! $Id$ module o3_chem_m IMPLICIT none private o3_prod contains subroutine o3_chem(julien, gmtime, t_seri, zmasse, pdtphys, rlat, rlon, q) ! This procedure evolves the ozone mass fraction through a time ! step taking only chemistry into account. ! All the 2-dimensional arrays are on the partial "physics" grid. ! Their shape is "(/klon, nbp_lev/)". ! Index "(i, :)" is for longitude "rlon(i)", latitude "rlat(i)". use assert_m, only: assert use dimphy, only: klon use regr_pr_comb_coefoz_m, only: c_Mob, a4_mass, a2, r_het_interm use mod_grid_phy_lmdz, only: nbp_lev use nrtype, only: pi integer, intent(in):: julien ! jour julien, 1 <= julien <= 360 real, intent(in):: gmtime ! heure de la journée en fraction de jour real, intent(in):: t_seri(:, :) ! (klon, nbp_lev) temperature, in K real, intent(in):: zmasse(:, :) ! (klon, nbp_lev) ! (column-density of mass of air in a cell, in kg m-2) ! "zmasse(:, k)" is for layer "k".) real, intent(in):: pdtphys ! time step for physics, in s REAL, intent(in):: rlat(:), rlon(:) ! (longitude and latitude of each horizontal position, in degrees) real, intent(inout):: q(:, :) ! (klon, nbp_lev) mass fraction of ozone ! "q(:, k)" is at middle of layer "k".) ! Variables local to the procedure: ! (for "pi") integer k real c(klon, nbp_lev) ! (constant term during a time step in the net mass production ! rate of ozone by chemistry, per unit mass of air, in s-1) ! "c(:, k)" is at middle of layer "k".) real b(klon, nbp_lev) ! (coefficient of "q" in the net mass production ! rate of ozone by chemistry, per unit mass of air, in s-1) ! "b(:, k)" is at middle of layer "k".) real dq_o3_chem(klon, nbp_lev) ! (variation of ozone mass fraction due to chemistry during a time step) ! "dq_o3_chem(:, k)" is at middle of layer "k".) real earth_long ! (longitude vraie de la Terre dans son orbite solaire, par ! rapport au point vernal (21 mars), en degrés) real pmu0(klon) ! mean of cosine of solar zenith angle during "pdtphys" real trash1 real trash2(klon) !------------------------------------------------------------- call assert(klon == (/size(q, 1), size(t_seri, 1), size(zmasse, 1), & size(rlat), size(rlon)/), "o3_chem klon") call assert(nbp_lev == (/size(q, 2), size(t_seri, 2), size(zmasse, 2)/), & "o3_chem nbp_lev") c = c_Mob + a4_mass * t_seri ! Compute coefficient "b": ! Heterogeneous chemistry is only at low temperature: where (t_seri < 195.) b = r_het_interm elsewhere b = 0. end where ! Heterogeneous chemistry is only during daytime: call orbite(real(julien), earth_long, trash1) call zenang(earth_long, gmtime, 0., pdtphys, rlat, rlon, pmu0, trash2) forall (k = 1: nbp_lev) where (pmu0 <= cos(87. / 180. * pi)) b(:, k) = 0. end forall b = b + a2 ! Midpoint method: ! Trial step to the midpoint: dq_o3_chem = o3_prod(q, zmasse, c, b) * pdtphys / 2 ! "Real" step across the whole interval: dq_o3_chem = o3_prod(q + dq_o3_chem, zmasse, c, b) * pdtphys q = q + dq_o3_chem ! Confine the mass fraction: q = min(max(q, 0.), .01) end subroutine o3_chem !************************************************* function o3_prod(q, zmasse, c, b) ! This function computes the production rate of ozone by chemistry. ! All the 2-dimensional arrays are on the partial "physics" grid. ! Their shape is "(/klon, nbp_lev/)". ! Index "(i, :)" is for longitude "rlon(i)", latitude "rlat(i)". use regr_pr_comb_coefoz_m, only: a6_mass use assert_m, only: assert use dimphy, only: klon use mod_grid_phy_lmdz, only: nbp_lev real, intent(in):: q(:, :) ! mass fraction of ozone ! "q(:, k)" is at middle of layer "k".) real, intent(in):: zmasse(:, :) ! (column-density of mass of air in a layer, in kg m-2) ! ("zmasse(:, k)" is for layer "k".) real, intent(in):: c(:, :) ! (constant term during a time step in the net mass production ! rate of ozone by chemistry, per unit mass of air, in s-1) ! "c(:, k)" is at middle of layer "k".) real, intent(in):: b(:, :) ! (coefficient of "q" in the net mass production rate of ozone by ! chemistry, per unit mass of air, in s-1) ! ("b(:, k)" is at middle of layer "k".) real o3_prod(klon, nbp_lev) ! (net mass production rate of ozone by chemistry, per unit mass ! of air, in s-1) ! ("o3_prod(:, k)" is at middle of layer "k".) ! Variables local to the procedure: real sigma_mass(klon, nbp_lev) ! (mass column-density of ozone above point, in kg m-2) ! ("sigma_mass(:, k)" is at middle of layer "k".) integer k !------------------------------------------------------------------- call assert(klon == (/size(q, 1), size(zmasse, 1), size(c, 1), & size(b, 1)/), "o3_prod 1") call assert(nbp_lev == (/size(q, 2), size(zmasse, 2), size(c, 2), & size(b, 2)/), "o3_prod 2") ! Compute the column-density above the base of layer ! "k", and, as a first approximation, take it as column-density ! above the middle of layer "k": sigma_mass(:, nbp_lev) = zmasse(:, nbp_lev) * q(:, nbp_lev) ! top layer do k = nbp_lev - 1, 1, -1 sigma_mass(:, k) = sigma_mass(:, k+1) + zmasse(:, k) * q(:, k) END DO o3_prod = c + b * q + a6_mass * sigma_mass end function o3_prod end module o3_chem_m