source: palm/trunk/SOURCE/lpm_droplet_condensation.f90 @ 2576

Last change on this file since 2576 was 2375, checked in by schwenkel, 7 years ago

improved aerosol initialization for bulk microphysics

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[1682]1!> @file lpm_droplet_condensation.f90
[2000]2!------------------------------------------------------------------------------!
[1036]3! This file is part of PALM.
4!
[2000]5! PALM is free software: you can redistribute it and/or modify it under the
6! terms of the GNU General Public License as published by the Free Software
7! Foundation, either version 3 of the License, or (at your option) any later
8! version.
[1036]9!
10! PALM is distributed in the hope that it will be useful, but WITHOUT ANY
11! WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
12! A PARTICULAR PURPOSE.  See the GNU General Public License for more details.
13!
14! You should have received a copy of the GNU General Public License along with
15! PALM. If not, see <http://www.gnu.org/licenses/>.
16!
[2101]17! Copyright 1997-2017 Leibniz Universitaet Hannover
[2000]18!------------------------------------------------------------------------------!
[1036]19!
[849]20! Current revisions:
21! ------------------
[2375]22!
23!
[1891]24! Former revisions:
25! -----------------
26! $Id: lpm_droplet_condensation.f90 2375 2017-08-29 14:10:28Z Giersch $
[2375]27! Changed ONLY-dependencies
28!
29! 2312 2017-07-14 20:26:51Z hoffmann
[2312]30! Rosenbrock scheme improved. Gas-kinetic effect added.
[1891]31!
[2001]32! 2000 2016-08-20 18:09:15Z knoop
33! Forced header and separation lines into 80 columns
[2312]34!
[1891]35! 1890 2016-04-22 08:52:11Z hoffmann
[1890]36! Some improvements of the Rosenbrock method. If the Rosenbrock method needs more
37! than 40 iterations to find a sufficient time setp, the model is not aborted.
[2312]38! This might lead to small erros. But they can be assumend as negligible, since
39! the maximum timesetp of the Rosenbrock method after 40 iterations will be
40! smaller than 10^-16 s.
41!
[1872]42! 1871 2016-04-15 11:46:09Z hoffmann
43! Initialization of aerosols added.
44!
[1851]45! 1849 2016-04-08 11:33:18Z hoffmann
[1852]46! Interpolation of supersaturation has been removed because it is not in
47! accordance with the release/depletion of latent heat/water vapor in
[1849]48! interaction_droplets_ptq.
49! Calculation of particle Reynolds number has been corrected.
[1852]50! eps_ros added from modules.
[1849]51!
[1832]52! 1831 2016-04-07 13:15:51Z hoffmann
53! curvature_solution_effects moved to particle_attributes
54!
[1823]55! 1822 2016-04-07 07:49:42Z hoffmann
56! Unused variables removed.
57!
[1683]58! 1682 2015-10-07 23:56:08Z knoop
[2312]59! Code annotations made doxygen readable
60!
[1360]61! 1359 2014-04-11 17:15:14Z hoffmann
[2312]62! New particle structure integrated.
[1360]63! Kind definition added to all floating point numbers.
64!
[1347]65! 1346 2014-03-27 13:18:20Z heinze
[2312]66! Bugfix: REAL constants provided with KIND-attribute especially in call of
[1347]67! intrinsic function like MAX, MIN, SIGN
68!
[1323]69! 1322 2014-03-20 16:38:49Z raasch
70! REAL constants defined as wp-kind
71!
[1321]72! 1320 2014-03-20 08:40:49Z raasch
[1320]73! ONLY-attribute added to USE-statements,
74! kind-parameters added to all INTEGER and REAL declaration statements,
75! kinds are defined in new module kinds,
76! comment fields (!:) to be used for variable explanations added to
77! all variable declaration statements
[1072]78!
[1319]79! 1318 2014-03-17 13:35:16Z raasch
80! module interfaces removed
81!
[1093]82! 1092 2013-02-02 11:24:22Z raasch
83! unused variables removed
84!
[1072]85! 1071 2012-11-29 16:54:55Z franke
[1071]86! Ventilation effect for evaporation of large droplets included
87! Check for unreasonable results included in calculation of Rosenbrock method
88! since physically unlikely results were observed and for the same
89! reason the first internal time step in Rosenbrock method should be < 1.0E02 in
90! case of evaporation
91! Unnecessary calculation of ql_int removed
92! Unnecessary calculations in Rosenbrock method (d2rdt2, drdt_m, dt_ros_last)
93! removed
94! Bugfix: factor in calculation of surface tension changed from 0.00155 to
95! 0.000155
[849]96!
[1037]97! 1036 2012-10-22 13:43:42Z raasch
98! code put under GPL (PALM 3.9)
99!
[850]100! 849 2012-03-15 10:35:09Z raasch
101! initial revision (former part of advec_particles)
[849]102!
[850]103!
[849]104! Description:
105! ------------
[1682]106!> Calculates change in droplet radius by condensation/evaporation, using
107!> either an analytic formula or by numerically integrating the radius growth
108!> equation including curvature and solution effects using Rosenbrocks method
109!> (see Numerical recipes in FORTRAN, 2nd edition, p. 731).
110!> The analytical formula and growth equation follow those given in
111!> Rogers and Yau (A short course in cloud physics, 3rd edition, p. 102/103).
[849]112!------------------------------------------------------------------------------!
[1682]113 SUBROUTINE lpm_droplet_condensation (ip,jp,kp)
[849]114
[2312]115
[1320]116    USE arrays_3d,                                                             &
[2312]117        ONLY:  hyp, pt, q, ql_c, ql_v
[849]118
[1320]119    USE cloud_parameters,                                                      &
[2375]120        ONLY:  l_d_rv, l_v, molecular_weight_of_solute,                        &
121               molecular_weight_of_water, rho_l, rho_s, r_v, vanthoff
[849]122
[1320]123    USE constants,                                                             &
124        ONLY:  pi
[849]125
[1320]126    USE control_parameters,                                                    &
[1822]127        ONLY:  dt_3d, dz, message_string, molecular_viscosity, rho_surface
128
[1320]129    USE cpulog,                                                                &
130        ONLY:  cpu_log, log_point_s
[849]131
[1320]132    USE grid_variables,                                                        &
[1822]133        ONLY:  dx, dy
[1071]134
[1320]135    USE lpm_collision_kernels_mod,                                             &
136        ONLY:  rclass_lbound, rclass_ubound
[849]137
[1320]138    USE kinds
139
140    USE particle_attributes,                                                   &
[2375]141        ONLY:  curvature_solution_effects, hall_kernel, number_of_particles,   &
142               particles, radius_classes, use_kernel_tables, wang_kernel
[1320]143
144    IMPLICIT NONE
145
[1682]146    INTEGER(iwp) :: ip                         !<
147    INTEGER(iwp) :: jp                         !<
148    INTEGER(iwp) :: kp                         !<
149    INTEGER(iwp) :: n                          !<
[1320]150
[1849]151    REAL(wp) ::  afactor                       !< curvature effects
[1682]152    REAL(wp) ::  arg                           !<
[1849]153    REAL(wp) ::  bfactor                       !< solute effects
[1682]154    REAL(wp) ::  ddenom                        !<
155    REAL(wp) ::  delta_r                       !<
[1849]156    REAL(wp) ::  diameter                      !< diameter of cloud droplets
[2312]157    REAL(wp) ::  diff_coeff                    !< diffusivity for water vapor
[1682]158    REAL(wp) ::  drdt                          !<
159    REAL(wp) ::  dt_ros                        !<
160    REAL(wp) ::  dt_ros_sum                    !<
161    REAL(wp) ::  d2rdtdr                       !<
[1849]162    REAL(wp) ::  e_a                           !< current vapor pressure
163    REAL(wp) ::  e_s                           !< current saturation vapor pressure
[2312]164    REAL(wp) ::  error                         !< local truncation error in Rosenbrock
165    REAL(wp) ::  k1                            !<
166    REAL(wp) ::  k2                            !<
167    REAL(wp) ::  r_err                         !< First order estimate of Rosenbrock radius
168    REAL(wp) ::  r_ros                         !< Rosenbrock radius
169    REAL(wp) ::  r_ros_ini                     !< initial Rosenbrock radius
170    REAL(wp) ::  r0                            !< gas-kinetic lengthscale
171    REAL(wp) ::  sigma                         !< surface tension of water
172    REAL(wp) ::  thermal_conductivity          !< thermal conductivity for water
[1849]173    REAL(wp) ::  t_int                         !< temperature
174    REAL(wp) ::  w_s                           !< terminal velocity of droplets
[2312]175    REAL(wp) ::  re_p                          !< particle Reynolds number
[1849]176!
[2312]177!-- Parameters for Rosenbrock method (see Verwer et al., 1999)
178    REAL(wp), PARAMETER :: prec = 1.0E-3_wp     !< precision of Rosenbrock solution
179    REAL(wp), PARAMETER :: q_increase = 1.5_wp  !< increase factor in timestep
180    REAL(wp), PARAMETER :: q_decrease = 0.9_wp  !< decrease factor in timestep
181    REAL(wp), PARAMETER :: gamma = 0.292893218814_wp !< = 1.0 - 1.0 / SQRT(2.0)
[849]182!
[1849]183!-- Parameters for terminal velocity
184    REAL(wp), PARAMETER ::  a_rog = 9.65_wp      !< parameter for fall velocity
185    REAL(wp), PARAMETER ::  b_rog = 10.43_wp     !< parameter for fall velocity
186    REAL(wp), PARAMETER ::  c_rog = 0.6_wp       !< parameter for fall velocity
187    REAL(wp), PARAMETER ::  k_cap_rog = 4.0_wp   !< parameter for fall velocity
188    REAL(wp), PARAMETER ::  k_low_rog = 12.0_wp  !< parameter for fall velocity
189    REAL(wp), PARAMETER ::  d0_rog = 0.745_wp    !< separation diameter
[849]190
[1849]191    REAL(wp), DIMENSION(number_of_particles) ::  ventilation_effect     !<
192    REAL(wp), DIMENSION(number_of_particles) ::  new_r                  !<
[849]193
[1849]194    CALL cpu_log( log_point_s(42), 'lpm_droplet_condens', 'start' )
[849]195
196!
[2312]197!-- Absolute temperature
[1849]198    t_int = pt(kp,jp,ip) * ( hyp(kp) / 100000.0_wp )**0.286_wp
[849]199!
[2312]200!-- Saturation vapor pressure (Eq. 10 in Bolton, 1980)
201    e_s = 611.2_wp * EXP( 17.62_wp * ( t_int - 273.15_wp ) / ( t_int - 29.65_wp ) )
[1849]202!
[2312]203!-- Current vapor pressure
204    e_a = q(kp,jp,ip) * hyp(kp) / ( q(kp,jp,ip) + 0.622_wp )
205!
206!-- Thermal conductivity for water (from Rogers and Yau, Table 7.1)
207    thermal_conductivity = 7.94048E-05_wp * t_int + 0.00227011_wp
208!
209!-- Moldecular diffusivity of water vapor in air (Hall und Pruppacher, 1976)
210    diff_coeff           = 0.211E-4_wp * ( t_int / 273.15_wp )**1.94_wp * &
211                           ( 101325.0_wp / hyp(kp) )
212!
213!-- Lengthscale for gas-kinetic effects (from Mordy, 1959, p. 23):
214    r0 = diff_coeff / 0.036_wp * SQRT( 2.0_wp * pi / ( r_v * t_int ) )
215!
216!-- Calculate effects of heat conductivity and diffusion of water vapor on the
217!-- diffusional growth process (usually known as 1.0 / (F_k + F_d) )
218    ddenom  = 1.0_wp / ( rho_l * r_v * t_int / ( e_s * diff_coeff ) +          &
[1849]219                         ( l_v / ( r_v * t_int ) - 1.0_wp ) * rho_l *          &
[2312]220                         l_v / ( thermal_conductivity * t_int )                &
[1849]221                       )
[1359]222    new_r = 0.0_wp
[1849]223!
224!-- Determine ventilation effect on evaporation of large drops
[1359]225    DO  n = 1, number_of_particles
[1849]226
227       IF ( particles(n)%radius >= 4.0E-5_wp  .AND.  e_a / e_s < 1.0_wp )  THEN
[849]228!
[1849]229!--       Terminal velocity is computed for vertical direction (Rogers et al.,
230!--       1993, J. Appl. Meteorol.)
231          diameter = particles(n)%radius * 2000.0_wp !diameter in mm
232          IF ( diameter <= d0_rog )  THEN
233             w_s = k_cap_rog * diameter * ( 1.0_wp - EXP( -k_low_rog * diameter ) )
234          ELSE
235             w_s = a_rog - b_rog * EXP( -c_rog * diameter )
236          ENDIF
[849]237!
[2312]238!--       Calculate droplet's Reynolds number
[1849]239          re_p = 2.0_wp * particles(n)%radius * w_s / molecular_viscosity
[1071]240!
[1359]241!--       Ventilation coefficient (Rogers and Yau, 1989):
242          IF ( re_p > 2.5_wp )  THEN
[1849]243             ventilation_effect(n) = 0.78_wp + 0.28_wp * SQRT( re_p )
[1071]244          ELSE
[1849]245             ventilation_effect(n) = 1.0_wp + 0.09_wp * re_p
[1071]246          ENDIF
[1849]247       ELSE
[1071]248!
[2312]249!--       For small droplets or in supersaturated environments, the ventilation
[1849]250!--       effect does not play a role
251          ventilation_effect(n) = 1.0_wp
[849]252       ENDIF
[1359]253    ENDDO
[849]254
[2312]255    IF( .NOT. curvature_solution_effects ) then
[849]256!
[2312]257!--    Use analytic model for diffusional growth including gas-kinetic
258!--    effects (Mordy, 1959) but without the impact of aerosols.
[1849]259       DO  n = 1, number_of_particles
[2312]260          arg      = ( particles(n)%radius + r0 )**2 + 2.0_wp * dt_3d * ddenom * &
261                                                       ventilation_effect(n) *   &
262                                                       ( e_a / e_s - 1.0_wp )
263          arg      = MAX( arg, ( 0.01E-6 + r0 )**2 )
264          new_r(n) = SQRT( arg ) - r0
[1849]265       ENDDO
[1359]266
[2312]267    ELSE
[1849]268!
[2312]269!--    Integrate the diffusional growth including gas-kinetic (Mordy, 1959),
270!--    as well as curvature and solute effects (e.g., Köhler, 1936).
[849]271!
[2312]272!--    Curvature effect (afactor) with surface tension (sigma) by Straka (2009)
273       sigma = 0.0761_wp - 0.000155_wp * ( t_int - 273.15_wp )
[1071]274!
[2312]275!--    Solute effect (afactor)
276       afactor = 2.0_wp * sigma / ( rho_l * r_v * t_int )
[849]277
[2312]278       DO  n = 1, number_of_particles
[849]279!
[2312]280!--       Solute effect (bfactor)
281          bfactor = vanthoff * rho_s * particles(n)%aux1**3 *                    &
282                    molecular_weight_of_water / ( rho_l * molecular_weight_of_solute )
[1071]283
[2312]284          dt_ros     = particles(n)%aux2  ! use previously stored Rosenbrock timestep
285          dt_ros_sum = 0.0_wp
[1871]286
[2312]287          r_ros     = particles(n)%radius  ! initialize Rosenbrock particle radius
288          r_ros_ini = r_ros
[849]289!
[2312]290!--       Integrate growth equation using a 2nd-order Rosenbrock method
291!--       (see Verwer et al., 1999, Eq. (3.2)). The Rosenbrock method adjusts
292!--       its with internal timestep to minimize the local truncation error.
293          DO WHILE ( dt_ros_sum < dt_3d )
[1071]294
[2312]295             dt_ros = MIN( dt_ros, dt_3d - dt_ros_sum )
[1871]296
[2312]297             DO
[849]298
[2312]299                drdt = ddenom * ventilation_effect(n) * ( e_a / e_s - 1.0 -    &
[1849]300                                                          afactor / r_ros +    &
301                                                          bfactor / r_ros**3   &
[2312]302                                                        ) / ( r_ros + r0 )
[1849]303
[2312]304                d2rdtdr = -ddenom * ventilation_effect(n) * (                  &
305                                                (e_a / e_s - 1.0) * r_ros**4 - &
306                                                afactor * r0 * r_ros**2 -      &
307                                                2.0 * afactor * r_ros**3 +     &
308                                                3.0 * bfactor * r0 +           &
309                                                4.0 * bfactor * r_ros          &
310                                                            )                  &
311                          / ( r_ros**4 * ( r_ros + r0 )**2 )
[849]312
[2312]313                k1    = drdt / ( 1.0 - gamma * dt_ros * d2rdtdr )
[849]314
[2312]315                r_ros = MAX(r_ros_ini + k1 * dt_ros, particles(n)%aux1)
316                r_err = r_ros
[849]317
[2312]318                drdt  = ddenom * ventilation_effect(n) * ( e_a / e_s - 1.0 -   &
319                                                           afactor / r_ros +   &
320                                                           bfactor / r_ros**3  &
321                                                         ) / ( r_ros + r0 )
[849]322
[2312]323                k2 = ( drdt - dt_ros * 2.0 * gamma * d2rdtdr * k1 ) / &
324                     ( 1.0 - dt_ros * gamma * d2rdtdr )
[849]325
[2312]326                r_ros = MAX(r_ros_ini + dt_ros * ( 1.5 * k1 + 0.5 * k2), particles(n)%aux1)
327   !
328   !--          Check error of the solution, and reduce dt_ros if necessary.
329                error = ABS(r_err - r_ros) / r_ros
330                IF ( error .GT. prec )  THEN
331                   dt_ros = SQRT( q_decrease * prec / error ) * dt_ros
332                   r_ros  = r_ros_ini
[849]333                ELSE
[2312]334                   dt_ros_sum = dt_ros_sum + dt_ros
335                   dt_ros     = q_increase * dt_ros
336                   r_ros_ini  = r_ros
337                   EXIT
[849]338                ENDIF
339
[2312]340             END DO
[849]341
[2312]342          END DO !Rosenbrock loop
[849]343!
[2312]344!--       Store new particle radius
345          new_r(n) = r_ros
[849]346!
[2312]347!--       Store internal time step value for next PALM step
348          particles(n)%aux2 = dt_ros
[849]349
[2312]350       ENDDO !Particle loop
[849]351
[2312]352    ENDIF
[849]353
[2312]354    DO  n = 1, number_of_particles
[849]355!
[2312]356!--    Sum up the change in liquid water for the respective grid
357!--    box for the computation of the release/depletion of water vapor
358!--    and heat.
[1890]359       ql_c(kp,jp,ip) = ql_c(kp,jp,ip) + particles(n)%weight_factor *          &
[1359]360                                   rho_l * 1.33333333_wp * pi *                &
361                                   ( new_r(n)**3 - particles(n)%radius**3 ) /  &
[849]362                                   ( rho_surface * dx * dy * dz )
[2312]363!
364!--    Check if the increase in liqid water is not too big. If this is the case,
365!--    the model timestep might be too long.
[1890]366       IF ( ql_c(kp,jp,ip) > 100.0_wp )  THEN
367          WRITE( message_string, * ) 'k=',kp,' j=',jp,' i=',ip,      &
368                       ' ql_c=',ql_c(kp,jp,ip), ' &part(',n,')%wf=', &
[849]369                       particles(n)%weight_factor,' delta_r=',delta_r
370          CALL message( 'lpm_droplet_condensation', 'PA0143', 2, 2, -1, 6, 1 )
371       ENDIF
372!
[2312]373!--    Check if the change in the droplet radius is not too big. If this is the
374!--    case, the model timestep might be too long.
375       delta_r = new_r(n) - particles(n)%radius
376       IF ( delta_r < 0.0_wp  .AND. new_r(n) < 0.0_wp )  THEN
[1890]377          WRITE( message_string, * ) '#1 k=',kp,' j=',jp,' i=',ip,    &
[1849]378                       ' e_s=',e_s, ' e_a=',e_a,' t_int=',t_int,      &
[1890]379                       ' &delta_r=',delta_r,                          &
[849]380                       ' particle_radius=',particles(n)%radius
381          CALL message( 'lpm_droplet_condensation', 'PA0144', 2, 2, -1, 6, 1 )
382       ENDIF
383!
384!--    Sum up the total volume of liquid water (needed below for
385!--    re-calculating the weighting factors)
[1890]386       ql_v(kp,jp,ip) = ql_v(kp,jp,ip) + particles(n)%weight_factor * new_r(n)**3
[849]387!
388!--    Determine radius class of the particle needed for collision
[2312]389       IF ( use_kernel_tables )  THEN
[1359]390          particles(n)%class = ( LOG( new_r(n) ) - rclass_lbound ) /           &
391                               ( rclass_ubound - rclass_lbound ) *             &
[849]392                               radius_classes
393          particles(n)%class = MIN( particles(n)%class, radius_classes )
394          particles(n)%class = MAX( particles(n)%class, 1 )
395       ENDIF
[2312]396 !
397 !--   Store new radius to particle features
398       particles(n)%radius = new_r(n)
[849]399
400    ENDDO
401
402    CALL cpu_log( log_point_s(42), 'lpm_droplet_condens', 'stop' )
403
404
405 END SUBROUTINE lpm_droplet_condensation
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