SUBROUTINE MIECALC_AER(tau_strat, piz_strat, cg_strat, tau_strat_wave, tau_lw_abs_rrtm, paprs, debut) !-------Mie computations for a size distribution ! of homogeneous spheres. ! !========================================================== !--Ref : Toon and Ackerman, Applied Optics, 1981 ! Stephens, CSIRO, 1979 ! Attention : surdimensionement des tableaux ! to be compiled with double precision option (-r8 on Sun) ! AUTHOR: Olivier Boucher, Christoph Kleinschmitt !-------SIZE distribution properties---------------- !--sigma_g : geometric standard deviation !--r_0 : geometric number mean radius (um)/modal radius !--Ntot : total concentration in m-3 USE phys_local_var_mod, ONLY: tr_seri, mdw, alpha_bin, piz_bin, cg_bin USE aerophys USE aero_mod USE infotrac, ONLY : nbtr, nbtr_bin, nbtr_sulgas, id_SO2_strat USE dimphy USE YOMCST , ONLY : RG, RPI USE mod_phys_lmdz_para, only: gather, scatter, bcast USE mod_grid_phy_lmdz, ONLY : klon_glo USE mod_phys_lmdz_mpi_data, ONLY : is_mpi_root USE print_control_mod, ONLY: prt_level, lunout IMPLICIT NONE ! Variable input LOGICAL,INTENT(IN) :: debut ! le flag de l'initialisation de la physique REAL,DIMENSION(klon,klev+1),INTENT(IN) :: paprs ! pression pour chaque inter-couche (en Pa) ! Stratospheric aerosols optical properties REAL, DIMENSION(klon,klev,nbands_sw_rrtm) :: tau_strat, piz_strat, cg_strat REAL, DIMENSION(klon,klev,nwave_sw+nwave_lw) :: tau_strat_wave REAL, DIMENSION(klon,klev,nbands_lw_rrtm) :: tau_lw_abs_rrtm !! REAL,DIMENSION(klon_glo,klev,nbtr) :: tr_seri_glo ! Concentration Traceur [U/KgA] ! local variables REAL Ntot PARAMETER (Ntot=1.0) LOGICAL, PARAMETER :: refr_ind_interpol = .TRUE. ! set interpolation of refractive index REAL r_0 ! aerosol particle radius [m] INTEGER bin_number, ilon, ilev REAL masse,volume,surface REAL rmin, rmax !----integral bounds in m !------------------------------------- COMPLEX m !----refractive index m=n_r-i*n_i INTEGER Nmax,Nstart !--number of iterations COMPLEX k2, k3, z1, z2 COMPLEX u1,u5,u6,u8 COMPLEX a(1:21000), b(1:21000) COMPLEX I INTEGER n !--loop index REAL nnn COMPLEX nn REAL Q_ext, Q_abs, Q_sca, g, omega !--parameters for radius r REAL x, x_old !--size parameter REAL r, r_lower, r_upper !--radius REAL sigma_sca, sigma_ext, sigma_abs REAL omegatot, gtot !--averaged parameters COMPLEX ksiz2(-1:21000), psiz2(1:21000) COMPLEX nu1z1(1:21010), nu1z2(1:21010) COMPLEX nu3z2(0:21000) REAL number, deltar INTEGER bin, Nbin, it PARAMETER (Nbin=10) LOGICAL smallx !---wavelengths STREAMER INTEGER Nwv, NwvmaxSW PARAMETER (NwvmaxSW=24) REAL lambda(1:NwvmaxSW+1) DATA lambda/0.28E-6, 0.30E-6, 0.33E-6, 0.36E-6, 0.40E-6, & 0.44E-6, 0.48E-6, 0.52E-6, 0.57E-6, 0.64E-6, & 0.69E-6, 0.75E-6, 0.78E-6, 0.87E-6, 1.00E-6, & 1.10E-6, 1.19E-6, 1.28E-6, 1.53E-6, 1.64E-6, & 2.13E-6, 2.38E-6, 2.91E-6, 3.42E-6, 4.00E-6/ !---wavelengths de references !---be careful here the 5th wavelength is 1020 nm INTEGER nb REAL lambda_ref(nwave_sw+nwave_lw) DATA lambda_ref /0.443E-6,0.550E-6,0.670E-6, & 0.765E-6,1.020E-6,10.E-6/ !--LW INTEGER NwvmaxLW PARAMETER (NwvmaxLW=500) REAL Tb, hh, cc, kb PARAMETER (Tb=220.0, hh=6.62607e-34) PARAMETER (cc=2.99792e8, kb=1.38065e-23) !---TOA fluxes - Streamer Cs REAL weight(1:NwvmaxSW), weightLW !c DATA weight/0.839920E1, 0.231208E2, 0.322393E2, 0.465058E2, !c . 0.678199E2, 0.798964E2, 0.771359E2, 0.888472E2, !c . 0.115281E3, 0.727565E2, 0.816992E2, 0.336172E2, !c . 0.914603E2, 0.112706E3, 0.658840E2, 0.524470E2, !c . 0.391067E2, 0.883864E2, 0.276672E2, 0.681812E2, !c . 0.190966E2, 0.250766E2, 0.128704E2, 0.698720E1/ !---TOA fluxes - Tad DATA weight/ 4.20, 11.56, 16.12, 23.25, 33.91, 39.95, 38.57, & 44.42, 57.64, 29.36, 47.87, 16.81, 45.74, 56.35, & 32.94, 26.22, 19.55, 44.19, 13.83, 34.09, 9.55, & 12.54, 6.44, 3.49/ !C---BOA fluxes - Tad !c DATA weight/ 0.01, 4.05, 9.51, 15.99, 26.07, 33.10, 33.07, !c . 39.91, 52.67, 27.89, 43.60, 13.67, 42.22, 40.12, !c . 32.70, 14.44, 19.48, 14.23, 13.43, 16.42, 8.33, !c . 0.95, 0.65, 2.76/ REAL lambda_int(1:NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW), ll REAL dlambda_int(1:NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW), dl REAL n_r(1:NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW) REAL n_i(1:NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW) REAL ilambda, ilambda_prev, ilambda_max, ilambda_min REAL n_r_h2so4, n_i_h2so4 REAL n_r_h2so4_prev, n_i_h2so4_prev REAL final_a(1:NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW) REAL final_g(1:NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW) REAL final_w(1:NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW) INTEGER band, bandSW, bandLW, wavenumber !---wavelengths SW RRTM REAL wv_rrtm_SW(nbands_sw_rrtm+1) DATA wv_rrtm_SW/ 0.185E-6, 0.25E-6, 0.44E-6, 0.69E-6, & 1.19E-6, 2.38E-6, 4.00E-6/ !---wavenumbers and wavelengths LW RRTM REAL wn_rrtm(nbands_lw_rrtm+1), wv_rrtm(nbands_lw_rrtm+1) DATA wn_rrtm/ 10., 250., 500., 630., 700., 820., & 980., 1080., 1180., 1390., 1480., 1800., & 2080., 2250., 2380., 2600., 3000./ !--GCM results REAL gcm_a(nbands_sw_rrtm+nbands_lw_rrtm) REAL gcm_g(nbands_sw_rrtm+nbands_lw_rrtm) REAL gcm_w(nbands_sw_rrtm+nbands_lw_rrtm) REAL gcm_weight_a(nbands_sw_rrtm+nbands_lw_rrtm) REAL gcm_weight_g(nbands_sw_rrtm+nbands_lw_rrtm) REAL gcm_weight_w(nbands_sw_rrtm+nbands_lw_rrtm) REAL ss_a(nbands_sw_rrtm+nbands_lw_rrtm+nwave_sw+nwave_lw) REAL ss_w(nbands_sw_rrtm+nbands_lw_rrtm+nwave_sw+nwave_lw) REAL ss_g(nbands_sw_rrtm+nbands_lw_rrtm+nwave_sw+nwave_lw) INTEGER, PARAMETER :: nb_lambda_h2so4=62 REAL, DIMENSION (nb_lambda_h2so4,4) :: ref_ind !-- fichier h2so4_0.75_300.00_hummel_1988_p_q.dat ! -- wavenumber (cm-1), wavelength (um), n_r, n_i DATA ref_ind / & 200.000, 50.0000, 2.01000, 6.5000E-01, & 250.000, 40.0000, 1.94000, 6.3000E-01, & 285.714, 35.0000, 1.72000, 5.2000E-01, & 333.333, 30.0000, 1.73000, 2.9000E-01, & 358.423, 27.9000, 1.78000, 2.5000E-01, & 400.000, 25.0000, 1.84000, 2.4000E-01, & 444.444, 22.5000, 1.82000, 2.9000E-01, & 469.484, 21.3000, 1.79000, 2.5000E-01, & 500.000, 20.0000, 1.81000, 2.3000E-01, & 540.541, 18.5000, 1.92700, 3.0200E-01, & 555.556, 18.0000, 1.95000, 4.1000E-01, & 581.395, 17.2000, 1.72400, 5.9000E-01, & 609.756, 16.4000, 1.52000, 4.1400E-01, & 666.667, 15.0000, 1.59000, 2.1100E-01, & 675.676, 14.8000, 1.61000, 2.0500E-01, & 714.286, 14.0000, 1.64000, 1.9500E-01, & 769.231, 13.0000, 1.69000, 1.9500E-01, & 800.000, 12.5000, 1.74000, 1.9800E-01, & 869.565, 11.5000, 1.89000, 3.7400E-01, & 909.091, 11.0000, 1.67000, 4.8500E-01, & 944.198, 10.5910, 1.72000, 3.4000E-01, & 1000.000, 10.0000, 1.89000, 4.5500E-01, & 1020.408, 9.8000, 1.91000, 6.8000E-01, & 1052.632, 9.5000, 1.67000, 7.5000E-01, & 1086.957, 9.2000, 1.60000, 5.8600E-01, & 1111.111, 9.0000, 1.65000, 6.3300E-01, & 1149.425, 8.7000, 1.53000, 7.7200E-01, & 1176.471, 8.5000, 1.37000, 7.5500E-01, & 1219.512, 8.2000, 1.20000, 6.4500E-01, & 1265.823, 7.9000, 1.14000, 4.8800E-01, & 1388.889, 7.2000, 1.21000, 1.7600E-01, & 1538.462, 6.5000, 1.37000, 1.2800E-01, & 1612.903, 6.2000, 1.42400, 1.6500E-01, & 1666.667, 6.0000, 1.42500, 1.9500E-01, & 1818.182, 5.5000, 1.33700, 1.8300E-01, & 2000.000, 5.0000, 1.36000, 1.2100E-01, & 2222.222, 4.5000, 1.38500, 1.2000E-01, & 2500.000, 4.0000, 1.39800, 1.2600E-01, & 2666.667, 3.7500, 1.39600, 1.3100E-01, & 2857.143, 3.5000, 1.37600, 1.5800E-01, & 2948.113, 3.3920, 1.35200, 1.5900E-01, & 3125.000, 3.2000, 1.31100, 1.3500E-01, & 3333.333, 3.0000, 1.29300, 9.5500E-02, & 3703.704, 2.7000, 1.30300, 5.7000E-03, & 4000.000, 2.5000, 1.34400, 3.7600E-03, & 4444.444, 2.2500, 1.37000, 1.8000E-03, & 5000.000, 2.0000, 1.38400, 1.2600E-03, & 5555.556, 1.8000, 1.39000, 5.5000E-04, & 6510.417, 1.5360, 1.40300, 1.3700E-04, & 7692.308, 1.3000, 1.41000, 1.0000E-05, & 9433.962, 1.0600, 1.42000, 1.5000E-06, & 11627.907, 0.8600, 1.42500, 1.7900E-07, & 14409.222, 0.6940, 1.42800, 1.9900E-08, & 15797.788, 0.6330, 1.42900, 1.4700E-08, & 18181.818, 0.5500, 1.43000, 1.0000E-08, & 19417.476, 0.5150, 1.43100, 1.0000E-08, & 20491.803, 0.4880, 1.43200, 1.0000E-08, & 25000.000, 0.4000, 1.44000, 1.0000E-08, & 29673.591, 0.3370, 1.45900, 1.0000E-08, & 33333.333, 0.3000, 1.46900, 1.0000E-08, & 40000.000, 0.2500, 1.48400, 1.0000E-08, & 50000.000, 0.2000, 1.49800, 1.0000E-08 / !--------------------------------------------------------- IF (debut) THEN !--initialising dry diameters to geometrically spaced mass/volume (see Jacobson 1994) mdw(1)=mdwmin IF (V_rat.LT.1.62) THEN ! compensate for dip in second bin for lower volume ratio mdw(2)=mdw(1)*2.**(1./3.) DO it=3, nbtr_bin mdw(it)=mdw(it-1)*V_rat**(1./3.) ENDDO ELSE DO it=2, nbtr_bin mdw(it)=mdw(it-1)*V_rat**(1./3.) ENDDO ENDIF PRINT *,'init mdw=', mdw !--compute particle radius for a composition of 75% H2SO4 / 25% H2O at T=293K DO bin_number=1, nbtr_bin r_0=(dens_aer_dry/dens_aer_ref/0.75)**(1./3.)*mdw(bin_number)/2. !--integral boundaries set to bin boundaries rmin=r_0/sqrt(V_rat**(1./3.)) rmax=r_0*sqrt(V_rat**(1./3.)) !--set up SW DO Nwv=1, NwvmaxSW lambda_int(Nwv)=( lambda(Nwv)+lambda(Nwv+1) ) /2. ENDDO DO nb=1, nwave_sw+nwave_lw lambda_int(NwvmaxSW+nb)=lambda_ref(nb) ENDDO !--set up LW !--conversion wavenumber in cm-1 to wavelength in m DO Nwv=1, nbands_lw_rrtm+1 wv_rrtm(Nwv)=10000./wn_rrtm(Nwv)*1.e-6 ENDDO DO Nwv=1, NwvmaxLW lambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv)= & exp( log(wv_rrtm(1))+float(Nwv-1)/float(NwvmaxLW-1)* & (log(wv_rrtm(nbands_lw_rrtm+1))-log(wv_rrtm(1))) ) ENDDO !--computing the dlambdas Nwv=1 dlambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv)= & & lambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv)- & & lambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv+1) DO Nwv=2, NwvmaxLW-1 dlambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv)= & & (lambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv-1)- & & lambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv+1))/2. ENDDO Nwv=NwvmaxLW dlambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv)= & & lambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv-1)- & & lambda_int(NwvmaxSW+nwave_sw+nwave_lw+Nwv) IF (refr_ind_interpol) THEN ilambda_max=ref_ind(1,2)/1.e6 !--in m ilambda_min=ref_ind(nb_lambda_h2so4,2)/1.e6 !--in m DO Nwv=1, NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW IF (lambda_int(Nwv).GT.ilambda_max) THEN !for lambda out of data range, take boundary values n_r(Nwv)=ref_ind(1,3) n_i(Nwv)=ref_ind(1,4) ELSEIF (lambda_int(Nwv).LE.ilambda_min) THEN n_r(Nwv)=ref_ind(nb_lambda_h2so4,3) n_i(Nwv)=ref_ind(nb_lambda_h2so4,4) ELSE DO nb=2,nb_lambda_h2so4 ilambda=ref_ind(nb,2)/1.e6 ilambda_prev=ref_ind(nb-1,2)/1.e6 n_r_h2so4=ref_ind(nb,3) n_r_h2so4_prev=ref_ind(nb-1,3) n_i_h2so4=ref_ind(nb,4) n_i_h2so4_prev=ref_ind(nb-1,4) IF (lambda_int(Nwv).GT.ilambda.AND. & lambda_int(Nwv).LE.ilambda_prev) THEN !--- linear interpolation n_r(Nwv)=n_r_h2so4+(lambda_int(Nwv)-ilambda)/ & (ilambda_prev-ilambda)*(n_r_h2so4_prev-n_r_h2so4) n_i(Nwv)=n_i_h2so4+(lambda_int(Nwv)-ilambda)/ & (ilambda_prev-ilambda)*(n_i_h2so4_prev-n_i_h2so4) ENDIF ENDDO ENDIF ENDDO ELSE !-- no refr_ind_interpol, closest neighbour from upper wavelength DO Nwv=1, NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW n_r(Nwv)=ref_ind(1,3) n_i(Nwv)=ref_ind(1,4) DO nb=2,nb_lambda_h2so4 IF (ref_ind(nb,2)/1.e6.GT.lambda_int(Nwv)) THEN !--- step function n_r(Nwv)=ref_ind(nb,3) n_i(Nwv)=ref_ind(nb,4) ENDIF ENDDO ENDDO ENDIF !---Loop on wavelengths DO Nwv=1, NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW m=CMPLX(n_r(Nwv),-n_i(Nwv)) I=CMPLX(0.,1.) sigma_sca=0.0 sigma_ext=0.0 sigma_abs=0.0 gtot=0.0 omegatot=0.0 masse = 0.0 volume=0.0 surface=0.0 DO bin=1, Nbin !---loop on size bins r_lower=exp(log(rmin)+FLOAT(bin-1)/FLOAT(Nbin)*(log(rmax)-log(rmin))) r_upper=exp(log(rmin)+FLOAT(bin)/FLOAT(Nbin)*(log(rmax)-log(rmin))) deltar=r_upper-r_lower r=sqrt(r_lower*r_upper) x=2.*RPI*r/lambda_int(Nwv) !we impose a minimum value for x and extrapolate quantities for small x values smallx = .FALSE. IF (x.LT.0.001) THEN smallx = .TRUE. x_old = x x = 0.001 ENDIF number=Ntot*deltar/(rmax-rmin) !dN/dr constant over tracer bin ! masse=masse +4./3.*RPI*(r**3)*number*deltar*ropx*1.E3 !--g/m3 volume=volume+4./3.*RPI*(r**3)*number*deltar surface=surface+4.*RPI*r**2*number*deltar k2=m k3=CMPLX(1.0,0.0) z2=CMPLX(x,0.0) z1=m*z2 IF (0.0.LE.x.AND.x.LE.8.) THEN Nmax=INT(x+4*x**(1./3.)+1.)+2 ELSEIF (8..LT.x.AND.x.LT.4200.) THEN Nmax=INT(x+4.05*x**(1./3.)+2.)+1 ELSEIF (4200..LE.x.AND.x.LE.20000.) THEN Nmax=INT(x+4*x**(1./3.)+2.)+1 ELSE PRINT *, 'x out of bound, x=', x STOP ENDIF Nstart=Nmax+100 !-----------loop for nu1z1, nu1z2 nu1z1(Nstart)=CMPLX(0.0,0.0) nu1z2(Nstart)=CMPLX(0.0,0.0) DO n=Nstart-1, 1 , -1 nn=CMPLX(FLOAT(n),0.0) nu1z1(n)=(nn+1.)/z1 - 1./( (nn+1.)/z1 + nu1z1(n+1) ) nu1z2(n)=(nn+1.)/z2 - 1./( (nn+1.)/z2 + nu1z2(n+1) ) ENDDO !------------loop for nu3z2 nu3z2(0)=-I DO n=1, Nmax nn=CMPLX(FLOAT(n),0.0) nu3z2(n)=-nn/z2 + 1./ (nn/z2 - nu3z2(n-1) ) ENDDO !-----------loop for psiz2 and ksiz2 (z2) ksiz2(-1)=COS(REAL(z2))-I*SIN(REAL(z2)) ksiz2(0)=SIN(REAL(z2))+I*COS(REAL(z2)) DO n=1,Nmax nn=CMPLX(FLOAT(n),0.0) ksiz2(n)=(2.*nn-1.)/z2 * ksiz2(n-1) - ksiz2(n-2) psiz2(n)=CMPLX(REAL(ksiz2(n)),0.0) ENDDO !-----------loop for a(n) and b(n) DO n=1, Nmax u1=k3*nu1z1(n) - k2*nu1z2(n) u5=k3*nu1z1(n) - k2*nu3z2(n) u6=k2*nu1z1(n) - k3*nu1z2(n) u8=k2*nu1z1(n) - k3*nu3z2(n) a(n)=psiz2(n)/ksiz2(n) * u1/u5 b(n)=psiz2(n)/ksiz2(n) * u6/u8 ENDDO !-----------------final loop-------------- Q_ext=0.0 Q_sca=0.0 g=0.0 DO n=Nmax-1,1,-1 nnn=FLOAT(n) Q_ext=Q_ext+ (2.*nnn+1.) * REAL( a(n)+b(n) ) Q_sca=Q_sca+ (2.*nnn+1.) * & REAL( a(n)*CONJG(a(n)) + b(n)*CONJG(b(n)) ) g=g + nnn*(nnn+2.)/(nnn+1.) * & REAL( a(n)*CONJG(a(n+1))+b(n)*CONJG(b(n+1)) ) + & (2.*nnn+1.)/nnn/(nnn+1.) * REAL(a(n)*CONJG(b(n))) ENDDO Q_ext=2./x**2 * Q_ext Q_sca=2./x**2 * Q_sca !--extrapolation in case of small x values IF (smallx) THEN Q_ext = x_old/x * Q_ext Q_sca = x_old/x * Q_sca ENDIF Q_abs=Q_ext-Q_sca IF (AIMAG(m).EQ.0.0) Q_abs=0.0 omega=Q_sca/Q_ext ! g is wrong in the smallx case (but that does not matter as long as we ignore LW scattering) g=g*4./x**2/Q_sca sigma_sca=sigma_sca+r**2*Q_sca*number sigma_abs=sigma_abs+r**2*Q_abs*number sigma_ext=sigma_ext+r**2*Q_ext*number omegatot=omegatot+r**2*Q_ext*omega*number gtot =gtot+r**2*Q_sca*g*number ENDDO !---bin !------------------------------------------------------------------ sigma_sca=RPI*sigma_sca sigma_abs=RPI*sigma_abs sigma_ext=RPI*sigma_ext gtot=RPI*gtot/sigma_sca omegatot=RPI*omegatot/sigma_ext final_g(Nwv)=gtot final_w(Nwv)=omegatot ! final_a(Nwv)=sigma_ext/masse final_a(Nwv)=sigma_ext !extinction/absorption cross section per particle ENDDO !--loop on wavelength !---averaging over LMDZ wavebands DO band=1, nbands_sw_rrtm+nbands_lw_rrtm gcm_a(band)=0.0 gcm_g(band)=0.0 gcm_w(band)=0.0 gcm_weight_a(band)=0.0 gcm_weight_g(band)=0.0 gcm_weight_w(band)=0.0 ENDDO !---band 1 is now in the UV, so we take the first wavelength as being representative DO Nwv=1,1 bandSW=1 gcm_a(bandSW)=gcm_a(bandSW)+final_a(Nwv)*weight(Nwv) gcm_weight_a(bandSW)=gcm_weight_a(bandSW)+weight(Nwv) gcm_w(bandSW)=gcm_w(bandSW)+final_w(Nwv)*final_a(Nwv)*weight(Nwv) gcm_weight_w(bandSW)=gcm_weight_w(bandSW)+final_a(Nwv)*weight(Nwv) gcm_g(bandSW)=gcm_g(bandSW)+final_g(Nwv)*final_a(Nwv)*final_w(Nwv)*weight(Nwv) gcm_weight_g(bandSW)=gcm_weight_g(bandSW)+final_a(Nwv)*final_w(Nwv)*weight(Nwv) ENDDO DO Nwv=1,NwvmaxSW IF (lambda_int(Nwv).LE.wv_rrtm_SW(3)) THEN !--RRTM spectral interval 2 bandSW=2 ELSEIF (lambda_int(Nwv).LE.wv_rrtm_SW(4)) THEN !--RRTM spectral interval 3 bandSW=3 ELSEIF (lambda_int(Nwv).LE.wv_rrtm_SW(5)) THEN !--RRTM spectral interval 4 bandSW=4 ELSEIF (lambda_int(Nwv).LE.wv_rrtm_SW(6)) THEN !--RRTM spectral interval 5 bandSW=5 ELSE !--RRTM spectral interval 6 bandSW=6 ENDIF gcm_a(bandSW)=gcm_a(bandSW)+final_a(Nwv)*weight(Nwv) gcm_weight_a(bandSW)=gcm_weight_a(bandSW)+weight(Nwv) gcm_w(bandSW)=gcm_w(bandSW)+final_w(Nwv)*final_a(Nwv)*weight(Nwv) gcm_weight_w(bandSW)=gcm_weight_w(bandSW)+final_a(Nwv)*weight(Nwv) gcm_g(bandSW)=gcm_g(bandSW)+final_g(Nwv)*final_a(Nwv)*final_w(Nwv)*weight(Nwv) gcm_weight_g(bandSW)=gcm_weight_g(bandSW)+final_a(Nwv)*final_w(Nwv)*weight(Nwv) ENDDO DO Nwv=NwvmaxSW+nwave_sw+nwave_lw+1,NwvmaxSW+nwave_sw+nwave_lw+NwvmaxLW ll=lambda_int(Nwv) dl=dlambda_int(Nwv) weightLW=1./ll**5./(exp(hh*cc/kb/Tb/ll)-1.)*dl bandLW=1 !--default value starting from the highest lambda DO band=2, nbands_lw_rrtm IF (ll.LT.wv_rrtm(band)) THEN !--as long as bandLW=band ENDIF ENDDO gcm_a(nbands_sw_rrtm+bandLW)=gcm_a(nbands_sw_rrtm+bandLW)+final_a(Nwv)* & (1.-final_w(Nwv))*weightLW gcm_weight_a(nbands_sw_rrtm+bandLW)=gcm_weight_a(nbands_sw_rrtm+bandLW)+weightLW gcm_w(nbands_sw_rrtm+bandLW)=gcm_w(nbands_sw_rrtm+bandLW)+final_w(Nwv)* & final_a(Nwv)*weightLW gcm_weight_w(nbands_sw_rrtm+bandLW)=gcm_weight_w(nbands_sw_rrtm+bandLW)+ & final_a(Nwv)*weightLW gcm_g(nbands_sw_rrtm+bandLW)=gcm_g(nbands_sw_rrtm+bandLW)+final_g(Nwv)* & final_a(Nwv)*final_w(Nwv)*weightLW gcm_weight_g(nbands_sw_rrtm+bandLW)=gcm_weight_g(nbands_sw_rrtm+bandLW)+ & final_a(Nwv)*final_w(Nwv)*weightLW ENDDO DO band=1, nbands_sw_rrtm+nbands_lw_rrtm gcm_a(band)=gcm_a(band)/gcm_weight_a(band) gcm_w(band)=gcm_w(band)/gcm_weight_w(band) gcm_g(band)=gcm_g(band)/gcm_weight_g(band) ss_a(band)=gcm_a(band) ss_w(band)=gcm_w(band) ss_g(band)=gcm_g(band) ENDDO DO nb=1, nwave_sw+nwave_lw ss_a(nbands_sw_rrtm+nbands_lw_rrtm+nb)=final_a(NwvmaxSW+nb) ss_w(nbands_sw_rrtm+nbands_lw_rrtm+nb)=final_w(NwvmaxSW+nb) ss_g(nbands_sw_rrtm+nbands_lw_rrtm+nb)=final_g(NwvmaxSW+nb) ENDDO DO nb=1,nbands_sw_rrtm+nbands_lw_rrtm+nwave_sw+nwave_lw alpha_bin(nb,bin_number)=ss_a(nb) !extinction/absorption cross section per particle piz_bin(nb,bin_number)=ss_w(nb) cg_bin(nb,bin_number)=ss_g(nb) ENDDO ENDDO !loop over tracer bins !!$OMP END MASTER ! CALL bcast(alpha_bin) ! CALL bcast(piz_bin) ! CALL bcast(cg_bin) !!$OMP BARRIER !set to default values at first time step (tr_seri still zero) tau_strat(:,:,:)=1.e-15 piz_strat(:,:,:)=1.0 cg_strat(:,:,:)=0.0 tau_lw_abs_rrtm(:,:,:)=1.e-15 tau_strat_wave(:,:,:)=1.e-15 ELSE !-- not debut !--compute optical properties of actual size distribution (from tr_seri) DO ilon=1,klon DO ilev=1, klev DO nb=1,nbands_sw_rrtm tau_strat(ilon,ilev,nb)=0.0 DO bin_number=1, nbtr_bin tau_strat(ilon,ilev,nb)=tau_strat(ilon,ilev,nb)+alpha_bin(nb,bin_number) & *tr_seri(ilon,ilev,bin_number+nbtr_sulgas)*(paprs(ilon,ilev)-paprs(ilon,ilev+1))/RG ENDDO piz_strat(ilon,ilev,nb)=0.0 DO bin_number=1, nbtr_bin piz_strat(ilon,ilev,nb)=piz_strat(ilon,ilev,nb)+piz_bin(nb,bin_number)*alpha_bin(nb,bin_number) & *tr_seri(ilon,ilev,bin_number+nbtr_sulgas)*(paprs(ilon,ilev)-paprs(ilon,ilev+1))/RG ENDDO piz_strat(ilon,ilev,nb)=piz_strat(ilon,ilev,nb)/MAX(tau_strat(ilon,ilev,nb),1.e-15) cg_strat(ilon,ilev,nb)=0.0 DO bin_number=1, nbtr_bin cg_strat(ilon,ilev,nb)=cg_strat(ilon,ilev,nb)+cg_bin(nb,bin_number)*piz_bin(nb,bin_number)*alpha_bin(nb,bin_number) & *tr_seri(ilon,ilev,bin_number+nbtr_sulgas)*(paprs(ilon,ilev)-paprs(ilon,ilev+1))/RG ENDDO cg_strat(ilon,ilev,nb)=cg_strat(ilon,ilev,nb)/MAX(tau_strat(ilon,ilev,nb)*piz_strat(ilon,ilev,nb),1.e-15) ENDDO DO nb=1,nbands_lw_rrtm tau_lw_abs_rrtm(ilon,ilev,nb)=0.0 DO bin_number=1, nbtr_bin tau_lw_abs_rrtm(ilon,ilev,nb)=tau_lw_abs_rrtm(ilon,ilev,nb)+alpha_bin(nbands_sw_rrtm+nb,bin_number) & *tr_seri(ilon,ilev,bin_number+nbtr_sulgas)*(paprs(ilon,ilev)-paprs(ilon,ilev+1))/RG ENDDO ENDDO DO nb=1,nwave_sw+nwave_lw tau_strat_wave(ilon,ilev,nb)=0.0 DO bin_number=1, nbtr_bin tau_strat_wave(ilon,ilev,nb)=tau_strat_wave(ilon,ilev,nb)+alpha_bin(nbands_sw_rrtm+nbands_lw_rrtm+nb,bin_number) & *tr_seri(ilon,ilev,bin_number+nbtr_sulgas)*(paprs(ilon,ilev)-paprs(ilon,ilev+1))/RG ENDDO ENDDO ENDDO ENDDO ENDIF !debut END SUBROUTINE MIECALC_AER