3258 :
3259 : real (kind=dbl_kind) :: &
3260 3784725 : mu0n ! cosine solar zenith angle in medium
3261 :
3262 : real (kind=dbl_kind) :: &
3263 3784725 : alp , & ! temporary for alpha
3264 3784725 : gam , & ! temporary for agamm
3265 3784725 : lm , & ! temporary for el
3266 3784725 : mu , & ! temporary for gauspt
3267 3784725 : ne , & ! temporary for n
3268 3784725 : ue , & ! temporary for u
3269 3784725 : extins , & ! extinction
3270 3784725 : amg , & ! alp - gam
3271 3784725 : apg ! alp + gam
3272 :
3273 : integer (kind=int_kind), parameter :: &
3274 : ngmax = 8 ! number of gaussian angles in hemisphere
3275 :
3276 : real (kind=dbl_kind), dimension (ngmax), parameter :: &
3277 : gauspt & ! gaussian angles (radians)
3278 : = (/ .9894009_dbl_kind, .9445750_dbl_kind, &
3279 : .8656312_dbl_kind, .7554044_dbl_kind, &
3280 : .6178762_dbl_kind, .4580168_dbl_kind, &
3281 : .2816036_dbl_kind, .0950125_dbl_kind/), &
3282 : gauswt & ! gaussian weights
3283 : = (/ .0271525_dbl_kind, .0622535_dbl_kind, &
3284 : .0951585_dbl_kind, .1246290_dbl_kind, &
3285 : .1495960_dbl_kind, .1691565_dbl_kind, &
3286 : .1826034_dbl_kind, .1894506_dbl_kind/)
3287 :
3288 : integer (kind=int_kind) :: &
3289 : ng ! gaussian integration index
3290 :
3291 : real (kind=dbl_kind) :: &
3292 3784725 : gwt , & ! gaussian weight
3293 3784725 : swt , & ! sum of weights
3294 3784725 : trn , & ! layer transmission
3295 3784725 : rdr , & ! rdir for gaussian integration
3296 3784725 : tdr , & ! tdir for gaussian integration
3297 3784725 : smr , & ! accumulator for rdif gaussian integration
3298 3784725 : smt ! accumulator for tdif gaussian integration
3299 :
3300 : real (kind=dbl_kind) :: &
3301 3784725 : exp_min ! minimum exponential value
3302 :
3303 : character(len=*),parameter :: subname='(solution_dEdd)'
3304 :
3305 : !-----------------------------------------------------------------------
3306 :
3307 123849180 : do k = 0, klevp
3308 113836044 : trndir(k) = c0
3309 113836044 : trntdr(k) = c0
3310 113836044 : trndif(k) = c0
3311 113836044 : rupdir(k) = c0
3312 113836044 : rupdif(k) = c0
3313 123849180 : rdndif(k) = c0
3314 : enddo
3315 :
3316 : ! initialize top interface of top layer
3317 10013136 : trndir(0) = c1
3318 10013136 : trntdr(0) = c1
3319 10013136 : trndif(0) = c1
3320 10013136 : rdndif(0) = c0
3321 :
3322 : ! mu0 is cosine solar zenith angle above the fresnel level; make
3323 : ! sure mu0 is large enough for stable and meaningful radiation
3324 : ! solution: .01 is like sun just touching horizon with its lower edge
3325 10013136 : mu0 = max(coszen,p01)
3326 :
3327 : ! mu0n is cosine solar zenith angle used to compute the layer
3328 : ! Delta-Eddington solution; it is initially computed to be the
3329 : ! value below the fresnel level, i.e. the cosine solar zenith
3330 : ! angle below the fresnel level for the refracted solar beam:
3331 10013136 : mu0nij = sqrt(c1-((c1-mu0**2)/(refindx*refindx)))
3332 :
3333 : ! compute level of fresnel refraction
3334 : ! if ponded sea ice, fresnel level is the top of the pond.
3335 10013136 : kfrsnl = 0
3336 : ! if snow over sea ice or bare sea ice, fresnel level is
3337 : ! at base of sea ice SSL (and top of the sea ice DL); the
3338 : ! snow SSL counts for one, then the number of snow layers,
3339 : ! then the sea ice SSL which also counts for one:
3340 10013136 : if( srftyp < 2 ) kfrsnl = nslyr + 2
3341 :
3342 : ! proceed down one layer at a time; if the total transmission to
3343 : ! the interface just above a given layer is less than trmin, then no
3344 : ! Delta-Eddington computation for that layer is done.
3345 :
3346 : ! begin main level loop
3347 113836044 : do k = 0, klev
3348 :
3349 : ! initialize all layer apparent optical properties to 0
3350 103822908 : rdir (k) = c0
3351 103822908 : rdif_a(k) = c0
3352 103822908 : rdif_b(k) = c0
3353 103822908 : tdir (k) = c0
3354 103822908 : tdif_a(k) = c0
3355 103822908 : tdif_b(k) = c0
3356 103822908 : trnlay(k) = c0
3357 :
3358 : ! compute next layer Delta-eddington solution only if total transmission
3359 : ! of radiation to the interface just above the layer exceeds trmin.
3360 :
3361 103822908 : if (trntdr(k) > trmin ) then
3362 :
3363 : ! calculation over layers with penetrating radiation
3364 :
3365 53991881 : tautot = tau(k)
3366 53991881 : wtot = w0(k)
3367 53991881 : gtot = g(k)
3368 53991881 : ftot = gtot*gtot
3369 :
3370 53991881 : ts = taus(wtot,ftot,tautot)
3371 53991881 : ws = omgs(wtot,ftot)
3372 53991881 : gs = asys(gtot,ftot)
3373 53991881 : lm = el(ws,gs)
3374 53991881 : ue = u(ws,gs,lm)
3375 :
3376 53991881 : mu0n = mu0nij
3377 : ! if level k is above fresnel level and the cell is non-pond, use the
3378 : ! non-refracted beam instead
3379 53991881 : if( srftyp < 2 .and. k < kfrsnl ) mu0n = mu0
3380 :
3381 53991881 : exp_min = min(exp_argmax,lm*ts)
3382 53991881 : extins = exp(-exp_min)
3383 53991881 : ne = n(ue,extins)
3384 :
3385 : ! first calculation of rdif, tdif using Delta-Eddington formulas
3386 : ! rdif_a(k) = (ue+c1)*(ue-c1)*(c1/extins - extins)/ne
3387 53991881 : rdif_a(k) = (ue**2-c1)*(c1/extins - extins)/ne
3388 53991881 : tdif_a(k) = c4*ue/ne
3389 :
3390 : ! evaluate rdir,tdir for direct beam
3391 53991881 : exp_min = min(exp_argmax,ts/mu0n)
3392 53991881 : trnlay(k) = exp(-exp_min)
3393 53991881 : alp = alpha(ws,mu0n,gs,lm)
3394 53991881 : gam = agamm(ws,mu0n,gs,lm)
3395 53991881 : apg = alp + gam
3396 53991881 : amg = alp - gam
3397 53991881 : rdir(k) = apg*rdif_a(k) + amg*(tdif_a(k)*trnlay(k) - c1)
3398 53991881 : tdir(k) = apg*tdif_a(k) + (amg* rdif_a(k)-apg+c1)*trnlay(k)
3399 :
3400 : ! recalculate rdif,tdif using direct angular integration over rdir,tdir,
3401 : ! since Delta-Eddington rdif formula is not well-behaved (it is usually
3402 : ! biased low and can even be negative); use ngmax angles and gaussian
3403 : ! integration for most accuracy:
3404 53991881 : R1 = rdif_a(k) ! use R1 as temporary
3405 53991881 : T1 = tdif_a(k) ! use T1 as temporary
3406 53991881 : swt = c0
3407 53991881 : smr = c0
3408 53991881 : smt = c0
3409 485926929 : do ng=1,ngmax
3410 431935048 : mu = gauspt(ng)
3411 431935048 : gwt = gauswt(ng)
3412 431935048 : swt = swt + mu*gwt
3413 431935048 : exp_min = min(exp_argmax,ts/mu)
3414 431935048 : trn = exp(-exp_min)
3415 431935048 : alp = alpha(ws,mu,gs,lm)
3416 431935048 : gam = agamm(ws,mu,gs,lm)
3417 431935048 : apg = alp + gam
3418 431935048 : amg = alp - gam
3419 431935048 : rdr = apg*R1 + amg*T1*trn - amg
3420 431935048 : tdr = apg*T1 + amg*R1*trn - apg*trn + trn
3421 431935048 : smr = smr + mu*rdr*gwt
3422 485926929 : smt = smt + mu*tdr*gwt
3423 : enddo ! ng
3424 53991881 : rdif_a(k) = smr/swt
3425 53991881 : tdif_a(k) = smt/swt
3426 :
3427 : ! homogeneous layer
3428 53991881 : rdif_b(k) = rdif_a(k)
3429 53991881 : tdif_b(k) = tdif_a(k)
3430 :
3431 : ! add fresnel layer to top of desired layer if either
3432 : ! air or snow overlies ice; we ignore refraction in ice
3433 : ! if a melt pond overlies it:
3434 :
3435 53991881 : if( k == kfrsnl ) then
3436 : ! compute fresnel reflection and transmission amplitudes
3437 : ! for two polarizations: 1=perpendicular and 2=parallel to
3438 : ! the plane containing incident, reflected and refracted rays.
3439 : R1 = (mu0 - refindx*mu0n) / &
3440 5827398 : (mu0 + refindx*mu0n)
3441 : R2 = (refindx*mu0 - mu0n) / &
3442 5827398 : (refindx*mu0 + mu0n)
3443 : T1 = c2*mu0 / &
3444 5827398 : (mu0 + refindx*mu0n)
3445 : T2 = c2*mu0 / &
3446 5827398 : (refindx*mu0 + mu0n)
3447 :
3448 : ! unpolarized light for direct beam
3449 5827398 : Rf_dir_a = p5 * (R1*R1 + R2*R2)
3450 5827398 : Tf_dir_a = p5 * (T1*T1 + T2*T2)*refindx*mu0n/mu0
3451 :
3452 : ! precalculated diffuse reflectivities and transmissivities
3453 : ! for incident radiation above and below fresnel layer, using
3454 : ! the direct albedos and accounting for complete internal
3455 : ! reflection from below; precalculated because high order
3456 : ! number of gaussian points (~256) is required for convergence:
3457 :
3458 : ! above
3459 5827398 : Rf_dif_a = cp063
3460 5827398 : Tf_dif_a = c1 - Rf_dif_a
3461 : ! below
3462 5827398 : Rf_dif_b = cp455
3463 5827398 : Tf_dif_b = c1 - Rf_dif_b
3464 :
3465 : ! the k = kfrsnl layer properties are updated to combined
3466 : ! the fresnel (refractive) layer, always taken to be above
3467 : ! the present layer k (i.e. be the top interface):
3468 :
3469 5827398 : rintfc = c1 / (c1-Rf_dif_b*rdif_a(k))
3470 2288038 : tdir(k) = Tf_dir_a*tdir(k) + &
3471 2288038 : Tf_dir_a*rdir(k) * &
3472 5827398 : Rf_dif_b*rintfc*tdif_a(k)
3473 2288038 : rdir(k) = Rf_dir_a + &
3474 2288038 : Tf_dir_a*rdir(k) * &
3475 5827398 : rintfc*Tf_dif_b
3476 2288038 : rdif_a(k) = Rf_dif_a + &
3477 2288038 : Tf_dif_a*rdif_a(k) * &
3478 5827398 : rintfc*Tf_dif_b
3479 2288038 : rdif_b(k) = rdif_b(k) + &
3480 2288038 : tdif_b(k)*Rf_dif_b * &
3481 5827398 : rintfc*tdif_a(k)
3482 5827398 : tdif_a(k) = tdif_a(k)*rintfc*Tf_dif_a
3483 5827398 : tdif_b(k) = tdif_b(k)*rintfc*Tf_dif_b
3484 :
3485 : ! update trnlay to include fresnel transmission
3486 5827398 : trnlay(k) = Tf_dir_a*trnlay(k)
3487 :
3488 : endif ! k = kfrsnl
3489 :
3490 : endif ! trntdr(k) > trmin
3491 :
3492 : ! initialize current layer properties to zero; only if total
3493 : ! transmission to the top interface of the current layer exceeds the
3494 : ! minimum, will these values be computed below:
3495 : ! Calculate the solar beam transmission, total transmission, and
3496 : ! reflectivity for diffuse radiation from below at interface k,
3497 : ! the top of the current layer k:
3498 : !
3499 : ! layers interface
3500 : !
3501 : ! --------------------- k-1
3502 : ! k-1
3503 : ! --------------------- k
3504 : ! k
3505 : ! ---------------------
3506 : ! For k = klevp
3507 : ! note that we ignore refraction between sea ice and underlying ocean:
3508 : !
3509 : ! layers interface
3510 : !
3511 : ! --------------------- k-1
3512 : ! k-1
3513 : ! --------------------- k
3514 : ! \\\\\\\ ocean \\\\\\\
3515 :
3516 103822908 : trndir(k+1) = trndir(k)*trnlay(k)
3517 103822908 : refkm1 = c1/(c1 - rdndif(k)*rdif_a(k))
3518 103822908 : tdrrdir = trndir(k)*rdir(k)
3519 103822908 : tdndif = trntdr(k) - trndir(k)
3520 39146466 : trntdr(k+1) = trndir(k)*tdir(k) + &
3521 142969374 : (tdndif + tdrrdir*rdndif(k))*refkm1*tdif_a(k)
3522 39146466 : rdndif(k+1) = rdif_b(k) + &
3523 142969374 : (tdif_b(k)*rdndif(k)*refkm1*tdif_a(k))
3524 113836044 : trndif(k+1) = trndif(k)*refkm1*tdif_a(k)
3525 :
3526 : enddo ! k end main level loop
3527 :
3528 : ! compute reflectivity to direct and diffuse radiation for layers
3529 : ! below by adding succesive layers starting from the underlying
3530 : ! ocean and working upwards:
3531 : !
3532 : ! layers interface
3533 : !
3534 : ! --------------------- k
3535 : ! k
3536 : ! --------------------- k+1
3537 : ! k+1
3538 : ! ---------------------
3539 :
3540 10013136 : rupdir(klevp) = albodr
3541 10013136 : rupdif(klevp) = albodf
3542 :
3543 113836044 : do k=klev,0,-1
3544 : ! interface scattering
3545 103822908 : refkp1 = c1/( c1 - rdif_b(k)*rupdif(k+1))
3546 : ! dir from top layer plus exp tran ref from lower layer, interface
3547 : ! scattered and tran thru top layer from below, plus diff tran ref
3548 : ! from lower layer with interface scattering tran thru top from below
3549 39146466 : rupdir(k) = rdir(k) &
3550 78292932 : + ( trnlay(k) *rupdir(k+1) &
3551 142969374 : + (tdir(k)-trnlay(k))*rupdif(k+1))*refkp1*tdif_b(k)
3552 : ! dif from top layer from above, plus dif tran upwards reflected and
3553 : ! interface scattered which tran top from below
3554 113836044 : rupdif(k) = rdif_a(k) + tdif_a(k)*rupdif(k+1)*refkp1*tdif_b(k)
3555 : enddo ! k
3556 :
3557 10013136 : end subroutine solution_dEdd
3558 :
3559 : !=======================================================================
3560 : !
3561 : ! Set snow horizontal coverage, density and grain radius diagnostically
3562 : ! for the Delta-Eddington solar radiation method.
3563 : !
3564 : ! author: Bruce P. Briegleb, NCAR
3565 : ! 2013: E Hunke merged with NCAR version
3566 :
3567 3900730 : subroutine shortwave_dEdd_set_snow(nslyr, R_snw, &
3568 : dT_mlt, rsnw_mlt, &
3569 : aice, vsno, &
3570 : Tsfc, fs, &
3571 : hs0, hs, &
3572 3900730 : rhosnw, rsnw)
3573 :
3574 : integer (kind=int_kind), intent(in) :: &
3575 : nslyr ! number of snow layers
3576 :
3577 : real (kind=dbl_kind), intent(in) :: &
3578 : R_snw , & ! snow tuning parameter; +1 > ~.01 change in broadband albedo
3579 : dT_mlt, & ! change in temp for non-melt to melt snow grain radius change (C)
3580 : rsnw_mlt ! maximum melting snow grain radius (10^-6 m)
3581 :
3582 : real (kind=dbl_kind), intent(in) :: &
3583 : aice , & ! concentration of ice
3584 : vsno , & ! volume of snow
3585 : Tsfc , & ! surface temperature
3586 : hs0 ! snow depth for transition to bare sea ice (m)
3587 :
3588 : real (kind=dbl_kind), intent(inout) :: &
3589 : fs , & ! horizontal coverage of snow
3590 : hs ! snow depth
3591 :
3592 : real (kind=dbl_kind), dimension (:), intent(out) :: &
3593 : rhosnw , & ! density in snow layer (kg/m3)
3594 : rsnw ! grain radius in snow layer (micro-meters)
3595 :
3596 : ! local variables
3597 :
3598 : integer (kind=int_kind) :: &
3599 : ks ! snow vertical index
3600 :
3601 : real (kind=dbl_kind) :: &
3602 1405899 : fT , & ! piecewise linear function of surface temperature
3603 1405899 : dTs , & ! difference of Tsfc and Timelt
3604 1405899 : rsnw_nm ! actual used nonmelt snow grain radius (micro-meters)
3605 :
3606 : real (kind=dbl_kind), parameter :: &
3607 : ! units for the following are 1.e-6 m (micro-meters)
3608 : rsnw_fresh = 100._dbl_kind, & ! freshly-fallen snow grain radius
3609 : rsnw_nonmelt = 500._dbl_kind, & ! nonmelt snow grain radius
3610 : rsnw_sig = 250._dbl_kind ! assumed sigma for snow grain radius
3611 :
3612 : character(len=*),parameter :: subname='(shortwave_dEdd_set_snow)'
3613 :
3614 : !-----------------------------------------------------------------------
3615 :
3616 : ! set snow horizontal fraction
3617 3900730 : hs = vsno / aice
3618 :
3619 3900730 : if (hs >= hs_min) then
3620 2908808 : fs = c1
3621 2908808 : if (hs0 > puny) fs = min(hs/hs0, c1)
3622 : endif
3623 :
3624 : ! bare ice, temperature dependence
3625 3900730 : dTs = Timelt - Tsfc
3626 3900730 : fT = -min(dTs/dT_mlt-c1,c0)
3627 : ! tune nonmelt snow grain radius if desired: note that
3628 : ! the sign is negative so that if R_snw is 1, then the
3629 : ! snow grain radius is reduced and thus albedo increased.
3630 3900730 : rsnw_nm = rsnw_nonmelt - R_snw*rsnw_sig
3631 3900730 : rsnw_nm = max(rsnw_nm, rsnw_fresh)
3632 3900730 : rsnw_nm = min(rsnw_nm, rsnw_mlt)
3633 8710492 : do ks = 1, nslyr
3634 : ! snow density ccsm3 constant value
3635 4809762 : rhosnw(ks) = rhos
3636 : ! snow grain radius between rsnw_nonmelt and rsnw_mlt
3637 4809762 : rsnw(ks) = rsnw_nm + (rsnw_mlt-rsnw_nm)*fT
3638 4809762 : rsnw(ks) = max(rsnw(ks), rsnw_fresh)
3639 8710492 : rsnw(ks) = min(rsnw(ks), rsnw_mlt)
3640 : enddo ! ks
3641 :
3642 3900730 : end subroutine shortwave_dEdd_set_snow
3643 :
3644 : !=======================================================================
3645 : !
3646 : ! Set pond fraction and depth diagnostically for
3647 : ! the Delta-Eddington solar radiation method.
3648 : !
3649 : ! author: Bruce P. Briegleb, NCAR
3650 : ! 2013: E Hunke merged with NCAR version
3651 :
3652 72399 : subroutine shortwave_dEdd_set_pond(Tsfc, &
3653 : fs, fp, &
3654 : hp)
3655 :
3656 : real (kind=dbl_kind), intent(in) :: &
3657 : Tsfc , & ! surface temperature
3658 : fs ! horizontal coverage of snow
3659 :
3660 : real (kind=dbl_kind), intent(out) :: &
3661 : fp , & ! pond fractional coverage (0 to 1)
3662 : hp ! pond depth (m)
3663 :
3664 : ! local variables
3665 :
3666 : real (kind=dbl_kind) :: &
3667 26280 : fT , & ! piecewise linear function of surface temperature
3668 26280 : dTs ! difference of Tsfc and Timelt
3669 :
3670 : real (kind=dbl_kind), parameter :: &
3671 : dT_pnd = c1 ! change in temp for pond fraction and depth
3672 :
3673 : character(len=*),parameter :: subname='(shortwave_dEdd_set_pond)'
3674 :
3675 : !-----------------------------------------------------------------------
3676 :
3677 : ! bare ice, temperature dependence
3678 72399 : dTs = Timelt - Tsfc
3679 72399 : fT = -min(dTs/dT_pnd-c1,c0)
3680 : ! pond
3681 72399 : fp = 0.3_dbl_kind*fT*(c1-fs)
3682 72399 : hp = 0.3_dbl_kind*fT*(c1-fs)
3683 :
3684 72399 : end subroutine shortwave_dEdd_set_pond
3685 :
3686 : ! End Delta-Eddington shortwave method
3687 :
3688 : !=======================================================================
3689 : !
3690 : ! authors Nicole Jeffery, LANL
3691 :
3692 0 : subroutine compute_shortwave_trcr(nslyr, &
3693 0 : bgcN, zaero, &
3694 0 : trcrn_bgcsw, &
3695 0 : sw_grid, hin, &
3696 : hbri, &
3697 : nilyr, nblyr, &
3698 0 : i_grid, &
3699 : skl_bgc, z_tracers )
3700 :
3701 : integer (kind=int_kind), intent(in) :: &
3702 : nslyr ! number of snow layers
3703 :
3704 : integer (kind=int_kind), intent(in) :: &
3705 : nblyr , & ! number of bio layers
3706 : nilyr ! number of ice layers
3707 :
3708 : real (kind=dbl_kind), dimension (:), intent(in) :: &
3709 : bgcN , & ! Nit tracer
3710 : zaero ! zaero tracer
3711 :
3712 : real (kind=dbl_kind), dimension (:), intent(out):: &
3713 : trcrn_bgcsw ! ice on shortwave grid tracers
3714 :
3715 : real (kind=dbl_kind), dimension (:), intent(in) :: &
3716 : sw_grid , & !
3717 : i_grid ! CICE bio grid
3718 :
3719 : real(kind=dbl_kind), intent(in) :: &
3720 : hin , & ! CICE ice thickness
3721 : hbri ! brine height
3722 :
3723 : logical (kind=log_kind), intent(in) :: &
3724 : skl_bgc , & ! skeletal layer bgc
3725 : z_tracers ! zbgc
3726 :
3727 : ! local variables
3728 :
3729 : integer (kind=int_kind) :: k, n, nn
3730 :
3731 : real (kind=dbl_kind), dimension (ntrcr+2) :: &
3732 0 : trtmp0, & ! temporary, remapped tracers
3733 0 : trtmp
3734 :
3735 : real (kind=dbl_kind), dimension (nilyr+1):: &
3736 0 : icegrid ! correct for large ice surface layers
3737 :
3738 : real (kind=dbl_kind):: &
3739 0 : top_conc ! 1% (min_bgc) of surface concentration
3740 : ! when hin > hbri: just used in sw calculation
3741 :
3742 : character(len=*),parameter :: subname='(compute_shortwave_trcr)'
3743 :
3744 : !-----------------------------------------------------------------
3745 : ! Compute aerosols and algal chlorophyll on shortwave grid
3746 : !-----------------------------------------------------------------
3747 :
3748 0 : trtmp0(:) = c0
3749 0 : trtmp(:) = c0
3750 0 : trcrn_bgcsw(:) = c0
3751 :
3752 0 : do k = 1,nilyr+1
3753 0 : icegrid(k) = sw_grid(k)
3754 : enddo
3755 0 : if (sw_grid(1)*hin*c2 > hi_ssl) then
3756 0 : icegrid(1) = hi_ssl/c2/hin
3757 : endif
3758 :
3759 0 : if (z_tracers) then
3760 0 : if (tr_bgc_N) then
3761 0 : if (size(bgcN) < n_algae*(nblyr+3)) then
3762 0 : call icepack_warnings_add(subname//' ERROR: size(bgcN) too small')
3763 0 : call icepack_warnings_setabort(.true.,__FILE__,__LINE__)
3764 0 : return
3765 : endif
3766 :
3767 0 : do k = 1, nblyr+1
3768 0 : do n = 1, n_algae
3769 0 : trtmp0(nt_bgc_N(1) + k-1) = trtmp0(nt_bgc_N(1) + k-1) + &
3770 0 : R_chl2N(n)*F_abs_chl(n)*bgcN(nt_bgc_N(n)-nt_bgc_N(1)+1 + k-1)
3771 : enddo ! n
3772 : enddo ! k
3773 :
3774 0 : top_conc = trtmp0(nt_bgc_N(1))*min_bgc
3775 : call remap_zbgc (nilyr+1, &
3776 : nt_bgc_N(1), &
3777 0 : trtmp0(1:ntrcr ), &
3778 0 : trtmp (1:ntrcr+2), &
3779 : 1, nblyr+1, &
3780 : hin, hbri, &
3781 0 : icegrid(1:nilyr+1), &
3782 0 : i_grid(1:nblyr+1), top_conc )
3783 0 : if (icepack_warnings_aborted(subname)) return
3784 :
3785 0 : do k = 1, nilyr+1
3786 0 : trcrn_bgcsw(nlt_chl_sw+nslyr+k) = trtmp(nt_bgc_N(1) + k-1)
3787 : enddo ! k
3788 :
3789 0 : do n = 1, n_algae ! snow contribution
3790 0 : trcrn_bgcsw(nlt_chl_sw)= trcrn_bgcsw(nlt_chl_sw) &
3791 0 : + R_chl2N(n)*F_abs_chl(n)*bgcN(nt_bgc_N(n)-nt_bgc_N(1)+1+nblyr+1)
3792 : ! snow surface layer
3793 0 : trcrn_bgcsw(nlt_chl_sw+1:nlt_chl_sw+nslyr) = &
3794 0 : trcrn_bgcsw(nlt_chl_sw+1:nlt_chl_sw+nslyr) &
3795 0 : + R_chl2N(n)*F_abs_chl(n)*bgcN(nt_bgc_N(n)-nt_bgc_N(1)+1+nblyr+2)
3796 : ! only 1 snow layer in zaero
3797 : enddo ! n
3798 : endif ! tr_bgc_N
3799 :
3800 0 : if (tr_zaero) then
3801 0 : if (size(zaero) < n_zaero*(nblyr+3)) then
3802 0 : call icepack_warnings_add(subname//' ERROR: size(zaero) too small')
3803 0 : call icepack_warnings_setabort(.true.,__FILE__,__LINE__)
3804 0 : return
3805 : endif
3806 :
3807 0 : do n = 1, n_zaero
3808 :
3809 0 : trtmp0(:) = c0
3810 0 : trtmp(:) = c0
3811 :
3812 0 : do k = 1, nblyr+1
3813 0 : trtmp0(nt_zaero(n) + k-1) = zaero(nt_zaero(n)-nt_zaero(1)+1+k-1)
3814 : enddo
3815 :
3816 0 : top_conc = trtmp0(nt_zaero(n))*min_bgc
3817 : call remap_zbgc (nilyr+1, &
3818 0 : nt_zaero(n), &
3819 0 : trtmp0(1:ntrcr ), &
3820 0 : trtmp (1:ntrcr+2), &
3821 : 1, nblyr+1, &
3822 : hin, hbri, &
3823 0 : icegrid(1:nilyr+1), &
3824 0 : i_grid(1:nblyr+1), top_conc )
3825 0 : if (icepack_warnings_aborted(subname)) return
3826 :
3827 0 : do k = 1,nilyr+1
3828 0 : trcrn_bgcsw(nlt_zaero_sw(n)+nslyr+k) = trtmp(nt_zaero(n) + k-1)
3829 : enddo
3830 0 : trcrn_bgcsw(nlt_zaero_sw(n))= zaero(nt_zaero(n)-nt_zaero(1)+1+nblyr+1) !snow ssl
3831 0 : trcrn_bgcsw(nlt_zaero_sw(n)+1:nlt_zaero_sw(n)+nslyr)= zaero(nt_zaero(n)-nt_zaero(1)+1+nblyr+2)
3832 : enddo ! n
3833 : endif ! tr_zaero
3834 0 : elseif (skl_bgc) then
3835 :
3836 0 : do nn = 1,n_algae
3837 0 : trcrn_bgcsw(nbtrcr_sw) = trcrn_bgcsw(nbtrcr_sw) &
3838 0 : + F_abs_chl(nn)*R_chl2N(nn) &
3839 0 : * bgcN(nt_bgc_N(nn)-nt_bgc_N(1)+1)*sk_l/hin &
3840 0 : * real(nilyr,kind=dbl_kind)
3841 : enddo
3842 :
3843 : endif
3844 : end subroutine compute_shortwave_trcr
3845 :
3846 : !=======================================================================
3847 : !autodocument_start icepack_prep_radiation
3848 : ! Scales radiation fields computed on the previous time step.
3849 : !
3850 : ! authors: Elizabeth Hunke, LANL
3851 :
3852 1405200 : subroutine icepack_prep_radiation (ncat, nilyr, nslyr, &
3853 1405200 : aice, aicen, &
3854 : swvdr, swvdf, &
3855 : swidr, swidf, &
3856 : alvdr_ai, alvdf_ai, &
3857 : alidr_ai, alidf_ai, &
3858 : scale_factor, &
3859 1405200 : fswsfcn, fswintn, &
3860 1405200 : fswthrun, &
3861 1405200 : fswthrun_vdr, &
3862 1405200 : fswthrun_vdf, &
3863 1405200 : fswthrun_idr, &
3864 1405200 : fswthrun_idf, &
3865 1405200 : fswpenln, &
3866 1405200 : Sswabsn, Iswabsn)
3867 :
3868 : integer (kind=int_kind), intent(in) :: &
3869 : ncat , & ! number of ice thickness categories
3870 : nilyr , & ! number of ice layers
3871 : nslyr ! number of snow layers
3872 :
3873 : real (kind=dbl_kind), intent(in) :: &
3874 : aice , & ! ice area fraction
3875 : swvdr , & ! sw down, visible, direct (W/m^2)
3876 : swvdf , & ! sw down, visible, diffuse (W/m^2)
3877 : swidr , & ! sw down, near IR, direct (W/m^2)
3878 : swidf , & ! sw down, near IR, diffuse (W/m^2)
3879 : ! grid-box-mean albedos aggregated over categories (if calc_Tsfc)
3880 : alvdr_ai , & ! visible, direct (fraction)
3881 : alidr_ai , & ! near-ir, direct (fraction)
3882 : alvdf_ai , & ! visible, diffuse (fraction)
3883 : alidf_ai ! near-ir, diffuse (fraction)
3884 :
3885 : real (kind=dbl_kind), dimension(:), intent(in) :: &
3886 : aicen ! ice area fraction in each category
3887 :
3888 : real (kind=dbl_kind), intent(inout) :: &
3889 : scale_factor ! shortwave scaling factor, ratio new:old
3890 :
3891 : real (kind=dbl_kind), dimension(:), intent(inout) :: &
3892 : fswsfcn , & ! SW absorbed at ice/snow surface (W m-2)
3893 : fswintn , & ! SW absorbed in ice interior, below surface (W m-2)
3894 : fswthrun ! SW through ice to ocean (W/m^2)
3895 :
3896 : real (kind=dbl_kind), dimension(:), intent(inout), optional :: &
3897 : fswthrun_vdr , & ! vis dir SW through ice to ocean (W/m^2)
3898 : fswthrun_vdf , & ! vis dif SW through ice to ocean (W/m^2)
3899 : fswthrun_idr , & ! nir dir SW through ice to ocean (W/m^2)
3900 : fswthrun_idf ! nir dif SW through ice to ocean (W/m^2)
3901 :
3902 : real (kind=dbl_kind), dimension(:,:), intent(inout) :: &
3903 : fswpenln , & ! visible SW entering ice layers (W m-2)
3904 : Iswabsn , & ! SW radiation absorbed in ice layers (W m-2)
3905 : Sswabsn ! SW radiation absorbed in snow layers (W m-2)
3906 :
3907 : !autodocument_end
3908 :
3909 : ! local variables
3910 :
3911 : integer (kind=int_kind) :: &
3912 : k , & ! vertical index
3913 : n ! thickness category index
3914 :
3915 509328 : real (kind=dbl_kind) :: netsw
3916 :
3917 : character(len=*),parameter :: subname='(icepack_prep_radiation)'
3918 :
3919 : !-----------------------------------------------------------------
3920 : ! Compute netsw scaling factor (new netsw / old netsw)
3921 : !-----------------------------------------------------------------
3922 :
3923 1405200 : if (aice > c0 .and. scale_factor > puny) then
3924 : netsw = swvdr*(c1 - alvdr_ai) &
3925 : + swvdf*(c1 - alvdf_ai) &
3926 : + swidr*(c1 - alidr_ai) &
3927 763490 : + swidf*(c1 - alidf_ai)
3928 763490 : scale_factor = netsw / scale_factor
3929 : else
3930 641710 : scale_factor = c1
3931 : endif
3932 :
3933 8045088 : do n = 1, ncat
3934 :
3935 8045088 : if (aicen(n) > puny) then
3936 :
3937 : !-----------------------------------------------------------------
3938 : ! Scale absorbed solar radiation for change in net shortwave
3939 : !-----------------------------------------------------------------
3940 :
3941 4491434 : fswsfcn(n) = scale_factor*fswsfcn (n)
3942 4491434 : fswintn(n) = scale_factor*fswintn (n)
3943 4491434 : fswthrun(n) = scale_factor*fswthrun(n)
3944 4491434 : if (present(fswthrun_vdr)) fswthrun_vdr(n) = scale_factor*fswthrun_vdr(n)
3945 4491434 : if (present(fswthrun_vdf)) fswthrun_vdf(n) = scale_factor*fswthrun_vdf(n)
3946 4491434 : if (present(fswthrun_idr)) fswthrun_idr(n) = scale_factor*fswthrun_idr(n)
3947 4491434 : if (present(fswthrun_idf)) fswthrun_idf(n) = scale_factor*fswthrun_idf(n)
3948 38603268 : do k = 1,nilyr+1
3949 38603268 : fswpenln(k,n) = scale_factor*fswpenln(k,n)
3950 : enddo !k
3951 9891780 : do k=1,nslyr
3952 9891780 : Sswabsn(k,n) = scale_factor*Sswabsn(k,n)
3953 : enddo
3954 34111834 : do k=1,nilyr
3955 34111834 : Iswabsn(k,n) = scale_factor*Iswabsn(k,n)
3956 : enddo
3957 :
3958 : endif
3959 : enddo ! ncat
3960 :
3961 1405200 : end subroutine icepack_prep_radiation
3962 :
3963 : !=======================================================================
3964 : !autodocument_start icepack_step_radiation
3965 : ! Computes radiation fields
3966 : !
3967 : ! authors: William H. Lipscomb, LANL
3968 : ! David Bailey, NCAR
3969 : ! Elizabeth C. Hunke, LANL
3970 :
3971 1054038 : subroutine icepack_step_radiation (dt, ncat, &
3972 : nblyr, &
3973 : nilyr, nslyr, &
3974 : dEdd_algae, &
3975 1054038 : swgrid, igrid, &
3976 1054038 : fbri, &
3977 1054038 : aicen, vicen, &
3978 1054038 : vsnon, Tsfcn, &
3979 1054038 : alvln, apndn, &
3980 1054038 : hpndn, ipndn, &
3981 1054038 : aeron, &
3982 1054038 : bgcNn, zaeron, &
3983 1054038 : trcrn_bgcsw, &
3984 : TLAT, TLON, &
3985 0 : calendar_type, &
3986 : days_per_year, &
3987 : nextsw_cday, &
3988 : yday, sec, &
3989 1054038 : kaer_tab, waer_tab, &
3990 1054038 : gaer_tab, &
3991 1054038 : kaer_bc_tab, &
3992 1054038 : waer_bc_tab, &
3993 1054038 : gaer_bc_tab, &
3994 1054038 : bcenh, &
3995 : modal_aero, &
3996 : swvdr, swvdf, &
3997 : swidr, swidf, &
3998 : coszen, fsnow, &
3999 2108076 : alvdrn, alvdfn, &
4000 2108076 : alidrn, alidfn, &
4001 1054038 : fswsfcn, fswintn, &
4002 1054038 : fswthrun, &
4003 1054038 : fswthrun_vdr, &
4004 1054038 : fswthrun_vdf, &
4005 1054038 : fswthrun_idr, &
4006 1054038 : fswthrun_idf, &
4007 1054038 : fswpenln, &
4008 1054038 : Sswabsn, Iswabsn, &
4009 1054038 : albicen, albsnon, &
4010 1054038 : albpndn, apeffn, &
4011 1054038 : snowfracn, &
4012 1054038 : dhsn, ffracn, &
4013 : l_print_point, &
4014 : initonly)
4015 :
4016 : integer (kind=int_kind), intent(in) :: &
4017 : ncat , & ! number of ice thickness categories
4018 : nilyr , & ! number of ice layers
4019 : nslyr , & ! number of snow layers
4020 : nblyr ! number of bgc layers
4021 :
4022 : real (kind=dbl_kind), intent(in) :: &
4023 : dt , & ! time step (s)
4024 : swvdr , & ! sw down, visible, direct (W/m^2)
4025 : swvdf , & ! sw down, visible, diffuse (W/m^2)
4026 : swidr , & ! sw down, near IR, direct (W/m^2)
4027 : swidf , & ! sw down, near IR, diffuse (W/m^2)
4028 : fsnow , & ! snowfall rate (kg/m^2 s)
4029 : TLAT, TLON ! latitude and longitude (radian)
4030 :
4031 : character (len=char_len), intent(in) :: &
4032 : calendar_type ! differentiates Gregorian from other calendars
4033 :
4034 : integer (kind=int_kind), intent(in) :: &
4035 : days_per_year, & ! number of days in one year
4036 : sec ! elapsed seconds into date
4037 :
4038 : real (kind=dbl_kind), intent(in) :: &
4039 : nextsw_cday , & ! julian day of next shortwave calculation
4040 : yday ! day of the year
4041 :
4042 : real (kind=dbl_kind), intent(inout) :: &
4043 : coszen ! cosine solar zenith angle, < 0 for sun below horizon
4044 :
4045 : real (kind=dbl_kind), dimension (:), intent(in) :: &
4046 : igrid ! biology vertical interface points
4047 :
4048 : real (kind=dbl_kind), dimension (:), intent(in) :: &
4049 : swgrid ! grid for ice tracers used in dEdd scheme
4050 :
4051 : real (kind=dbl_kind), dimension(:,:), intent(in) :: &
4052 : kaer_tab, & ! aerosol mass extinction cross section (m2/kg)
4053 : waer_tab, & ! aerosol single scatter albedo (fraction)
4054 : gaer_tab ! aerosol asymmetry parameter (cos(theta))
4055 :
4056 : real (kind=dbl_kind), dimension(:,:), intent(in) :: &
4057 : kaer_bc_tab, & ! aerosol mass extinction cross section (m2/kg)
4058 : waer_bc_tab, & ! aerosol single scatter albedo (fraction)
4059 : gaer_bc_tab ! aerosol asymmetry parameter (cos(theta))
4060 :
4061 : real (kind=dbl_kind), dimension(:,:,:), intent(in) :: &
4062 : bcenh
4063 :
4064 : real (kind=dbl_kind), dimension(:), intent(in) :: &
4065 : aicen , & ! ice area fraction in each category
4066 : vicen , & ! ice volume in each category (m)
4067 : vsnon , & ! snow volume in each category (m)
4068 : Tsfcn , & ! surface temperature (deg C)
4069 : alvln , & ! level-ice area fraction
4070 : apndn , & ! pond area fraction
4071 : hpndn , & ! pond depth (m)
4072 : ipndn , & ! pond refrozen lid thickness (m)
4073 : fbri ! brine fraction
4074 :
4075 : real(kind=dbl_kind), dimension(:,:), intent(in) :: &
4076 : aeron , & ! aerosols (kg/m^3)
4077 : bgcNn , & ! bgc Nit tracers
4078 : zaeron ! bgcz aero tracers
4079 :
4080 : real(kind=dbl_kind), dimension(:,:), intent(inout) :: &
4081 : trcrn_bgcsw ! zaerosols (kg/m^3) and chla (mg/m^3)
4082 :
4083 : real (kind=dbl_kind), dimension(:), intent(inout) :: &
4084 : alvdrn , & ! visible, direct albedo (fraction)
4085 : alidrn , & ! near-ir, direct (fraction)
4086 : alvdfn , & ! visible, diffuse (fraction)
4087 : alidfn , & ! near-ir, diffuse (fraction)
4088 : fswsfcn , & ! SW absorbed at ice/snow surface (W m-2)
4089 : fswintn , & ! SW absorbed in ice interior, below surface (W m-2)
4090 : fswthrun , & ! SW through ice to ocean (W/m^2)
4091 : snowfracn , & ! snow fraction on each category
4092 : dhsn , & ! depth difference for snow on sea ice and pond ice
4093 : ffracn , & ! fraction of fsurfn used to melt ipond
4094 : ! albedo components for history
4095 : albicen , & ! bare ice
4096 : albsnon , & ! snow
4097 : albpndn , & ! pond
4098 : apeffn ! effective pond area used for radiation calculation
4099 :
4100 : real (kind=dbl_kind), dimension(:), intent(inout), optional :: &
4101 : fswthrun_vdr , & ! vis dir SW through ice to ocean (W/m^2)
4102 : fswthrun_vdf , & ! vis dif SW through ice to ocean (W/m^2)
4103 : fswthrun_idr , & ! nir dir SW through ice to ocean (W/m^2)
4104 : fswthrun_idf ! nir dif SW through ice to ocean (W/m^2)
4105 :
4106 : real (kind=dbl_kind), dimension(:,:), intent(inout) :: &
4107 : fswpenln , & ! visible SW entering ice layers (W m-2)
4108 : Iswabsn , & ! SW radiation absorbed in ice layers (W m-2)
4109 : Sswabsn ! SW radiation absorbed in snow layers (W m-2)
4110 :
4111 : logical (kind=log_kind), intent(in) :: &
4112 : l_print_point, & ! flag for printing diagnostics
4113 : dEdd_algae , & ! .true. use prognostic chla in dEdd
4114 : modal_aero ! .true. use modal aerosol optical treatment
4115 :
4116 : logical (kind=log_kind), optional :: &
4117 : initonly ! flag to indicate init only, default is false
4118 :
4119 : !autodocument_end
4120 :
4121 : ! local variables
4122 :
4123 : integer (kind=int_kind) :: &
4124 : n ! thickness category index
4125 :
4126 : logical (kind=log_kind) :: &
4127 : linitonly ! local flag for initonly
4128 :
4129 : real(kind=dbl_kind) :: &
4130 382047 : hin, & ! Ice thickness (m)
4131 382047 : hbri ! brine thickness (m)
4132 :
4133 : real (kind=dbl_kind), dimension(:), allocatable :: &
4134 1054038 : l_fswthrun_vdr , & ! vis dir SW through ice to ocean (W/m^2)
4135 1054038 : l_fswthrun_vdf , & ! vis dif SW through ice to ocean (W/m^2)
4136 1054038 : l_fswthrun_idr , & ! nir dir SW through ice to ocean (W/m^2)
4137 1054038 : l_fswthrun_idf ! nir dif SW through ice to ocean (W/m^2)
4138 :
4139 : character(len=*),parameter :: subname='(icepack_step_radiation)'
4140 :
4141 1054038 : allocate(l_fswthrun_vdr(ncat))
4142 1054038 : allocate(l_fswthrun_vdf(ncat))
4143 1054038 : allocate(l_fswthrun_idr(ncat))
4144 1054038 : allocate(l_fswthrun_idf(ncat))
4145 :
4146 1054038 : hin = c0
4147 1054038 : hbri = c0
4148 1054038 : linitonly = .false.
4149 1054038 : if (present(initonly)) then
4150 138 : linitonly = initonly
4151 : endif
4152 :
4153 : ! Initialize
4154 6034608 : do n = 1, ncat
4155 4980570 : alvdrn (n) = c0
4156 4980570 : alidrn (n) = c0
4157 4980570 : alvdfn (n) = c0
4158 4980570 : alidfn (n) = c0
4159 4980570 : fswsfcn (n) = c0
4160 4980570 : fswintn (n) = c0
4161 6034608 : fswthrun(n) = c0
4162 : enddo ! ncat
4163 43272588 : fswpenln (:,:) = c0
4164 38292018 : Iswabsn (:,:) = c0
4165 12463278 : Sswabsn (:,:) = c0
4166 6034608 : trcrn_bgcsw(:,:) = c0
4167 :
4168 : ! Interpolate z-shortwave tracers to shortwave grid
4169 1054038 : if (dEdd_algae) then
4170 0 : do n = 1, ncat
4171 0 : if (aicen(n) .gt. puny) then
4172 0 : hin = vicen(n)/aicen(n)
4173 0 : hbri= fbri(n)*hin
4174 : call compute_shortwave_trcr(nslyr, &
4175 0 : bgcNn(:,n), &
4176 0 : zaeron(:,n), &
4177 0 : trcrn_bgcsw(:,n), &
4178 0 : swgrid, hin, &
4179 : hbri, &
4180 : nilyr, nblyr, &
4181 0 : igrid, &
4182 0 : skl_bgc, z_tracers )
4183 0 : if (icepack_warnings_aborted(subname)) return
4184 : endif
4185 : enddo
4186 : endif
4187 :
4188 1054038 : if (calc_Tsfc) then
4189 1054038 : if (trim(shortwave) == 'dEdd') then ! delta Eddington
4190 :
4191 : call run_dEdd(dt, ncat, &
4192 : dEdd_algae, &
4193 : nilyr, nslyr, &
4194 0 : aicen, vicen, &
4195 0 : vsnon, Tsfcn, &
4196 0 : alvln, apndn, &
4197 0 : hpndn, ipndn, &
4198 0 : aeron, kalg, &
4199 0 : trcrn_bgcsw, &
4200 : heat_capacity, &
4201 : TLAT, TLON, &
4202 : calendar_type,days_per_year, &
4203 : nextsw_cday, yday, &
4204 : sec, R_ice, &
4205 : R_pnd, R_snw, &
4206 : dT_mlt, rsnw_mlt, &
4207 : hs0, hs1, &
4208 : hp1, pndaspect, &
4209 0 : kaer_tab, waer_tab, &
4210 0 : gaer_tab, &
4211 0 : kaer_bc_tab, &
4212 0 : waer_bc_tab, &
4213 0 : gaer_bc_tab, &
4214 0 : bcenh, &
4215 : modal_aero, &
4216 : swvdr, swvdf, &
4217 : swidr, swidf, &
4218 : coszen, fsnow, &
4219 0 : alvdrn, alvdfn, &
4220 0 : alidrn, alidfn, &
4221 0 : fswsfcn, fswintn, &
4222 0 : fswthrun=fswthrun, &
4223 : fswthrun_vdr=l_fswthrun_vdr, &
4224 : fswthrun_vdf=l_fswthrun_vdf, &
4225 : fswthrun_idr=l_fswthrun_idr, &
4226 : fswthrun_idf=l_fswthrun_idf, &
4227 0 : fswpenln=fswpenln, &
4228 0 : Sswabsn=Sswabsn, &
4229 0 : Iswabsn=Iswabsn, &
4230 0 : albicen=albicen, &
4231 0 : albsnon=albsnon, &
4232 0 : albpndn=albpndn, &
4233 0 : apeffn=apeffn, &
4234 0 : snowfracn=snowfracn, &
4235 0 : dhsn=dhsn, &
4236 0 : ffracn=ffracn, &
4237 : l_print_point=l_print_point, &
4238 909228 : initonly=linitonly)
4239 909228 : if (icepack_warnings_aborted(subname)) return
4240 :
4241 144810 : elseif (trim(shortwave) == 'ccsm3') then
4242 :
4243 0 : call shortwave_ccsm3(aicen, vicen, &
4244 0 : vsnon, &
4245 0 : Tsfcn, &
4246 : swvdr, swvdf, &
4247 : swidr, swidf, &
4248 : heat_capacity, &
4249 : albedo_type, &
4250 : albicev, albicei, &
4251 : albsnowv, albsnowi, &
4252 : ahmax, &
4253 0 : alvdrn, alidrn, &
4254 0 : alvdfn, alidfn, &
4255 0 : fswsfcn, fswintn, &
4256 0 : fswthru=fswthrun, &
4257 : fswthru_vdr=l_fswthrun_vdr,&
4258 : fswthru_vdf=l_fswthrun_vdf,&
4259 : fswthru_idr=l_fswthrun_idr,&
4260 : fswthru_idf=l_fswthrun_idf,&
4261 0 : fswpenl=fswpenln, &
4262 0 : Iswabs=Iswabsn, &
4263 0 : Sswabs=Sswabsn, &
4264 0 : albin=albicen, &
4265 0 : albsn=albsnon, &
4266 : coszen=coszen, &
4267 : ncat=ncat, &
4268 144810 : nilyr=nilyr)
4269 144810 : if (icepack_warnings_aborted(subname)) return
4270 :
4271 : else
4272 :
4273 0 : call icepack_warnings_add(subname//' ERROR: shortwave '//trim(shortwave)//' unknown')
4274 0 : call icepack_warnings_setabort(.true.,__FILE__,__LINE__)
4275 0 : return
4276 :
4277 : endif ! shortwave
4278 :
4279 : else ! .not. calc_Tsfc
4280 :
4281 : ! Calculate effective pond area for HadGEM
4282 :
4283 0 : if (tr_pond_topo) then
4284 0 : do n = 1, ncat
4285 0 : apeffn(n) = c0
4286 0 : if (aicen(n) > puny) then
4287 : ! Lid effective if thicker than hp1
4288 0 : if (apndn(n)*aicen(n) > puny .and. ipndn(n) < hp1) then
4289 0 : apeffn(n) = apndn(n)
4290 : else
4291 0 : apeffn(n) = c0
4292 : endif
4293 0 : if (apndn(n) < puny) apeffn(n) = c0
4294 : endif
4295 : enddo ! ncat
4296 :
4297 : endif ! tr_pond_topo
4298 :
4299 : ! Initialize for safety
4300 0 : do n = 1, ncat
4301 0 : alvdrn(n) = c0
4302 0 : alidrn(n) = c0
4303 0 : alvdfn(n) = c0
4304 0 : alidfn(n) = c0
4305 0 : fswsfcn(n) = c0
4306 0 : fswintn(n) = c0
4307 0 : fswthrun(n) = c0
4308 : enddo ! ncat
4309 0 : Iswabsn(:,:) = c0
4310 0 : Sswabsn(:,:) = c0
4311 :
4312 : endif ! calc_Tsfc
4313 :
4314 6034608 : if (present(fswthrun_vdr)) fswthrun_vdr = l_fswthrun_vdr
4315 6034608 : if (present(fswthrun_vdf)) fswthrun_vdf = l_fswthrun_vdf
4316 6034608 : if (present(fswthrun_idr)) fswthrun_idr = l_fswthrun_idr
4317 6034608 : if (present(fswthrun_idf)) fswthrun_idf = l_fswthrun_idf
4318 :
4319 1054038 : deallocate(l_fswthrun_vdr)
4320 1054038 : deallocate(l_fswthrun_vdf)
4321 1054038 : deallocate(l_fswthrun_idr)
4322 1054038 : deallocate(l_fswthrun_idf)
4323 :
4324 1054038 : end subroutine icepack_step_radiation
4325 :
4326 : ! Delta-Eddington solution expressions
4327 :
4328 : !=======================================================================
4329 :
4330 485926929 : real(kind=dbl_kind) function alpha(w,uu,gg,e)
4331 :
4332 : real(kind=dbl_kind), intent(in) :: w, uu, gg, e
4333 :
4334 485926929 : alpha = p75*w*uu*((c1 + gg*(c1-w))/(c1 - e*e*uu*uu))
4335 :
4336 485926929 : end function alpha
4337 :
4338 : !=======================================================================
4339 :
4340 485926929 : real(kind=dbl_kind) function agamm(w,uu,gg,e)
4341 :
4342 : real(kind=dbl_kind), intent(in) :: w, uu, gg, e
4343 :
4344 485926929 : agamm = p5*w*((c1 + c3*gg*(c1-w)*uu*uu)/(c1-e*e*uu*uu))
4345 :
4346 485926929 : end function agamm
4347 :
4348 : !=======================================================================
4349 :
4350 53991881 : real(kind=dbl_kind) function n(uu,et)
4351 :
4352 : real(kind=dbl_kind), intent(in) :: uu, et
4353 :
4354 53991881 : n = ((uu+c1)*(uu+c1)/et ) - ((uu-c1)*(uu-c1)*et)
4355 :
4356 53991881 : end function n
4357 :
4358 : !=======================================================================
4359 :
4360 53991881 : real(kind=dbl_kind) function u(w,gg,e)
4361 :
4362 : real(kind=dbl_kind), intent(in) :: w, gg, e
4363 :
4364 53991881 : u = c1p5*(c1 - w*gg)/e
4365 :
4366 53991881 : end function u
4367 :
4368 : !=======================================================================
4369 :
4370 53991881 : real(kind=dbl_kind) function el(w,gg)
4371 :
4372 : real(kind=dbl_kind), intent(in) :: w, gg
4373 :
4374 53991881 : el = sqrt(c3*(c1-w)*(c1 - w*gg))
4375 :
4376 53991881 : end function el
4377 :
4378 : !=======================================================================
4379 :
4380 53991881 : real(kind=dbl_kind) function taus(w,f,t)
4381 :
4382 : real(kind=dbl_kind), intent(in) :: w, f, t
4383 :
4384 53991881 : taus = (c1 - w*f)*t
4385 :
4386 53991881 : end function taus
4387 :
4388 : !=======================================================================
4389 :
4390 53991881 : real(kind=dbl_kind) function omgs(w,f)
4391 :
4392 : real(kind=dbl_kind), intent(in) :: w, f
4393 :
4394 53991881 : omgs = (c1 - f)*w/(c1 - w*f)
4395 :
4396 53991881 : end function omgs
4397 :
4398 : !=======================================================================
4399 :
4400 53991881 : real(kind=dbl_kind) function asys(gg,f)
4401 :
4402 : real(kind=dbl_kind), intent(in) :: gg, f
4403 :
4404 53991881 : asys = (gg - f)/(c1 - f)
4405 :
4406 53991881 : end function asys
4407 :
4408 : !=======================================================================
4409 :
4410 : end module icepack_shortwave
4411 :
4412 : !=======================================================================
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