source: palm/trunk/SOURCE/lpm_droplet_collision.f90 @ 869

 SUBROUTINE lpm_droplet_collision

!------------------------------------------------------------------------------!
! Current revisions:
! ------------------
! 
!
! Former revisions:
! -----------------
! $Id: lpm_droplet_collision.f90 850 2012-03-15 12:09:25Z raasch $
!
! 849 2012-03-15 10:35:09Z raasch
! initial revision (former part of advec_particles)
!
!
! Description:
! ------------
! Calculates chang in droplet radius by collision. Droplet collision is
! calculated for each grid box seperately. Collision is parameterized by
! using collision kernels. Three different kernels are available:
! PALM kernel: Kernel is approximated using a method from Rogers and
!              Yau (1989, A Short Course in Cloud Physics, Pergamon Press).
!              All droplets smaller than the treated one are represented by
!              one droplet with mean features. Collision efficiencies are taken
!              from the respective table in Rogers and Yau.
! Hall kernel: Kernel from Hall (1980, J. Atmos. Sci., 2486-2507), which
!              considers collision due to pure gravitational effects.
! Wang kernel: Beside gravitational effects (treated with the Hall-kernel) also
!              the effects of turbulence on the collision are considered using
!              parameterizations of Ayala et al. (2008, New J. Phys., 10,
!              075015) and Wang and Grabowski (2009, Atmos. Sci. Lett., 10,
!              1-8). This kernel includes three possible effects of turbulence:
!              the modification of the relative velocity between the droplets,
!              the effect of preferential concentration, and the enhancement of
!              collision efficiencies. 
!------------------------------------------------------------------------------!

    USE arrays_3d
    USE cloud_parameters
    USE constants
    USE control_parameters
    USE cpulog
    USE grid_variables
    USE indices
    USE interfaces
    USE lpm_collision_kernels_mod
    USE particle_attributes

    IMPLICIT NONE

    INTEGER ::  eclass, i, ii, inc, is, j, jj, js, k, kk, n, pse, psi,        &
                rclass_l, rclass_s

    REAL ::  aa, bb, cc, dd, delta_r, delta_v, gg, epsilon, integral, lw_max, &
             mean_r, ql_int, ql_int_l, ql_int_u, u_int, u_int_l, u_int_u,     &
             v_int, v_int_l, v_int_u, w_int, w_int_l, w_int_u, sl_r3, sl_r4,  &
             x, y

    TYPE(particle_type) ::  tmp_particle


    CALL cpu_log( log_point_s(43), 'lpm_droplet_coll', 'start' )

    DO  i = nxl, nxr
       DO  j = nys, nyn
          DO  k = nzb+1, nzt
!
!--          Collision requires at least two particles in the box
             IF ( prt_count(k,j,i) > 1 )  THEN
!
!--             First, sort particles within the gridbox by their size,
!--             using Shell's method (see Numerical Recipes)
!--             NOTE: In case of using particle tails, the re-sorting of
!--             ----  tails would have to be included here!
                psi = prt_start_index(k,j,i) - 1
                inc = 1
                DO WHILE ( inc <= prt_count(k,j,i) )
                   inc = 3 * inc + 1
                ENDDO

                DO WHILE ( inc > 1 )
                   inc = inc / 3
                   DO  is = inc+1, prt_count(k,j,i)
                      tmp_particle = particles(psi+is)
                      js = is
                      DO WHILE ( particles(psi+js-inc)%radius >             &
                                 tmp_particle%radius )
                         particles(psi+js) = particles(psi+js-inc)
                         js = js - inc
                         IF ( js <= inc )  EXIT
                      ENDDO
                      particles(psi+js) = tmp_particle
                   ENDDO
                ENDDO

                psi = prt_start_index(k,j,i)
                pse = psi + prt_count(k,j,i)-1

!
!--             Now apply the different kernels
                IF ( ( hall_kernel .OR. wang_kernel )  .AND.  &
                     use_kernel_tables )  THEN
!
!--                Fast method with pre-calculated efficiencies for
!--                discrete radius- and dissipation-classes.
!
!--                Determine dissipation class index of this gridbox
                   IF ( wang_kernel )  THEN
                      eclass = INT( diss(k,j,i) * 1.0E4 / 1000.0 * &
                                    dissipation_classes ) + 1
                      epsilon = diss(k,j,i)
                   ELSE
                      epsilon = 0.0
                   ENDIF
                   IF ( hall_kernel .OR. epsilon * 1.0E4 < 0.001 )  THEN
                      eclass = 0   ! Hall kernel is used
                   ELSE
                      eclass = MIN( dissipation_classes, eclass )
                   ENDIF

                   DO  n = pse, psi+1, -1

                      integral = 0.0
                      lw_max   = 0.0
                      rclass_l = particles(n)%class
!
!--                   Calculate growth of collector particle radius using all
!--                   droplets smaller than current droplet 
                      DO  is = psi, n-1

                         rclass_s = particles(is)%class
                         integral = integral +                             &
                                    ( particles(is)%radius**3 *            &
                                      ckernel(rclass_l,rclass_s,eclass) *  &
                                      particles(is)%weight_factor )
!
!--                      Calculate volume of liquid water of the collected
!--                      droplets which is the maximum liquid water available
!--                      for droplet growth   
                         lw_max = lw_max + ( particles(is)%radius**3 * &
                                             particles(is)%weight_factor )

                      ENDDO

!
!--                   Change in radius of collector droplet due to collision
                      delta_r = 1.0 / ( 3.0 * particles(n)%radius**2 ) * &
                                integral * dt_3d * ddx * ddy / dz 

!
!--                   Change in volume of collector droplet due to collision
                      delta_v = particles(n)%weight_factor                  &
                                * ( ( particles(n)%radius + delta_r )**3    &
                                    - particles(n)%radius**3 )

                      IF ( lw_max < delta_v  .AND.  delta_v > 0.0 )  THEN
!-- replace by message call
                         PRINT*, 'Particle has grown to much because the',  &
                                 ' change of volume of particle is larger', &
                                 ' than liquid water available!'

                      ELSEIF ( lw_max == delta_v  .AND.  delta_v > 0.0 ) THEN
!-- can this case really happen??
                         DO  is = psi, n-1

                            particles(is)%weight_factor = 0.0
                            particle_mask(is)  = .FALSE.
                            deleted_particles = deleted_particles + 1

                         ENDDO

                      ELSEIF ( lw_max > delta_v  .AND.  delta_v > 0.0 )  THEN
!
!--                      Calculate new weighting factor of collected droplets
                         DO  is = psi, n-1

                            rclass_s = particles(is)%class
                            particles(is)%weight_factor = &
                               particles(is)%weight_factor - &
                               ( ( ckernel(rclass_l,rclass_s,eclass) * particles(is)%weight_factor &
                                 / integral ) * delta_v )

                            IF ( particles(is)%weight_factor < 0.0 )  THEN
                                  WRITE( message_string, * ) 'negative ',   &
                                                     'weighting factor: ',  &
                                                  particles(is)%weight_factor
                                  CALL message( 'lpm_droplet_collision', '', &
                                                2, 2, -1, 6, 1 )

                            ELSEIF ( particles(is)%weight_factor == 0.0 )  &
                            THEN

                                particles(is)%weight_factor = 0.0
                                particle_mask(is)  = .FALSE.
                                deleted_particles = deleted_particles + 1

                            ENDIF

                         ENDDO

                      ENDIF

                      particles(n)%radius = particles(n)%radius + delta_r
                      ql_vp(k,j,i) = ql_vp(k,j,i) + particles(n)%weight_factor &
                                                    * particles(n)%radius**3

                   ENDDO

                ELSEIF ( ( hall_kernel .OR. wang_kernel )  .AND.  &
                         .NOT. use_kernel_tables )  THEN
!
!--                Collision efficiencies are calculated for every new
!--                grid box. First, allocate memory for kernel table.
!--                Third dimension is 1, because table is re-calculated for
!--                every new dissipation value.
                   ALLOCATE( ckernel(prt_start_index(k,j,i):                 &
                             prt_start_index(k,j,i)+prt_count(k,j,i)-1,      &
                             prt_start_index(k,j,i):                         &
                             prt_start_index(k,j,i)+prt_count(k,j,i)-1,1:1) )
!
!--                Now calculate collision efficiencies for this box
                   CALL recalculate_kernel( i, j, k )

                   DO  n = pse, psi+1, -1

                      integral = 0.0
                      lw_max   = 0.0
!
!--                   Calculate growth of collector particle radius using all
!--                   droplets smaller than current droplet 
                      DO  is = psi, n-1

                         integral = integral + particles(is)%radius**3 * &
                                               ckernel(n,is,1) *         &
                                               particles(is)%weight_factor
!
!--                      Calculate volume of liquid water of the collected
!--                      droplets which is the maximum liquid water available
!--                      for droplet growth   
                         lw_max = lw_max + ( particles(is)%radius**3 * &
                                             particles(is)%weight_factor )

                      ENDDO

!
!--                   Change in radius of collector droplet due to collision
                      delta_r = 1.0 / ( 3.0 * particles(n)%radius**2 ) * &
                                integral * dt_3d * ddx * ddy / dz 

!
!--                   Change in volume of collector droplet due to collision
                      delta_v = particles(n)%weight_factor                  &
                                * ( ( particles(n)%radius + delta_r )**3    &
                                    - particles(n)%radius**3 )

                      IF ( lw_max < delta_v  .AND.  delta_v > 0.0 )  THEN
!-- replace by message call
                         PRINT*, 'Particle has grown to much because the',  &
                                 ' change of volume of particle is larger', &
                                 ' than liquid water available!'

                      ELSEIF ( lw_max == delta_v  .AND.  delta_v > 0.0 ) THEN
!-- can this case really happen??
                         DO  is = psi, n-1

                            particles(is)%weight_factor = 0.0
                            particle_mask(is)  = .FALSE.
                            deleted_particles = deleted_particles + 1

                         ENDDO

                      ELSEIF ( lw_max > delta_v  .AND.  delta_v > 0.0 )  THEN
!
!--                      Calculate new weighting factor of collected droplets
                         DO  is = psi, n-1

                            particles(is)%weight_factor =                   &
                                   particles(is)%weight_factor -            &
                                   ( ckernel(n,is,1) / integral * delta_v * &
                                     particles(is)%weight_factor )

                            IF ( particles(is)%weight_factor < 0.0 )  THEN
                                  WRITE( message_string, * ) 'negative ',   &
                                                     'weighting factor: ',  &
                                                  particles(is)%weight_factor
                                  CALL message( 'lpm_droplet_collision', '', &
                                                2, 2, -1, 6, 1 )

                            ELSEIF ( particles(is)%weight_factor == 0.0 )  &
                            THEN

                                particles(is)%weight_factor = 0.0
                                particle_mask(is)  = .FALSE.
                                deleted_particles = deleted_particles + 1

                            ENDIF

                         ENDDO

                      ENDIF

                      particles(n)%radius = particles(n)%radius + delta_r
                      ql_vp(k,j,i) = ql_vp(k,j,i) + particles(n)%weight_factor &
                                                    * particles(n)%radius**3

                   ENDDO

                   DEALLOCATE( ckernel )

                ELSEIF ( palm_kernel )  THEN
!
!--                PALM collision kernel
!
!--                Calculate the mean radius of all those particles which
!--                are of smaller size than the current particle and
!--                use this radius for calculating the collision efficiency
                   DO  n = psi+prt_count(k,j,i)-1, psi+1, -1

                      sl_r3 = 0.0
                      sl_r4 = 0.0

                      DO is = n-1, psi, -1
                         IF ( particles(is)%radius < particles(n)%radius )  &
                         THEN
                            sl_r3 = sl_r3 + particles(is)%weight_factor     &
                                            * particles(is)%radius**3
                            sl_r4 = sl_r4 + particles(is)%weight_factor     &
                                            * particles(is)%radius**4
                         ENDIF
                      ENDDO

                      IF ( ( sl_r3 ) > 0.0 )  THEN
                         mean_r = ( sl_r4 ) / ( sl_r3 )

                         CALL collision_efficiency_rogers( mean_r,             &
                                                    particles(n)%radius,       &
                                                    effective_coll_efficiency )

                      ELSE
                         effective_coll_efficiency = 0.0
                      ENDIF

                      IF ( effective_coll_efficiency > 1.0  .OR.            &
                           effective_coll_efficiency < 0.0 )                &
                      THEN
                         WRITE( message_string, * )  'collision_efficien' , &
                                   'cy out of range:' ,effective_coll_efficiency
                         CALL message( 'lpm_droplet_collision', 'PA0145', 2, &
                                       2, -1, 6, 1 )
                      ENDIF

!
!--                   Interpolation of ...
                      ii = particles(n)%x * ddx
                      jj = particles(n)%y * ddy
                      kk = ( particles(n)%z + 0.5 * dz ) / dz

                      x  = particles(n)%x - ii * dx
                      y  = particles(n)%y - jj * dy
                      aa = x**2          + y**2
                      bb = ( dx - x )**2 + y**2
                      cc = x**2          + ( dy - y )**2
                      dd = ( dx - x )**2 + ( dy - y )**2
                      gg = aa + bb + cc + dd

                      ql_int_l = ( (gg-aa) * ql(kk,jj,ii)   + (gg-bb) *     &
                                                           ql(kk,jj,ii+1)   &
                                 + (gg-cc) * ql(kk,jj+1,ii) + ( gg-dd ) *   &
                                                           ql(kk,jj+1,ii+1) &
                                 ) / ( 3.0 * gg )

                      ql_int_u = ( (gg-aa) * ql(kk+1,jj,ii)   + (gg-bb) *   &
                                                         ql(kk+1,jj,ii+1)   &
                                 + (gg-cc) * ql(kk+1,jj+1,ii) + (gg-dd) *   &
                                                         ql(kk+1,jj+1,ii+1) &
                                 ) / ( 3.0 * gg )

                      ql_int = ql_int_l + ( particles(n)%z - zu(kk) ) / dz *&
                                          ( ql_int_u - ql_int_l )

!
!--                   Interpolate u velocity-component
                      ii = ( particles(n)%x + 0.5 * dx ) * ddx
                      jj =   particles(n)%y * ddy
                      kk = ( particles(n)%z + 0.5 * dz ) / dz ! only if eqist

                      IF ( ( particles(n)%z - zu(kk) ) > (0.5*dz) ) kk = kk+1

                      x  = particles(n)%x + ( 0.5 - ii ) * dx
                      y  = particles(n)%y - jj * dy
                      aa = x**2          + y**2
                      bb = ( dx - x )**2 + y**2
                      cc = x**2          + ( dy - y )**2
                      dd = ( dx - x )**2 + ( dy - y )**2
                      gg = aa + bb + cc + dd

                      u_int_l = ( (gg-aa) * u(kk,jj,ii)   + (gg-bb) *       &
                                                           u(kk,jj,ii+1)    &
                                + (gg-cc) * u(kk,jj+1,ii) + (gg-dd) *       &
                                                           u(kk,jj+1,ii+1)  &
                                ) / ( 3.0 * gg ) - u_gtrans
                      IF ( kk+1 == nzt+1 )  THEN
                         u_int = u_int_l
                      ELSE
                         u_int_u = ( (gg-aa) * u(kk+1,jj,ii)   + (gg-bb) *  &
                                                          u(kk+1,jj,ii+1)   &
                                   + (gg-cc) * u(kk+1,jj+1,ii) + (gg-dd) *  &
                                                          u(kk+1,jj+1,ii+1) &
                                   ) / ( 3.0 * gg ) - u_gtrans
                         u_int = u_int_l + ( particles(n)%z - zu(kk) ) / dz &
                                           * ( u_int_u - u_int_l )
                      ENDIF

!
!--                   Same procedure for interpolation of the v velocity-com-
!--                   ponent (adopt index k from u velocity-component)
                      ii =   particles(n)%x * ddx
                      jj = ( particles(n)%y + 0.5 * dy ) * ddy

                      x  = particles(n)%x - ii * dx
                      y  = particles(n)%y + ( 0.5 - jj ) * dy
                      aa = x**2          + y**2
                      bb = ( dx - x )**2 + y**2
                      cc = x**2          + ( dy - y )**2
                      dd = ( dx - x )**2 + ( dy - y )**2
                      gg = aa + bb + cc + dd

                      v_int_l = ( ( gg-aa ) * v(kk,jj,ii)   + ( gg-bb ) *   &
                                                            v(kk,jj,ii+1)   &
                                + ( gg-cc ) * v(kk,jj+1,ii) + ( gg-dd ) *   &
                                                            v(kk,jj+1,ii+1) &
                                ) / ( 3.0 * gg ) - v_gtrans
                      IF ( kk+1 == nzt+1 )  THEN
                         v_int = v_int_l
                      ELSE
                         v_int_u = ( (gg-aa) * v(kk+1,jj,ii)   + (gg-bb) *  &
                                                            v(kk+1,jj,ii+1) &
                                   + (gg-cc) * v(kk+1,jj+1,ii) + (gg-dd) *  &
                                                          v(kk+1,jj+1,ii+1) &
                                   ) / ( 3.0 * gg ) - v_gtrans
                         v_int = v_int_l + ( particles(n)%z - zu(kk) ) / dz &
                                           * ( v_int_u - v_int_l )
                      ENDIF

!
!--                   Same procedure for interpolation of the w velocity-com-
!--                   ponent (adopt index i from v velocity-component)
                      jj = particles(n)%y * ddy
                      kk = particles(n)%z / dz

                      x  = particles(n)%x - ii * dx
                      y  = particles(n)%y - jj * dy
                      aa = x**2          + y**2
                      bb = ( dx - x )**2 + y**2
                      cc = x**2          + ( dy - y )**2
                      dd = ( dx - x )**2 + ( dy - y )**2
                      gg = aa + bb + cc + dd

                      w_int_l = ( ( gg-aa ) * w(kk,jj,ii)   + ( gg-bb ) *   &
                                                              w(kk,jj,ii+1) &
                                + ( gg-cc ) * w(kk,jj+1,ii) + ( gg-dd ) *   &
                                                            w(kk,jj+1,ii+1) &
                                ) / ( 3.0 * gg )
                      IF ( kk+1 == nzt+1 )  THEN
                         w_int = w_int_l
                      ELSE
                         w_int_u = ( (gg-aa) * w(kk+1,jj,ii)   + (gg-bb) *  &
                                                            w(kk+1,jj,ii+1) &
                                   + (gg-cc) * w(kk+1,jj+1,ii) + (gg-dd) *  &
                                                          w(kk+1,jj+1,ii+1) &
                                   ) / ( 3.0 * gg )
                         w_int = w_int_l + ( particles(n)%z - zw(kk) ) / dz &
                                           * ( w_int_u - w_int_l )
                      ENDIF

!
!--                   Change in radius due to collision
                      delta_r = effective_coll_efficiency / 3.0             &
                                * pi * sl_r3 * ddx * ddy / dz               &
                                * SQRT( ( u_int - particles(n)%speed_x )**2 &
                                      + ( v_int - particles(n)%speed_y )**2 &
                                      + ( w_int - particles(n)%speed_z )**2 &
                                      ) * dt_3d
!
!--                   Change in volume due to collision
                      delta_v = particles(n)%weight_factor                  &
                                * ( ( particles(n)%radius + delta_r )**3    &
                                    - particles(n)%radius**3 )

!
!--                   Check if collected particles provide enough LWC for
!--                   volume change of collector particle
                      IF ( delta_v >= sl_r3  .AND.  sl_r3 > 0.0 )  THEN

                         delta_r = ( ( sl_r3/particles(n)%weight_factor )   &
                                     + particles(n)%radius**3 )**( 1./3. )  &
                                     - particles(n)%radius

                         DO  is = n-1, psi, -1
                            IF ( particles(is)%radius < &
                                 particles(n)%radius )  THEN
                               particles(is)%weight_factor = 0.0
                               particle_mask(is) = .FALSE.
                               deleted_particles = deleted_particles + 1
                            ENDIF
                         ENDDO

                      ELSE IF ( delta_v < sl_r3  .AND.  sl_r3 > 0.0 )  THEN

                         DO  is = n-1, psi, -1
                            IF ( particles(is)%radius < particles(n)%radius &
                                 .AND.  sl_r3 > 0.0 )  THEN
                               particles(is)%weight_factor =                &
                                            ( ( particles(is)%weight_factor &
                                            * ( particles(is)%radius**3 ) ) &
                                            - ( delta_v                     &
                                            * particles(is)%weight_factor   &
                                            * ( particles(is)%radius**3 )   &
                                            / sl_r3 ) )                     &
                                            / ( particles(is)%radius**3 )

                               IF ( particles(is)%weight_factor < 0.0 )  THEN
                                  WRITE( message_string, * ) 'negative ',   &
                                                  'weighting factor: ',     &
                                                  particles(is)%weight_factor
                                  CALL message( 'lpm_droplet_collision', '', &
                                                2, 2, -1, 6, 1 )
                               ENDIF
                            ENDIF
                         ENDDO

                      ENDIF

                      particles(n)%radius = particles(n)%radius + delta_r
                      ql_vp(k,j,i) = ql_vp(k,j,i) +               &
                                     particles(n)%weight_factor * &
                                     ( particles(n)%radius**3 )
                   ENDDO

                ENDIF  ! collision kernel

                ql_vp(k,j,i) = ql_vp(k,j,i) + particles(psi)%weight_factor  &
                                              * particles(psi)%radius**3


             ELSE IF ( prt_count(k,j,i) == 1 )  THEN

                psi = prt_start_index(k,j,i)
                ql_vp(k,j,i) =  particles(psi)%weight_factor *              &
                                particles(psi)%radius**3
             ENDIF

!
!--          Check if condensation of LWC was conserved during collision
!--          process
             IF ( ql_v(k,j,i) /= 0.0 )  THEN
                IF ( ql_vp(k,j,i) / ql_v(k,j,i) >= 1.0001  .OR.             &
                     ql_vp(k,j,i) / ql_v(k,j,i) <= 0.9999 )  THEN
                   WRITE( message_string, * ) 'LWC is not conserved during',&
                                              ' collision! ',               &
                                              'LWC after condensation: ',   &
                                              ql_v(k,j,i),                  &
                                              ' LWC after collision: ',     &
                                              ql_vp(k,j,i)
                   CALL message( 'lpm_droplet_collision', '', 2, 2, -1, 6, 1 )
                ENDIF
             ENDIF

          ENDDO
       ENDDO
    ENDDO

    CALL cpu_log( log_point_s(43), 'lpm_droplet_coll', 'stop' )


 END SUBROUTINE lpm_droplet_collision