source: LMDZ6/trunk/libf/phylmd/ecrad/radiation/radiation_aerosol_optics.F90 @ 5423

Last change on this file since 5423 was 4853, checked in by idelkadi, 9 months ago

Ecrad update in LMDZ / Implementation of Ecrad double call in LMDZ

  • version 1.6.1 (commit 210d7911380f53a788c3cad73b3cf9b4e022ef87)
  • interface routines between lmdz and ecrad grouped in a new "lmdz" directory
  • double call method redesigned so as to go through the Ecrad initialization and configuration part only once for the entire simulation
  • clean-up in the read.F routine: delete unitules arguments
  • modification of default gas model in namelist (default: ECCKD)
File size: 48.7 KB
Line 
1! radiation_aerosol_optics.F90 - Computing aerosol optical properties
2!
3! (C) Copyright 2015- ECMWF.
4!
5! This software is licensed under the terms of the Apache Licence Version 2.0
6! which can be obtained at http://www.apache.org/licenses/LICENSE-2.0.
7!
8! In applying this licence, ECMWF does not waive the privileges and immunities
9! granted to it by virtue of its status as an intergovernmental organisation
10! nor does it submit to any jurisdiction.
11!
12! Author:  Robin Hogan
13! Email:   r.j.hogan@ecmwf.int
14!
15! Modifications
16!   2018-04-15  R. Hogan  Add "direct" option
17!   2020-11-14  R. Hogan  Add setup_general_aerosol_optics for ecCKD compatibility
18!   2022-03-27  R. Hogan  Add setup_general_aerosol_optics_legacy to use RRTM aerosol files with ecCKD
19!   2022-11-22  P. Ukkonen / R. Hogan  Optimizations to enhance vectorization
20
21#include "ecrad_config.h"
22
23module radiation_aerosol_optics
24
25  implicit none
26  public
27
28contains
29
30  ! Provides the elemental function "delta_eddington_extensive"
31#include "radiation_delta_eddington.h"
32
33  !---------------------------------------------------------------------
34  ! Load aerosol scattering data; this subroutine delegates to one
35  ! in radiation_aerosol_optics_data.F90
36  subroutine setup_aerosol_optics(config)
37
38    use parkind1,                      only : jprb
39    use yomhook,                       only : lhook, dr_hook, jphook
40    use radiation_config,              only : config_type
41    use radiation_aerosol_optics_data, only : aerosol_optics_type
42    use radiation_io,                  only : nulerr, radiation_abort
43
44    type(config_type), intent(inout) :: config
45
46    real(jphook) :: hook_handle
47
48    if (lhook) call dr_hook('radiation_aerosol_optics:setup_aerosol_optics',0,hook_handle)
49
50    if (config%n_aerosol_types > 0) then
51      ! Load data from file and prepare to map config%n_aerosol_types
52      ! aerosol types
53      if (config%use_general_aerosol_optics) then
54        ! Read file containing high spectral resolution optical
55        ! properties and average to the spectral intervals of the
56        ! current gas-optics scheme
57        call setup_general_aerosol_optics(config)
58      else
59        ! Read file containing optical properties already in the bands
60        ! of the gas-optics scheme
61        call config%aerosol_optics%setup(trim(config%aerosol_optics_file_name), &
62             &                           iverbose=config%iverbosesetup)
63      end if
64
65      call config%aerosol_optics%initialize_types(config%n_aerosol_types)
66
67      ! Check agreement in number of bands
68      if (config%n_bands_lw /= config%aerosol_optics%n_bands_lw) then
69        write(nulerr,'(a,i0,a,i0,a)') '*** Error: number of longwave bands (', &
70             &  config%n_bands_lw, ') does not match aerosol optics look-up table (', &
71             &  config%aerosol_optics%n_bands_lw, ')'
72        call radiation_abort()
73      end if
74      if (config%n_bands_sw /= config%aerosol_optics%n_bands_sw) then
75        write(nulerr,'(a)') '*** Error: number of shortwave bands does not match aerosol optics look-up table'
76        call radiation_abort()
77      end if
78
79      ! Map aerosol types to those loaded from the data file
80      call config%aerosol_optics%set_types(config%i_aerosol_type_map(1:config%n_aerosol_types))
81    end if
82
83    if (config%iverbosesetup >= 1) then
84      call config%aerosol_optics%print_description(config%i_aerosol_type_map(1:config%n_aerosol_types))
85    end if
86
87    if (lhook) call dr_hook('radiation_aerosol_optics:setup_aerosol_optics',1,hook_handle)
88
89  end subroutine setup_aerosol_optics
90
91
92  !---------------------------------------------------------------------
93  ! Read file containing high spectral resolution optical properties
94  ! and average to the spectral intervals of the current gas-optics
95  ! scheme
96  subroutine setup_general_aerosol_optics(config)
97
98    use parkind1,                      only : jprb
99    use yomhook,                       only : lhook, dr_hook, jphook
100#ifdef EASY_NETCDF_READ_MPI
101    use easy_netcdf_read_mpi,          only : netcdf_file
102#else
103    use easy_netcdf,                   only : netcdf_file
104#endif
105    use radiation_config,              only : config_type
106    use radiation_aerosol_optics_data, only : aerosol_optics_type
107    use radiation_spectral_definition, only : SolarReferenceTemperature, &
108         &                                    TerrestrialReferenceTemperature
109    use radiation_io,                  only : nulout
110
111    type(config_type), intent(inout), target :: config
112
113    ! The NetCDF file containing the aerosol optics data
114    type(netcdf_file)  :: file
115
116    ! Wavenumber points in NetCDF file
117    real(jprb), allocatable :: wavenumber(:) ! cm-1
118
119    ! Hydrophilic aerosol properties
120    real(jprb), allocatable :: mass_ext_philic(:,:,:)    ! Mass-ext coefficient (m2 kg-1)
121    real(jprb), allocatable :: ssa_philic(:,:,:)         ! Single-scattering albedo
122    real(jprb), allocatable :: g_philic(:,:,:)           ! Asymmetry factor
123    real(jprb), allocatable :: lidar_ratio_philic(:,:,:) ! Lidar ratio (sr)
124
125    ! Hydrophobic aerosol properties
126    real(jprb), allocatable :: mass_ext_phobic(:,:)      ! Mass-ext coefficient (m2 kg-1)
127    real(jprb), allocatable :: ssa_phobic(:,:)           ! Single-scattering albedo
128    real(jprb), allocatable :: g_phobic(:,:)             ! Asymmetry factor
129    real(jprb), allocatable :: lidar_ratio_phobic(:,:)   ! Lidar ratio (sr)
130
131    ! Mapping matrix between optical properties at the wavenumbers in
132    ! the file, and spectral intervals used by the gas-optics scheme
133    real(jprb), allocatable :: mapping(:,:)
134
135    ! Target monochromatic wavenumber for interpolation (cm-1)
136    real(jprb) :: wavenumber_target
137
138    ! Number of spectral points describing aerosol properties in the
139    ! shortwave and longwave
140    integer    :: nspecsw, nspeclw
141
142    ! Number of monochromatic wavelengths required
143    integer    :: nmono
144
145    integer    :: n_type_philic, n_type_phobic, nrh, nwn
146    integer    :: jtype, jwl, iwn
147
148    ! Weight of first point in interpolation
149    real(jprb) :: weight1
150
151    real(jphook) :: hook_handle
152
153    if (lhook) call dr_hook('radiation_aerosol_optics:setup_general_aerosol_optics',0,hook_handle)
154
155    associate(ao => config%aerosol_optics)
156
157      call file%open(trim(config%aerosol_optics_file_name), iverbose=config%iverbosesetup)
158
159      if (.not. file%exists('wavenumber')) then
160        ! Assume we have an old-style aerosol optics file with optical
161        ! properties provided per pre-defined band
162        call file%close()
163        if (config%iverbosesetup >= 2) then
164          write(nulout,'(a)') 'Legacy aerosol optics file: mapping between bands'
165        end if
166        call setup_general_aerosol_optics_legacy(config, trim(config%aerosol_optics_file_name))
167        if (lhook) call dr_hook('radiation_aerosol_optics:setup_general_aerosol_optics',1,hook_handle)
168        return
169      end if
170
171      if (file%exists('mass_ext_hydrophilic')) then
172        ao%use_hydrophilic = .true.
173      else
174        ao%use_hydrophilic = .false.
175      end if
176
177      call file%get('wavenumber', wavenumber)
178      nwn = size(wavenumber)
179
180      ! Read the raw scattering data
181      call file%get('mass_ext_hydrophobic',    mass_ext_phobic)
182      call file%get('ssa_hydrophobic',         ssa_phobic)
183      call file%get('asymmetry_hydrophobic',   g_phobic)
184      call file%get('lidar_ratio_hydrophobic', lidar_ratio_phobic)
185
186      call file%get_global_attribute('description_hydrophobic', &
187          &                         ao%description_phobic_str)
188
189      if (ao%use_hydrophilic) then
190        call file%get('mass_ext_hydrophilic',    mass_ext_philic)
191        call file%get('ssa_hydrophilic',         ssa_philic)
192        call file%get('asymmetry_hydrophilic',   g_philic)
193        call file%get('lidar_ratio_hydrophilic', lidar_ratio_philic)
194
195        call file%get('relative_humidity1',      ao%rh_lower)
196
197        call file%get_global_attribute('description_hydrophilic', &
198            &                         ao%description_philic_str)
199      end if
200
201      ! Close aerosol scattering file
202      call file%close()
203
204      n_type_phobic = size(mass_ext_phobic, 2)
205      if (ao%use_hydrophilic) then
206        n_type_philic = size(mass_ext_philic, 3)
207        nrh = size(ao%rh_lower)
208      else
209        n_type_philic = 0
210        nrh = 0
211      end if
212
213      if (config%do_cloud_aerosol_per_sw_g_point) then
214        nspecsw = config%gas_optics_sw%spectral_def%ng
215      else
216        nspecsw = config%gas_optics_sw%spectral_def%nband
217      end if
218
219      if (config%do_cloud_aerosol_per_lw_g_point) then
220        nspeclw = config%gas_optics_lw%spectral_def%ng
221      else
222        nspeclw = config%gas_optics_lw%spectral_def%nband
223      end if
224
225      if (allocated(ao%wavelength_mono)) then
226        ! Monochromatic wavelengths also required
227        nmono = size(ao%wavelength_mono)
228      else
229        nmono = 0
230      end if
231
232      call ao%allocate(n_type_phobic, n_type_philic, nrh, nspeclw, nspecsw, nmono)
233
234      if (config%do_sw) then
235        call config%gas_optics_sw%spectral_def%calc_mapping(wavenumber, mapping, &
236            &          use_bands=(.not. config%do_cloud_aerosol_per_sw_g_point))
237
238        ao%mass_ext_sw_phobic = matmul(mapping, mass_ext_phobic)
239        ao%ssa_sw_phobic = matmul(mapping, mass_ext_phobic*ssa_phobic) &
240            &           / ao%mass_ext_sw_phobic
241        ao%g_sw_phobic = matmul(mapping, mass_ext_phobic*ssa_phobic*g_phobic) &
242            &         / (ao%mass_ext_sw_phobic*ao%ssa_sw_phobic)
243
244        if (ao%use_hydrophilic) then
245          do jtype = 1,n_type_philic
246            ao%mass_ext_sw_philic(:,:,jtype) = matmul(mapping, mass_ext_philic(:,:,jtype))
247            ao%ssa_sw_philic(:,:,jtype) = matmul(mapping, mass_ext_philic(:,:,jtype) &
248                &                                        *ssa_philic(:,:,jtype)) &
249                &           / ao%mass_ext_sw_philic(:,:,jtype)
250            ao%g_sw_philic(:,:,jtype) = matmul(mapping, mass_ext_philic(:,:,jtype) &
251                &                       *ssa_philic(:,:,jtype)*g_philic(:,:,jtype)) &
252                &         / (ao%mass_ext_sw_philic(:,:,jtype)*ao%ssa_sw_philic(:,:,jtype))
253          end do
254        end if
255      end if
256
257      if (config%do_lw) then
258        call config%gas_optics_lw%spectral_def%calc_mapping(wavenumber, mapping, &
259            &          use_bands=(.not. config%do_cloud_aerosol_per_lw_g_point))
260
261        ao%mass_ext_lw_phobic = matmul(mapping, mass_ext_phobic)
262        ao%ssa_lw_phobic = matmul(mapping, mass_ext_phobic*ssa_phobic) &
263            &           / ao%mass_ext_lw_phobic
264        ao%g_lw_phobic = matmul(mapping, mass_ext_phobic*ssa_phobic*g_phobic) &
265            &         / (ao%mass_ext_lw_phobic*ao%ssa_lw_phobic)
266
267        if (ao%use_hydrophilic) then
268          do jtype = 1,n_type_philic
269            ao%mass_ext_lw_philic(:,:,jtype) = matmul(mapping, mass_ext_philic(:,:,jtype))
270            ao%ssa_lw_philic(:,:,jtype) = matmul(mapping, mass_ext_philic(:,:,jtype) &
271                &                                        *ssa_philic(:,:,jtype)) &
272                &           / ao%mass_ext_lw_philic(:,:,jtype)
273            ao%g_lw_philic(:,:,jtype) = matmul(mapping, mass_ext_philic(:,:,jtype) &
274                &                       *ssa_philic(:,:,jtype)*g_philic(:,:,jtype)) &
275                &         / (ao%mass_ext_lw_philic(:,:,jtype)*ao%ssa_lw_philic(:,:,jtype))
276          end do
277        end if
278      end if
279
280      if (allocated(ao%wavelength_mono)) then
281        ! Monochromatic wavelengths also required
282        do jwl = 1,nmono
283          ! Wavelength (m) to wavenumber (cm-1)
284          wavenumber_target = 0.01_jprb / ao%wavelength_mono(jwl)
285          ! Find index to first interpolation point, and its weight
286          if (wavenumber_target <= wavenumber(1)) then
287            weight1 = 1.0_jprb
288            iwn = 1
289          else if (wavenumber_target >= wavenumber(nwn)) then
290            iwn = nwn-1
291            weight1 = 0.0_jprb
292          else
293            iwn = 1
294            do while (wavenumber(iwn+1) < wavenumber_target .and. iwn < nwn-1)
295              iwn = iwn + 1
296            end do
297            weight1 = (wavenumber(iwn+1)-wavenumber_target) &
298                &  / (wavenumber(iwn+1)-wavenumber(iwn))
299          end if
300          ! Linear interpolation
301          ao%mass_ext_mono_phobic(jwl,:) = weight1 * mass_ext_phobic(iwn,:) &
302              &             + (1.0_jprb - weight1)* mass_ext_phobic(iwn+1,:)
303          ao%ssa_mono_phobic(jwl,:)      = weight1 * ssa_phobic(iwn,:) &
304              &             + (1.0_jprb - weight1)* ssa_phobic(iwn+1,:)
305          ao%g_mono_phobic(jwl,:)        = weight1 * g_phobic(iwn,:) &
306              &             + (1.0_jprb - weight1)* g_phobic(iwn+1,:)
307          ao%lidar_ratio_mono_phobic(jwl,:) = weight1 * lidar_ratio_phobic(iwn,:) &
308              &                + (1.0_jprb - weight1)* lidar_ratio_phobic(iwn+1,:)
309          if (ao%use_hydrophilic) then
310            ao%mass_ext_mono_philic(jwl,:,:) = weight1 * mass_ext_philic(iwn,:,:) &
311                &               + (1.0_jprb - weight1)* mass_ext_philic(iwn+1,:,:)
312            ao%ssa_mono_philic(jwl,:,:)      = weight1 * ssa_philic(iwn,:,:) &
313                &               + (1.0_jprb - weight1)* ssa_philic(iwn+1,:,:)
314            ao%g_mono_philic(jwl,:,:)        = weight1 * g_philic(iwn,:,:) &
315                &               + (1.0_jprb - weight1)* g_philic(iwn+1,:,:)
316            ao%lidar_ratio_mono_philic(jwl,:,:) = weight1 * lidar_ratio_philic(iwn,:,:) &
317                &                  + (1.0_jprb - weight1)* lidar_ratio_philic(iwn+1,:,:)
318          end if
319        end do
320      end if
321
322      ! Deallocate memory local to this routine
323      deallocate(mass_ext_phobic)
324      deallocate(ssa_phobic)
325      deallocate(g_phobic)
326      deallocate(lidar_ratio_phobic)
327      if (ao%use_hydrophilic) then
328        deallocate(mass_ext_philic)
329        deallocate(ssa_philic)
330        deallocate(g_philic)
331        deallocate(lidar_ratio_philic)
332      end if
333
334    end associate
335
336    if (lhook) call dr_hook('radiation_aerosol_optics:setup_general_aerosol_optics',1,hook_handle)
337
338  end subroutine setup_general_aerosol_optics
339
340
341  !---------------------------------------------------------------------
342  ! Read file containing legacy-style band-wise aerosol optical
343  ! properties and average to the spectral intervals of the current
344  ! gas-optics scheme
345  subroutine setup_general_aerosol_optics_legacy(config, file_name)
346
347    use parkind1,                      only : jprb
348    use yomhook,                       only : lhook, dr_hook, jphook
349#ifdef EASY_NETCDF_READ_MPI
350    use easy_netcdf_read_mpi,          only : netcdf_file
351#else
352    use easy_netcdf,                   only : netcdf_file
353#endif
354    use radiation_config,              only : config_type
355    use radiation_aerosol_optics_data, only : aerosol_optics_type
356    use radiation_spectral_definition, only : SolarReferenceTemperature, &
357         &                                    TerrestrialReferenceTemperature
358
359    type(config_type), intent(inout), target :: config
360
361    ! The NetCDF file containing the aerosol optics data
362    character(len=*), intent(in) :: file_name
363
364    ! Mapping matrix between optical properties at the wavenumbers in
365    ! the file, and spectral intervals used by the gas-optics scheme
366    real(jprb), allocatable :: mapping(:,:), mapping_transp(:,:)
367
368    ! Pointer to the aerosol optics coefficients for brevity of access
369    type(aerosol_optics_type), pointer :: ao
370
371    ! Local copy of aerosol optical properties in the spectral
372    ! intervals of the file, which is deallocated when it goes out of
373    ! scope
374    type(aerosol_optics_type) :: ao_legacy
375
376    integer :: jtype
377
378    real(jphook) :: hook_handle
379
380    if (lhook) call dr_hook('radiation_aerosol_optics:setup_general_aerosol_optics_legacy',0,hook_handle)
381    ao => config%aerosol_optics
382
383    ! Load file into a local structure
384    call ao_legacy%setup(file_name, iverbose=config%iverbosesetup)
385
386    ! Copy over scalars and coordinate variables
387    call ao%allocate(ao_legacy%n_type_phobic, ao_legacy%n_type_philic, ao_legacy%nrh, &
388         &           config%n_bands_lw, config%n_bands_sw, ao_legacy%n_mono_wl)
389    ao%description_phobic_str = ao_legacy%description_phobic_str
390    if (ao_legacy%use_hydrophilic) then
391      ao%description_philic_str = ao_legacy%description_philic_str
392      ao%rh_lower = ao_legacy%rh_lower
393    end if
394
395    ! use_hydrophilic = ao_legacy%use_hydrophilic
396    ! ao%iclass = ao_legacy%iclass
397    ! ao%itype = ao_legacy%itype
398    ! ao%ntype = ao_legacy%ntype
399    ! ao%n_type_phobic = ao_legacy%n_type_phobic
400    ! ao%n_type_philic = ao_legacy%n_type_philic
401    ! ao%n_mono_wl = ao_legacy%n_mono_wl
402    ! ao%use_monochromatic = ao_legacy%use_monochromatic
403
404    if (config%do_sw) then
405      call config%gas_optics_sw%spectral_def%calc_mapping_from_wavenumber_bands( &
406           &  ao_legacy%wavenumber1_sw, ao_legacy%wavenumber2_sw, mapping_transp, &
407           &  use_bands=(.not. config%do_cloud_aerosol_per_sw_g_point))
408      if (allocated(mapping)) then
409        deallocate(mapping)
410      end if
411      allocate(mapping(config%n_bands_sw,ao_legacy%n_bands_sw))
412      mapping = transpose(mapping_transp)
413      ao%mass_ext_sw_phobic = matmul(mapping, ao_legacy%mass_ext_sw_phobic)
414      ao%ssa_sw_phobic = matmul(mapping, ao_legacy%mass_ext_sw_phobic*ao_legacy%ssa_sw_phobic) &
415           &           / ao%mass_ext_sw_phobic
416      ao%g_sw_phobic = matmul(mapping, ao_legacy%mass_ext_sw_phobic*ao_legacy%ssa_sw_phobic &
417           &                           *ao_legacy%g_sw_phobic) &
418           &         / (ao%mass_ext_sw_phobic*ao%ssa_sw_phobic)
419
420      if (ao%use_hydrophilic) then
421        do jtype = 1,ao%n_type_philic
422          ao%mass_ext_sw_philic(:,:,jtype) = matmul(mapping, ao_legacy%mass_ext_sw_philic(:,:,jtype))
423          ao%ssa_sw_philic(:,:,jtype) = matmul(mapping, ao_legacy%mass_ext_sw_philic(:,:,jtype) &
424               &                                        *ao_legacy%ssa_sw_philic(:,:,jtype)) &
425               &           / ao%mass_ext_sw_philic(:,:,jtype)
426          ao%g_sw_philic(:,:,jtype) = matmul(mapping, ao_legacy%mass_ext_sw_philic(:,:,jtype) &
427               &               *ao_legacy%ssa_sw_philic(:,:,jtype)*ao_legacy%g_sw_philic(:,:,jtype)) &
428               &         / (ao%mass_ext_sw_philic(:,:,jtype)*ao%ssa_sw_philic(:,:,jtype))
429        end do
430      end if
431    end if
432
433    if (config%do_lw) then
434      if (allocated(mapping_transp)) then
435        deallocate(mapping_transp)
436      end if
437      call config%gas_optics_lw%spectral_def%calc_mapping_from_wavenumber_bands( &
438           &  ao_legacy%wavenumber1_lw, ao_legacy%wavenumber2_lw, mapping_transp, &
439           &  use_bands=(.not. config%do_cloud_aerosol_per_lw_g_point))
440      if (allocated(mapping)) then
441        deallocate(mapping)
442      end if
443      allocate(mapping(config%n_bands_lw,ao_legacy%n_bands_lw))
444      mapping = transpose(mapping_transp)
445      ao%mass_ext_lw_phobic = matmul(mapping, ao_legacy%mass_ext_lw_phobic)
446      ao%ssa_lw_phobic = matmul(mapping, ao_legacy%mass_ext_lw_phobic*ao_legacy%ssa_lw_phobic) &
447           &           / ao%mass_ext_lw_phobic
448      ao%g_lw_phobic = matmul(mapping, ao_legacy%mass_ext_lw_phobic*ao_legacy%ssa_lw_phobic &
449           &                           *ao_legacy%g_lw_phobic) &
450           &         / (ao%mass_ext_lw_phobic*ao%ssa_lw_phobic)
451
452      if (ao%use_hydrophilic) then
453        do jtype = 1,ao%n_type_philic
454          ao%mass_ext_lw_philic(:,:,jtype) = matmul(mapping, ao_legacy%mass_ext_lw_philic(:,:,jtype))
455          ao%ssa_lw_philic(:,:,jtype) = matmul(mapping, ao_legacy%mass_ext_lw_philic(:,:,jtype) &
456               &                                        *ao_legacy%ssa_lw_philic(:,:,jtype)) &
457               &           / ao%mass_ext_lw_philic(:,:,jtype)
458          ao%g_lw_philic(:,:,jtype) = matmul(mapping, ao_legacy%mass_ext_lw_philic(:,:,jtype) &
459               &               *ao_legacy%ssa_lw_philic(:,:,jtype)*ao_legacy%g_lw_philic(:,:,jtype)) &
460               &         / (ao%mass_ext_lw_philic(:,:,jtype)*ao%ssa_lw_philic(:,:,jtype))
461        end do
462      end if
463    end if
464
465    if (allocated(ao_legacy%wavelength_mono)) then
466      ao%wavelength_mono = ao_legacy%wavelength_mono
467      ao%mass_ext_mono_phobic = ao_legacy%mass_ext_mono_phobic
468      ao%ssa_mono_phobic = ao_legacy%ssa_mono_phobic
469      ao%g_mono_phobic = ao_legacy%g_mono_phobic
470      ao%lidar_ratio_mono_phobic = ao_legacy%lidar_ratio_mono_phobic
471      if (ao%use_hydrophilic) then
472        ao%mass_ext_mono_philic = ao_legacy%mass_ext_mono_philic
473        ao%ssa_mono_philic = ao_legacy%ssa_mono_philic
474        ao%g_mono_philic = ao_legacy%g_mono_philic
475        ao%lidar_ratio_mono_philic = ao_legacy%lidar_ratio_mono_philic
476      end if
477    end if
478
479    if (lhook) call dr_hook('radiation_aerosol_optics:setup_general_aerosol_optics_legacy',1,hook_handle)
480
481  end subroutine setup_general_aerosol_optics_legacy
482
483
484  !---------------------------------------------------------------------
485  ! Compute aerosol optical properties and add to existing gas optical
486  ! depth and scattering properties
487  subroutine add_aerosol_optics(nlev,istartcol,iendcol, &
488       &  config, thermodynamics, gas, aerosol, &
489       &  od_lw, ssa_lw, g_lw, od_sw, ssa_sw, g_sw)
490
491    use parkind1,                      only : jprb
492    use radiation_io,                  only : nulout, nulerr, radiation_abort
493    use yomhook,                       only : lhook, dr_hook, jphook
494    use radiation_config,              only : config_type
495    use radiation_thermodynamics,      only : thermodynamics_type
496    use radiation_gas,                 only : gas_type, IH2O, IMassMixingRatio
497    use radiation_aerosol,             only : aerosol_type
498    use radiation_constants,           only : AccelDueToGravity
499    use radiation_aerosol_optics_data, only : aerosol_optics_type, &
500         &  IAerosolClassUndefined,   IAerosolClassIgnored, &
501         &  IAerosolClassHydrophobic, IAerosolClassHydrophilic
502
503    real(jprb), parameter :: OneOverAccelDueToGravity = 1.0_jprb / AccelDueToGravity
504
505    integer, intent(in) :: nlev               ! number of model levels
506    integer, intent(in) :: istartcol, iendcol ! range of columns to process
507    type(config_type), intent(in), target :: config
508    type(thermodynamics_type),intent(in)  :: thermodynamics
509    type(gas_type),           intent(in)  :: gas
510    type(aerosol_type),       intent(in)  :: aerosol
511    ! Optical depth, single scattering albedo and asymmetry factor of
512    ! the atmosphere (gases on input, gases and aerosols on output)
513    ! for each g point. Note that longwave ssa and asymmetry and
514    ! shortwave asymmetry are all zero for gases, so are not yet
515    ! defined on input and are therefore intent(out).
516    real(jprb), dimension(config%n_g_lw,nlev,istartcol:iendcol), &
517         &   intent(inout) :: od_lw
518    real(jprb), dimension(config%n_g_lw_if_scattering,nlev,istartcol:iendcol), &
519         &   intent(out)   :: ssa_lw, g_lw
520    real(jprb), dimension(config%n_g_sw,nlev,istartcol:iendcol), &
521         &   intent(inout) :: od_sw, ssa_sw
522    real(jprb), dimension(config%n_g_sw,nlev,istartcol:iendcol), &
523         &   intent(out)   :: g_sw
524
525    ! Extinction optical depth, scattering optical depth and
526    ! asymmetry-times-scattering-optical-depth for all the aerosols in
527    ! a column for each spectral band of the shortwave and longwave
528    ! spectrum
529    real(jprb), dimension(config%n_bands_sw,nlev) &
530         &  :: od_sw_aerosol, scat_sw_aerosol, scat_g_sw_aerosol
531    real(jprb), dimension(config%n_bands_lw,nlev) &
532         &  :: od_lw_aerosol
533    real(jprb), dimension(config%n_bands_lw_if_scattering,nlev) &
534         &  :: scat_lw_aerosol, scat_g_lw_aerosol
535
536    real(jprb) :: local_od_sw, local_od_lw
537
538    real(jprb) :: h2o_mmr(istartcol:iendcol,nlev)
539
540    real(jprb) :: rh ! Relative humidity with respect to liquid water
541
542    ! Factor (kg m-2) to convert mixing ratio (kg kg-1) to mass in
543    ! path (kg m-2)
544    real(jprb) :: factor(nlev)
545
546    ! Temporary extinction and scattering optical depths of aerosol
547    ! plus gas
548    real(jprb) :: local_od, local_scat
549
550    ! Aerosol mixing ratio as a scalar
551    real(jprb) :: mixing_ratio
552
553    ! Loop indices for column, level, g point, band and aerosol type
554    integer :: jcol, jlev, jg, jtype, jband
555
556    ! Range of levels over which aerosols are present
557    integer :: istartlev, iendlev
558
559    ! Indices to spectral band and relative humidity look-up table
560    integer :: iband, irh, irhs(nlev)
561
562    ! Short cut for ao%itype(jtype)
563    integer :: itype
564
565    ! Pointer to the aerosol optics coefficients for brevity of access
566    type(aerosol_optics_type), pointer :: ao
567
568    real(jphook) :: hook_handle
569
570    if (lhook) call dr_hook('radiation_aerosol_optics:add_aerosol_optics',0,hook_handle)
571
572    if (aerosol%is_direct) then
573      ! Aerosol optical properties have been provided in each band
574      ! directly by the user
575      call add_aerosol_optics_direct(nlev,istartcol,iendcol, &
576           &  config, aerosol, &
577           &  od_lw, ssa_lw, g_lw, od_sw, ssa_sw, g_sw)
578    else
579      ! Aerosol mixing ratios have been provided
580
581      do jtype = 1,config%n_aerosol_types
582        if (config%aerosol_optics%iclass(jtype) == IAerosolClassUndefined) then
583          write(nulerr,'(a)') '*** Error: not all aerosol types are defined'
584          call radiation_abort()
585        end if
586      end do
587
588      if (config%iverbose >= 2) then
589        write(nulout,'(a)') 'Computing aerosol absorption/scattering properties'
590      end if
591
592      ao => config%aerosol_optics
593
594      istartlev = lbound(aerosol%mixing_ratio,2)
595      iendlev   = ubound(aerosol%mixing_ratio,2)
596
597      if (ubound(aerosol%mixing_ratio,3) /= config%n_aerosol_types) then
598        write(nulerr,'(a,i0,a,i0)') '*** Error: aerosol%mixing_ratio contains ', &
599             &  ubound(aerosol%mixing_ratio,3), ' aerosol types, expected ', &
600             &  config%n_aerosol_types
601        call radiation_abort()
602      end if
603
604      ! Set variables to zero that may not have been previously
605      g_sw(:,:,istartcol:iendcol) = 0.0_jprb
606      if (config%do_lw_aerosol_scattering) then
607        ssa_lw(:,:,istartcol:iendcol) = 0.0_jprb
608        g_lw(:,:,istartcol:iendcol)   = 0.0_jprb
609      end if
610
611      call gas%get(IH2O, IMassMixingRatio, h2o_mmr, istartcol=istartcol)
612
613      ! Loop over column
614      do jcol = istartcol,iendcol
615
616        ! Reset temporary arrays
617        od_sw_aerosol     = 0.0_jprb
618        scat_sw_aerosol   = 0.0_jprb
619        scat_g_sw_aerosol = 0.0_jprb
620        od_lw_aerosol     = 0.0_jprb
621        scat_lw_aerosol   = 0.0_jprb
622        scat_g_lw_aerosol = 0.0_jprb
623
624        do jlev = istartlev,iendlev
625          ! Compute relative humidity with respect to liquid
626          ! saturation and the index to the relative-humidity index of
627          ! hydrophilic-aerosol data
628          rh  = h2o_mmr(jcol,jlev) / thermodynamics%h2o_sat_liq(jcol,jlev)
629          irhs(jlev) = ao%calc_rh_index(rh)
630
631          factor(jlev) = ( thermodynamics%pressure_hl(jcol,jlev+1) &
632               &    -thermodynamics%pressure_hl(jcol,jlev  )  ) &
633               &   * OneOverAccelDueToGravity
634        end do
635
636        do jtype = 1,config%n_aerosol_types
637          itype = ao%itype(jtype)
638
639          ! Add the optical depth, scattering optical depth and
640          ! scattering optical depth-weighted asymmetry factor for
641          ! this aerosol type to the total for all aerosols.  Note
642          ! that the following expressions are array-wise, the
643          ! dimension being spectral band.
644          if (ao%iclass(jtype) == IAerosolClassHydrophobic) then
645            do jlev = istartlev,iendlev
646              mixing_ratio = aerosol%mixing_ratio(jcol,jlev,jtype)
647              do jband = 1,config%n_bands_sw
648                local_od_sw = factor(jlev) * mixing_ratio &
649                     &  * ao%mass_ext_sw_phobic(jband,itype)
650                od_sw_aerosol(jband,jlev) = od_sw_aerosol(jband,jlev) + local_od_sw
651                scat_sw_aerosol(jband,jlev) = scat_sw_aerosol(jband,jlev) &
652                     &  + local_od_sw * ao%ssa_sw_phobic(jband,itype)
653                scat_g_sw_aerosol(jband,jlev) = scat_g_sw_aerosol(jband,jlev) &
654                     &  + local_od_sw * ao%ssa_sw_phobic(jband,itype) &
655                     &  * ao%g_sw_phobic(jband,itype)
656              end do
657              if (config%do_lw_aerosol_scattering) then
658                do jband = 1,config%n_bands_lw
659                  local_od_lw = factor(jlev) * mixing_ratio &
660                       &  * ao%mass_ext_lw_phobic(jband,itype)
661                  od_lw_aerosol(jband,jlev) = od_lw_aerosol(jband,jlev) + local_od_lw
662                  scat_lw_aerosol(jband,jlev) = scat_lw_aerosol(jband,jlev) &
663                       &  + local_od_lw * ao%ssa_lw_phobic(jband,itype)
664                  scat_g_lw_aerosol(jband,jlev) = scat_g_lw_aerosol(jband,jlev) &
665                       &  + local_od_lw * ao%ssa_lw_phobic(jband,itype) &
666                       &  * ao%g_lw_phobic(jband,itype)
667                end do
668              else
669                ! If aerosol longwave scattering is not included then we
670                ! weight the optical depth by the single scattering
671                ! co-albedo
672                do jband = 1,config%n_bands_lw
673                  od_lw_aerosol(jband,jlev) = od_lw_aerosol(jband,jlev) &
674                       &  + factor(jlev) * mixing_ratio &
675                       &  * ao%mass_ext_lw_phobic(jband,itype) &
676                       &  * (1.0_jprb - ao%ssa_lw_phobic(jband,itype))
677                end do
678              end if
679            end do
680
681          else if (ao%iclass(jtype) == IAerosolClassHydrophilic) then
682            ! Hydrophilic aerosols require the look-up tables to
683            ! be indexed with irh
684            do jlev = istartlev,iendlev
685              mixing_ratio = aerosol%mixing_ratio(jcol,jlev,jtype)
686              irh = irhs(jlev)
687              do jband = 1,config%n_bands_sw
688                local_od_sw = factor(jlev) * mixing_ratio &
689                     &  * ao%mass_ext_sw_philic(jband,irh,itype)
690                od_sw_aerosol(jband,jlev) = od_sw_aerosol(jband,jlev) + local_od_sw
691                scat_sw_aerosol(jband,jlev) = scat_sw_aerosol(jband,jlev) &
692                     &  + local_od_sw * ao%ssa_sw_philic(jband,irh,itype)
693                scat_g_sw_aerosol(jband,jlev) = scat_g_sw_aerosol(jband,jlev) &
694                     &  + local_od_sw * ao%ssa_sw_philic(jband,irh,itype) &
695                     &  * ao%g_sw_philic(jband,irh,itype)
696              end do
697              if (config%do_lw_aerosol_scattering) then
698                do jband = 1,config%n_bands_lw
699                  local_od_lw = factor(jlev) * mixing_ratio &
700                       &  * ao%mass_ext_lw_philic(jband,irh,itype)
701                  od_lw_aerosol(jband,jlev) = od_lw_aerosol(jband,jlev) + local_od_lw
702                  scat_lw_aerosol(jband,jlev) = scat_lw_aerosol(jband,jlev) &
703                       &  + local_od_lw * ao%ssa_lw_philic(jband,irh,itype)
704                  scat_g_lw_aerosol(jband,jlev) = scat_g_lw_aerosol(jband,jlev) &
705                       &  + local_od_lw * ao%ssa_lw_philic(jband,irh,itype) &
706                       &  * ao%g_lw_philic(jband,irh,itype)
707                end do
708              else
709                ! If aerosol longwave scattering is not included then we
710                ! weight the optical depth by the single scattering
711                ! co-albedo
712                do jband = 1,config%n_bands_lw
713                  od_lw_aerosol(jband,jlev) = od_lw_aerosol(jband,jlev) &
714                       &  + factor(jlev) * mixing_ratio &
715                       &  * ao%mass_ext_lw_philic(jband,irh,itype) &
716                       &  * (1.0_jprb - ao%ssa_lw_philic(jband,irh,itype))
717                end do
718              end if
719            end do
720
721            ! Implicitly, if ao%iclass(jtype) == IAerosolClassNone, then
722            ! no aerosol scattering properties are added
723          end if
724
725        end do ! Loop over aerosol type
726
727        if (.not. config%do_sw_delta_scaling_with_gases) then
728          ! Delta-Eddington scaling on aerosol only.  Note that if
729          ! do_sw_delta_scaling_with_gases==.true. then the delta
730          ! scaling is done to the cloud-aerosol-gas mixture inside
731          ! the solver
732          call delta_eddington_extensive_vec(config%n_bands_sw*nlev, od_sw_aerosol, &
733               &                             scat_sw_aerosol, scat_g_sw_aerosol)
734        end if
735
736        ! Combine aerosol shortwave scattering properties with gas
737        ! properties (noting that any gas scattering will have an
738        ! asymmetry factor of zero)
739        if (config%do_cloud_aerosol_per_sw_g_point) then
740
741          ! We can assume the band and g-point indices are the same
742          do jlev = 1,nlev
743            do jg = 1,config%n_g_sw
744              local_scat = ssa_sw(jg,jlev,jcol)*od_sw(jg,jlev,jcol) + scat_sw_aerosol(jg,jlev)
745              od_sw(jg,jlev,jcol) = od_sw(jg,jlev,jcol) + od_sw_aerosol(jg,jlev)
746              g_sw(jg,jlev,jcol) = scat_g_sw_aerosol(jg,jlev) / max(local_scat, 1.0e-24_jprb)
747              ssa_sw(jg,jlev,jcol) = min(local_scat / max(od_sw(jg,jlev,jcol), 1.0e-24_jprb), 1.0_jprb)
748            end do
749          end do
750
751        else
752
753          do jlev = 1,nlev
754            do jg = 1,config%n_g_sw
755              ! Need to map between bands and g-points
756              iband = config%i_band_from_reordered_g_sw(jg)
757              local_od = od_sw(jg,jlev,jcol) + od_sw_aerosol(iband,jlev)
758              if (local_od > 0.0_jprb .and. od_sw_aerosol(iband,jlev) > 0.0_jprb) then
759                local_scat = ssa_sw(jg,jlev,jcol) * od_sw(jg,jlev,jcol) &
760                     &  + scat_sw_aerosol(iband,jlev)
761                ! Note that asymmetry_sw of gases is zero so the following
762                ! simply weights the aerosol asymmetry by the scattering
763                ! optical depth
764                if (local_scat > 0.0_jprb) then
765                  g_sw(jg,jlev,jcol) = scat_g_sw_aerosol(iband,jlev) / local_scat
766                end if
767                ssa_sw(jg,jlev,jcol) = local_scat / local_od
768                od_sw (jg,jlev,jcol) = local_od
769              end if
770            end do
771          end do
772
773        end if
774
775        ! Combine aerosol longwave scattering properties with gas
776        ! properties, noting that in the longwave, gases do not
777        ! scatter at all
778        if (config%do_lw_aerosol_scattering) then
779
780          call delta_eddington_extensive_vec(config%n_bands_lw*nlev, od_lw_aerosol, &
781               &                             scat_lw_aerosol, scat_g_lw_aerosol)
782
783          do jlev = istartlev,iendlev
784            do jg = 1,config%n_g_lw
785              iband = config%i_band_from_reordered_g_lw(jg)
786              local_od = od_lw(jg,jlev,jcol) + od_lw_aerosol(iband,jlev)
787              if (local_od > 0.0_jprb .and. od_lw_aerosol(iband,jlev) > 0.0_jprb) then
788                ! All scattering is due to aerosols, therefore the
789                ! asymmetry factor is equal to the value for aerosols
790                if (scat_lw_aerosol(iband,jlev) > 0.0_jprb) then
791                  g_lw(jg,jlev,jcol) = scat_g_lw_aerosol(iband,jlev) &
792                       &  / scat_lw_aerosol(iband,jlev)
793                end if
794                ssa_lw(jg,jlev,jcol) = scat_lw_aerosol(iband,jlev) / local_od
795                od_lw (jg,jlev,jcol) = local_od
796              end if
797            end do
798          end do
799
800        else
801
802          if (config%do_cloud_aerosol_per_lw_g_point) then
803            ! We can assume band and g-point indices are the same
804            do jlev = istartlev,iendlev
805              do jg = 1,config%n_g_lw
806                od_lw(jg,jlev,jcol) = od_lw(jg,jlev,jcol) + od_lw_aerosol(jg,jlev)
807              end do
808            end do
809          else
810            do jlev = istartlev,iendlev
811              do jg = 1,config%n_g_lw
812                od_lw(jg,jlev,jcol) = od_lw(jg,jlev,jcol) &
813                     &  + od_lw_aerosol(config%i_band_from_reordered_g_lw(jg),jlev)
814              end do
815            end do
816          end if
817
818        end if
819
820      end do ! Loop over column
821
822    end if
823
824    if (lhook) call dr_hook('radiation_aerosol_optics:add_aerosol_optics',1,hook_handle)
825
826  end subroutine add_aerosol_optics
827
828
829  !---------------------------------------------------------------------
830  ! Add precomputed optical properties to gas optical depth and
831  ! scattering properties
832  subroutine add_aerosol_optics_direct(nlev,istartcol,iendcol, &
833       &  config, aerosol, &
834       &  od_lw, ssa_lw, g_lw, od_sw, ssa_sw, g_sw)
835
836    use parkind1,                      only : jprb
837    use radiation_io,                  only : nulerr, radiation_abort
838    use yomhook,                       only : lhook, dr_hook, jphook
839    use radiation_config,              only : config_type
840    use radiation_aerosol,             only : aerosol_type
841
842    integer, intent(in) :: nlev               ! number of model levels
843    integer, intent(in) :: istartcol, iendcol ! range of columns to process
844    type(config_type), intent(in), target :: config
845    type(aerosol_type),       intent(in)  :: aerosol
846    ! Optical depth, single scattering albedo and asymmetry factor of
847    ! the atmosphere (gases on input, gases and aerosols on output)
848    ! for each g point. Note that longwave ssa and asymmetry and
849    ! shortwave asymmetry are all zero for gases, so are not yet
850    ! defined on input and are therefore intent(out).
851    real(jprb), dimension(config%n_g_lw,nlev,istartcol:iendcol), &
852         &   intent(inout) :: od_lw
853    real(jprb), dimension(config%n_g_lw_if_scattering,nlev,istartcol:iendcol), &
854         &   intent(out)   :: ssa_lw, g_lw
855    real(jprb), dimension(config%n_g_sw,nlev,istartcol:iendcol), &
856         &   intent(inout) :: od_sw, ssa_sw
857    real(jprb), dimension(config%n_g_sw,nlev,istartcol:iendcol), &
858         &   intent(out)   :: g_sw
859
860    ! Temporary extinction and scattering optical depths of aerosol
861    ! plus gas
862    real(jprb) :: local_od, local_scat
863
864    ! Extinction optical depth, scattering optical depth and
865    ! asymmetry-times-scattering-optical-depth for all the aerosols at
866    ! a point in space for each spectral band of the shortwave and
867    ! longwave spectrum
868    real(jprb), dimension(config%n_bands_sw,nlev) &
869         & :: od_sw_aerosol, scat_sw_aerosol, scat_g_sw_aerosol
870    real(jprb), dimension(config%n_bands_lw,nlev) :: od_lw_aerosol
871    real(jprb), dimension(config%n_bands_lw_if_scattering,nlev) &
872         & :: scat_lw_aerosol, scat_g_lw_aerosol
873
874    ! Loop indices for column, level, g point and band
875    integer :: jcol, jlev, jg, jb
876
877    ! Range of levels over which aerosols are present
878    integer :: istartlev, iendlev
879
880    ! Indices to spectral band
881    integer :: iband
882
883    real(jphook) :: hook_handle
884
885    if (lhook) call dr_hook('radiation_aerosol_optics:add_aerosol_optics_direct',0,hook_handle)
886
887    if (config%do_sw) then
888      ! Check array dimensions
889      if (ubound(aerosol%od_sw,1) /= config%n_bands_sw) then
890        write(nulerr,'(a,i0,a,i0)') '*** Error: aerosol%od_sw contains ', &
891           &  ubound(aerosol%od_sw,1), ' band, expected ', &
892           &  config%n_bands_sw
893        call radiation_abort()
894      end if
895
896      istartlev = lbound(aerosol%od_sw,2)
897      iendlev   = ubound(aerosol%od_sw,2)
898
899      ! Set variables to zero that may not have been previously
900      g_sw(:,:,istartcol:iendcol) = 0.0_jprb
901
902      ! Loop over position
903      do jcol = istartcol,iendcol
904! Added for DWD (2020)
905!NEC$ forced_collapse
906        do jlev = istartlev,iendlev
907          do jb = 1,config%n_bands_sw
908            od_sw_aerosol(jb,jlev) = aerosol%od_sw(jb,jlev,jcol)
909            scat_sw_aerosol(jb,jlev) = aerosol%ssa_sw(jb,jlev,jcol) * od_sw_aerosol(jb,jlev)
910            scat_g_sw_aerosol(jb,jlev) = aerosol%g_sw(jb,jlev,jcol) * scat_sw_aerosol(jb,jlev)
911
912            if (.not. config%do_sw_delta_scaling_with_gases) then
913              ! Delta-Eddington scaling on aerosol only.  Note that if
914              ! do_sw_delta_scaling_with_gases==.true. then the delta
915              ! scaling is done to the cloud-aerosol-gas mixture
916              ! inside the solver
917              call delta_eddington_extensive(od_sw_aerosol(jb,jlev), scat_sw_aerosol(jb,jlev), &
918                   &                         scat_g_sw_aerosol(jb,jlev))
919            end if
920          end do
921        end do
922        ! Combine aerosol shortwave scattering properties with gas
923        ! properties (noting that any gas scattering will have an
924        ! asymmetry factor of zero)
925        do jlev = istartlev,iendlev
926          if (od_sw_aerosol(1,jlev) > 0.0_jprb) then
927            do jg = 1,config%n_g_sw
928              iband = config%i_band_from_reordered_g_sw(jg)
929              local_od = od_sw(jg,jlev,jcol) + od_sw_aerosol(iband,jlev)
930              local_scat = ssa_sw(jg,jlev,jcol) * od_sw(jg,jlev,jcol) &
931                   &  + scat_sw_aerosol(iband,jlev)
932              ! Note that asymmetry_sw of gases is zero so the following
933              ! simply weights the aerosol asymmetry by the scattering
934              ! optical depth
935              g_sw(jg,jlev,jcol) = scat_g_sw_aerosol(iband,jlev) / local_scat
936              local_od = od_sw(jg,jlev,jcol) + od_sw_aerosol(iband,jlev)
937              ssa_sw(jg,jlev,jcol) = local_scat / local_od
938              od_sw (jg,jlev,jcol) = local_od
939            end do
940          end if
941        end do
942      end do
943
944    end if
945
946    if (config%do_lw) then
947
948      if (ubound(aerosol%od_lw,1) /= config%n_bands_lw) then
949        write(nulerr,'(a,i0,a,i0)') '*** Error: aerosol%od_lw contains ', &
950           &  ubound(aerosol%od_lw,1), ' band, expected ', &
951           &  config%n_bands_lw
952        call radiation_abort()
953      end if
954
955      istartlev = lbound(aerosol%od_lw,2)
956      iendlev   = ubound(aerosol%od_lw,2)
957
958      if (config%do_lw_aerosol_scattering) then
959        ssa_lw(:,:,istartcol:iendcol) = 0.0_jprb
960        g_lw(:,:,istartcol:iendcol)   = 0.0_jprb
961
962        ! Loop over position
963        do jcol = istartcol,iendcol
964! Added for DWD (2020)
965!NEC$ forced_collapse
966          do jlev = istartlev,iendlev
967            do jb = 1,config%n_bands_lw
968              od_lw_aerosol(jb,jlev) = aerosol%od_lw(jb,jlev,jcol)
969              scat_lw_aerosol(jb,jlev) = aerosol%ssa_lw(jb,jlev,jcol) * od_lw_aerosol(jb,jlev)
970              scat_g_lw_aerosol(jb,jlev) = aerosol%g_lw(jb,jlev,jcol) * scat_lw_aerosol(jb,jlev)
971
972              call delta_eddington_extensive(od_lw_aerosol(jb,jlev), scat_lw_aerosol(jb,jlev), &
973                   &                         scat_g_lw_aerosol(jb,jlev))
974            end do
975          end do
976          do jlev = istartlev,iendlev
977            do jg = 1,config%n_g_lw
978              iband = config%i_band_from_reordered_g_lw(jg)
979              if (od_lw_aerosol(iband,jlev) > 0.0_jprb) then
980                ! All scattering is due to aerosols, therefore the
981                ! asymmetry factor is equal to the value for aerosols
982                if (scat_lw_aerosol(iband,jlev) > 0.0_jprb) then
983                  g_lw(jg,jlev,jcol) = scat_g_lw_aerosol(iband,jlev) &
984                       &  / scat_lw_aerosol(iband,jlev)
985                end if
986                local_od = od_lw(jg,jlev,jcol) + od_lw_aerosol(iband,jlev)
987                ssa_lw(jg,jlev,jcol) = scat_lw_aerosol(iband,jlev) / local_od
988                od_lw (jg,jlev,jcol) = local_od
989              end if
990            end do
991          end do
992        end do
993
994      else ! No longwave scattering
995
996        ! Loop over position
997        do jcol = istartcol,iendcol
998! Added for DWD (2020)
999!NEC$ forced_collapse
1000          do jlev = istartlev,iendlev
1001            ! If aerosol longwave scattering is not included then we
1002            ! weight the optical depth by the single scattering
1003            ! co-albedo
1004            do jb = 1, config%n_bands_lw
1005              od_lw_aerosol(jb,jlev) = aerosol%od_lw(jb,jlev,jcol) &
1006                 &  * (1.0_jprb - aerosol%ssa_lw(jb,jlev,jcol))
1007            end do
1008          end do
1009          do jlev = istartlev,iendlev
1010            do jg = 1,config%n_g_lw
1011              od_lw(jg,jlev,jcol) = od_lw(jg,jlev,jcol) &
1012                   &  + od_lw_aerosol(config%i_band_from_reordered_g_lw(jg),jlev)
1013            end do
1014          end do
1015        end do
1016
1017      end if
1018    end if
1019
1020
1021    if (lhook) call dr_hook('radiation_aerosol_optics:add_aerosol_optics_direct',1,hook_handle)
1022
1023  end subroutine add_aerosol_optics_direct
1024
1025
1026  !---------------------------------------------------------------------
1027  ! Sometimes it is useful to specify aerosol in terms of its optical
1028  ! depth at a particular wavelength.  This function returns the dry
1029  ! mass-extinction coefficient, i.e. the extinction cross section per
1030  ! unit mass, for aerosol of type "itype" at the specified wavelength
1031  ! (m). For hydrophilic types, the value at the first relative
1032  ! humidity bin is taken.
1033  function dry_aerosol_mass_extinction(config, itype, wavelength)
1034
1035    use parkind1,                      only : jprb
1036    use radiation_io,                  only : nulerr, radiation_abort
1037    use radiation_config,              only : config_type
1038    use radiation_aerosol_optics_data, only : aerosol_optics_type, &
1039         &  IAerosolClassUndefined,   IAerosolClassIgnored, &
1040         &  IAerosolClassHydrophobic, IAerosolClassHydrophilic
1041
1042    type(config_type), intent(in), target :: config
1043
1044    ! Aerosol type
1045    integer, intent(in) :: itype
1046
1047    ! Wavelength (m)
1048    real(jprb), intent(in) :: wavelength
1049
1050    real(jprb) :: dry_aerosol_mass_extinction
1051
1052    ! Index to the monochromatic wavelength requested
1053    integer :: imono
1054
1055    ! Pointer to the aerosol optics coefficients for brevity of access
1056    type(aerosol_optics_type), pointer :: ao
1057
1058    ao => config%aerosol_optics
1059
1060    imono = minloc(abs(wavelength - ao%wavelength_mono), 1)
1061
1062    if (abs(wavelength - ao%wavelength_mono(imono))/wavelength > 0.02_jprb) then
1063      write(nulerr,'(a,e11.4,a)') '*** Error: requested wavelength ', &
1064           &  wavelength, ' not within 2% of stored wavelengths'
1065      call radiation_abort()
1066     end if
1067
1068    if (ao%iclass(itype) == IAerosolClassHydrophobic) then
1069      dry_aerosol_mass_extinction = ao%mass_ext_mono_phobic(imono,ao%itype(itype))
1070    else if (ao%iclass(itype) == IAerosolClassHydrophilic) then
1071      ! Take the value at the first relative-humidity bin for the
1072      ! "dry" aerosol value
1073      dry_aerosol_mass_extinction = ao%mass_ext_mono_philic(imono,1,ao%itype(itype))
1074    else
1075      dry_aerosol_mass_extinction = 0.0_jprb
1076    end if
1077
1078  end function dry_aerosol_mass_extinction
1079
1080
1081  !---------------------------------------------------------------------
1082  ! Compute aerosol extinction coefficient at a particular wavelength
1083  ! and a single height - this is useful for visibility diagnostics
1084  subroutine aerosol_extinction(ncol,istartcol,iendcol, &
1085       &  config, wavelength, mixing_ratio, relative_humidity, extinction)
1086
1087    use parkind1,                      only : jprb
1088    use yomhook,                       only : lhook, dr_hook, jphook
1089    use radiation_io,                  only : nulerr, radiation_abort
1090    use radiation_config,              only : config_type
1091    use radiation_aerosol_optics_data, only : aerosol_optics_type, &
1092         &  IAerosolClassUndefined,   IAerosolClassIgnored, &
1093         &  IAerosolClassHydrophobic, IAerosolClassHydrophilic
1094
1095    integer, intent(in) :: ncol               ! number of columns
1096    integer, intent(in) :: istartcol, iendcol ! range of columns to process
1097    type(config_type), intent(in), target :: config
1098    real(jprb), intent(in)  :: wavelength ! Requested wavelength (m)
1099    real(jprb), intent(in)  :: mixing_ratio(ncol,config%n_aerosol_types)
1100    real(jprb), intent(in)  :: relative_humidity(ncol)
1101    real(jprb), intent(out) :: extinction(ncol)
1102
1103    ! Local aerosol extinction
1104    real(jprb) :: ext
1105
1106    ! Index to the monochromatic wavelength requested
1107    integer :: imono
1108
1109    ! Pointer to the aerosol optics coefficients for brevity of access
1110    type(aerosol_optics_type), pointer :: ao
1111
1112    ! Loop indices for column and aerosol type
1113    integer :: jcol, jtype
1114
1115    ! Relative humidity index
1116    integer :: irh
1117
1118    real(jphook) :: hook_handle
1119
1120    if (lhook) call dr_hook('radiation_aerosol_optics:aerosol_extinction',0,hook_handle)
1121
1122    do jtype = 1,config%n_aerosol_types
1123      if (config%aerosol_optics%iclass(jtype) == IAerosolClassUndefined) then
1124        write(nulerr,'(a)') '*** Error: not all aerosol types are defined'
1125        call radiation_abort()
1126      end if
1127    end do
1128
1129    ao => config%aerosol_optics
1130
1131    imono = minloc(abs(wavelength - ao%wavelength_mono), 1)
1132
1133    if (abs(wavelength - ao%wavelength_mono(imono))/wavelength > 0.02_jprb) then
1134      write(nulerr,'(a,e11.4,a)') '*** Error: requested wavelength ', &
1135           &  wavelength, ' not within 2% of stored wavelengths'
1136      call radiation_abort()
1137     end if
1138
1139    ! Loop over position
1140    do jcol = istartcol,iendcol
1141      ext = 0.0_jprb
1142      ! Get relative-humidity index
1143      irh = ao%calc_rh_index(relative_humidity(jcol))
1144      ! Add extinction coefficients from each aerosol type
1145      do jtype = 1,config%n_aerosol_types
1146        if (ao%iclass(jtype) == IAerosolClassHydrophobic) then
1147          ext = ext + mixing_ratio(jcol,jtype) &
1148               &    * ao%mass_ext_mono_phobic(imono,ao%itype(jtype))
1149        else if (ao%iclass(jtype) == IAerosolClassHydrophilic) then
1150          ext = ext + mixing_ratio(jcol,jtype) &
1151               &    * ao%mass_ext_mono_philic(imono,irh,ao%itype(jtype))
1152        end if
1153      end do
1154
1155      extinction(jcol) = ext
1156    end do
1157
1158    if (lhook) call dr_hook('radiation_aerosol_optics:aerosol_extinction',1,hook_handle)
1159
1160  end subroutine aerosol_extinction
1161
1162end module radiation_aerosol_optics
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