[3526] | 1 | ! |
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| 2 | ! $Id: so2_to_h2so4.f90 5268 2024-10-23 17:02:39Z evignon $ |
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| 3 | ! |
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[2752] | 4 | SUBROUTINE SO2_TO_H2SO4(pdtphys,tr_seri,t_seri,pplay,paprs,is_strato) |
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[2690] | 5 | |
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| 6 | USE dimphy, ONLY : klon,klev |
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| 7 | USE aerophys |
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[3677] | 8 | USE infotrac_phy |
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[5264] | 9 | USE yomcst_mod_h, ONLY : RG, RD |
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[4601] | 10 | ! lifetime (sec) et O3_clim (VMR) |
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| 11 | USE phys_local_var_mod, ONLY : SO2_lifetime, H2SO4_lifetime, O3_clim, budg_3D_so2_to_h2so4, budg_so2_to_h2so4 |
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| 12 | USE strataer_local_var_mod, ONLY : flag_OH_reduced, flag_H2SO4_photolysis, flag_min_rreduce |
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| 13 | |
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[2690] | 14 | IMPLICIT NONE |
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| 15 | |
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| 16 | !-------------------------------------------------------- |
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| 17 | |
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| 18 | ! transfer variables when calling this routine |
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| 19 | REAL,INTENT(IN) :: pdtphys ! Pas d'integration pour la physique (seconde) |
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| 20 | REAL,DIMENSION(klon,klev,nbtr),INTENT(INOUT) :: tr_seri ! Concentration Traceur [U/KgA] |
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| 21 | REAL,DIMENSION(klon,klev),INTENT(IN) :: t_seri ! Temperature |
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| 22 | REAL,DIMENSION(klon,klev),INTENT(IN) :: pplay ! pression pour le mileu de chaque couche (en Pa) |
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| 23 | REAL,DIMENSION(klon,klev+1),INTENT(IN) :: paprs ! pression pour chaque inter-couche (en Pa) |
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[2695] | 24 | LOGICAL,DIMENSION(klon,klev),INTENT(IN) :: is_strato ! stratospheric flag |
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[2690] | 25 | |
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| 26 | ! local variables in coagulation routine |
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| 27 | INTEGER :: i,j,k,nb,ilon,ilev |
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[4601] | 28 | REAL :: dummyso4toso2,rkho2o3,rkoho3,rkso2oh |
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| 29 | REAL :: rmairdens,rrak0,rrak1,rrate,rreduce |
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| 30 | |
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[2690] | 31 | !--convert SO2 to H2SO4 |
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[2752] | 32 | budg_3D_so2_to_h2so4(:,:)=0.0 |
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| 33 | budg_so2_to_h2so4(:)=0.0 |
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| 34 | |
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[2690] | 35 | DO ilon=1, klon |
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[4601] | 36 | DO ilev=1, klev |
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| 37 | !only in the stratosphere |
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| 38 | IF (is_strato(ilon,ilev)) THEN |
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| 39 | IF (SO2_lifetime(ilon,ilev).GT.0.0 .AND. SO2_lifetime(ilon,ilev).LT.1.E10) THEN |
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| 40 | IF (flag_OH_reduced) THEN |
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| 41 | !--convert SO2 to H2SO4 (slimane) |
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| 42 | ! Reduce OH because of SO2 |
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| 43 | ! d[OH]/dt = k1[HO2][O] +k2[HO2][O3] +k3[HO2][NO] |
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| 44 | ! − (k4[O] +k5[O3] +k6[CO] +ks[SO2])[OH] |
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| 45 | ! In steady-state: d[OH]/dt = 0, so the ratio [OH]/[HO2] = |
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| 46 | ! (k1[O] +k2[O3] +k3[NO]) / (k4[O] +k5[O3] +k6[CO] +ks[SO2]) |
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| 47 | ! In the lower and middle stratosphere, |
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| 48 | ! [OH]/[HO2] ~(k2[O3] +k3[NO]) / (k5[O3] +k6[CO] +ks[SO2]) |
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| 49 | ! CO is only important near the tropopause. NO should not dominate over O3. |
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| 50 | ! So when consideringthe big terms: [OH]/[HO2] ~ ~ k2[O3] / (k5[O3] +ks[SO2]) |
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| 51 | ! For c: control run c (no effect of SO2), [OHc]/[HO2c] ~ ~ k2[O3] / k5[O3] = 1/ Rc |
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| 52 | ! For p: perturbed run (high SO2), [OHp]/[HO2p] ~ ~ k2[O3] / (k5[O3] +ks[SO2]) =1/Rp |
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| 53 | ! If HOx = OH + HO2 = constante, |
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| 54 | ! OHc + HO2c = OHp + HO2p |
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| 55 | ! OHc (1+Rc) = OHp (1+Rp) |
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| 56 | ! OHp = OHc (1+Rc) / (1+Rp) |
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| 57 | ! 1+Rc = (k2[O3] +k5[O3] ) / k2[O3] |
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| 58 | ! 1+Rp = (k2[O3] +k5[O3] +ks[SO2]) / k2[O3] |
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| 59 | ! (1+Rc) / (1+Rp)= (k2[O3] +k5[O3] )/ (k2[O3] +k5[O3] +ks[SO2]) |
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| 60 | ! OHp = OHc * (k(HO2+OH)*[O3] +k(OH+O3)[O3] ) / |
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| 61 | ! (k(HO2+OH)*[O3] +k(OH+O3)[O3] +k(SO2+OH)[SO2]) |
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| 62 | ! Final: OHp = OHc * (k(HO2+O3)*[O3] +k(OH+O3)[O3] ) / |
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| 63 | ! (k(HO2+O3)*[O3] +k(OH+O3)[O3] +k(SO2+OH)[SO2]) |
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| 64 | |
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| 65 | ! latest jpl 2020 |
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| 66 | rkho2o3 = 1.0e-14*exp( -490./t_seri(ilon,ilev) ) |
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| 67 | rkoho3 = 1.7e-12*exp( -940./t_seri(ilon,ilev) ) |
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| 68 | |
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| 69 | ! rkso2oh= so2 + oh + m ->hso3 + m-> h2so4 + m |
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| 70 | ! air density M(molecule/cm3) = Pa/(K*1.38e-19) |
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| 71 | rmairdens = pplay(ilon,ilev)/(t_seri(ilon,ilev)*1.38e-19) |
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| 72 | ! JPL 2020 |
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| 73 | rrak0 = 3.3e-31*( (300./t_seri(ilon,ilev))**4.3 ) |
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| 74 | rrak1 = 1.6e-12 |
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| 75 | rrate = (rrak0*rmairdens) / ( 1. + rrak0*rmairdens/rrak1 ) |
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| 76 | rreduce = 1./( 1. + log10((rrak0*rmairdens)/rrak1)**2 ) |
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| 77 | rkso2oh = rrate*(0.6**rreduce) |
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| 78 | |
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| 79 | ! O3 (molec/cm3): O3_clim in vmr |
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| 80 | rrak0 = O3_clim(ilon,ilev)*rmairdens |
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| 81 | ! SO2 (molec/cm3): convert from kg/kgA |
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| 82 | rrak1 = tr_seri(ilon,ilev,id_SO2_strat) & |
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| 83 | & *pplay(ilon,ilev)/t_seri(ilon,ilev)/RD/1.E6/mSO2mol |
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| 84 | |
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| 85 | IF (rrak1 .GE. 0.0) THEN |
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| 86 | rreduce =( (rkho2o3+rkoho3)*rrak0 + rkso2oh*rrak1 ) / & |
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| 87 | ( (rkho2o3+rkoho3)*rrak0 ) |
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| 88 | ! reduce OH, so extend SO2 lifetime |
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| 89 | rreduce = rreduce*SO2_lifetime(ilon,ilev) |
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| 90 | ELSE |
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| 91 | rreduce = SO2_lifetime(ilon,ilev) |
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| 92 | ENDIF |
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| 93 | ! end of IF (rrak1) THEN |
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| 94 | ELSE |
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| 95 | rreduce = SO2_lifetime(ilon,ilev) |
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| 96 | ENDIF |
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| 97 | ! end of IF (flag_OH_reduced) THEN |
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| 98 | |
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| 99 | ! Check lifetime rreduce < timestep*1.5 (such as SO2 loss > 0.5*SO2) with exp(-1/1.5)=0.52 |
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| 100 | ! Check lifetime rreduce < timestep*3 (such as SO2 loss > 0.28*SO2) with exp(-1/3)=0.72 |
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| 101 | IF(flag_min_rreduce) THEN |
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| 102 | IF (rreduce .LT. (3.*pdtphys)) rreduce = 3.*pdtphys |
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| 103 | ENDIF |
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| 104 | budg_3D_so2_to_h2so4(ilon,ilev)=tr_seri(ilon,ilev,id_SO2_strat)*(1.0-exp(-pdtphys/rreduce)) |
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| 105 | tr_seri(ilon,ilev,id_SO2_strat)=tr_seri(ilon,ilev,id_SO2_strat) - budg_3D_so2_to_h2so4(ilon,ilev) |
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| 106 | tr_seri(ilon,ilev,id_H2SO4_strat)=tr_seri(ilon,ilev,id_H2SO4_strat) + mH2SO4mol/mSO2mol*budg_3D_so2_to_h2so4(ilon,ilev) |
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| 107 | ENDIF |
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| 108 | ! IF (SO2_lifetime(ilon,ilev).GT.0.0 .AND. SO2_lifetime(ilon,ilev).LT.1.E10) THEN |
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| 109 | |
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| 110 | |
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| 111 | IF (flag_H2SO4_photolysis) THEN |
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| 112 | !--convert H2SO4 to SO2 using HCl photolysis (Rinsland et al, 1995) |
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| 113 | ! 4.6e-8 sec-1: J strato taken from Feierabend, et al., Chem. Phys. Lett., 2006. |
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| 114 | ! error before: ...exp(-pdtphys/4.6e-8) so negligible photolysis, |
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| 115 | ! should have been exp(-pdtphys*4.6e-8) |
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| 116 | ! Also: Lane and Kjaergaard: ,J. Phys. Chem. A, 2008 |
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| 117 | ! We find that the dominant photodissociation mechanism of H2SO4 |
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| 118 | ! below 70 km is absorption in the visible region by OH stretching overtone |
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| 119 | ! transitions, whereas above 70 km, absorption of Lyman-R ... |
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| 120 | ! In 2D model, 0.3 Rinsland et al, 1995 but Burkholder, Mills and McKeen say 0.016 |
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| 121 | ! JH2SO4=JHCL*0.3 (*0.016 would be too slow) |
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| 122 | ! test: quick sequential integration for SO2 to H2SO4 and reverse |
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| 123 | |
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| 124 | IF (H2SO4_lifetime(ilon,ilev).GT.0.0 .AND. H2SO4_lifetime(ilon,ilev).LT.1.E10) THEN |
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| 125 | |
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| 126 | rreduce = H2SO4_lifetime(ilon,ilev) |
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| 127 | dummyso4toso2 = 0.0 |
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| 128 | |
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| 129 | ! Check lifetime rreduce < timestep*1.5 (such as H2SO4 loss > 0.5*H2SO4) with exp(-1/1.5)=0.52 |
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| 130 | ! Check lifetime rreduce < timestep*3 (such as H2SO4 loss > 0.28*H2SO4) with exp(-1/3)=0.72 |
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| 131 | IF(flag_min_rreduce) THEN |
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| 132 | IF (rreduce .LT. (3.*pdtphys)) rreduce = 3.*pdtphys |
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| 133 | ENDIF |
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| 134 | dummyso4toso2 = (mSO2mol/mH2SO4mol)*tr_seri(ilon,ilev,id_H2SO4_strat)*(1.0-exp(-pdtphys/rreduce)) |
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| 135 | budg_3D_so2_to_h2so4(ilon,ilev) = budg_3D_so2_to_h2so4(ilon,ilev) + dummyso4toso2 |
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| 136 | tr_seri(ilon,ilev,id_SO2_strat)=tr_seri(ilon,ilev,id_SO2_strat) + dummyso4toso2 |
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| 137 | tr_seri(ilon,ilev,id_H2SO4_strat)=tr_seri(ilon,ilev,id_H2SO4_strat) - (mH2SO4mol/mSO2mol)*dummyso4toso2 |
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| 138 | ENDIF |
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| 139 | ! IF (H2SO4_lifetime(ilon,ilev).GT.0.0 .AND. H2SO4_lifetime(ilon,ilev).LT.1.E10) THEN |
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| 140 | ENDIF |
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| 141 | ! end of IF (flag_H2SO4_photolysis) THEN |
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| 142 | |
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| 143 | !convert budget from kg(SO2)/kgA to kg(S)/m2/layer/s for saving as diagnostic |
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| 144 | budg_3D_so2_to_h2so4(ilon,ilev)=budg_3D_so2_to_h2so4(ilon,ilev)*mSatom/mSO2mol* & |
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| 145 | (paprs(ilon,ilev)-paprs(ilon,ilev+1))/RG/pdtphys |
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| 146 | budg_so2_to_h2so4(ilon)=budg_so2_to_h2so4(ilon)+budg_3D_so2_to_h2so4(ilon,ilev) |
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| 147 | ENDIF |
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| 148 | ! IF (is_strato(ilon,ilev)) THEN |
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| 149 | ENDDO ! DO (klev) |
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| 150 | ENDDO ! DO (klon) |
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| 151 | |
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[2690] | 152 | END SUBROUTINE SO2_TO_H2SO4 |
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