[2428] | 1 | ! $Revision: 88 $, $Date: 2013-11-13 15:08:38 +0100 (mer. 13 nov. 2013) $ |
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| 2 | ! $URL: http://cfmip-obs-sim.googlecode.com/svn/stable/v1.4.0/quickbeam/zeff.f90 $ |
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[1262] | 3 | subroutine zeff(freq,D,N,nsizes,k2,tt,ice,xr,z_eff,z_ray,kr,qe,qs,rho_e) |
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| 4 | use math_lib |
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| 5 | use optics_lib |
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| 6 | implicit none |
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| 7 | |
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| 8 | ! Purpose: |
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| 9 | ! Simulates radar return of a volume given DSD of spheres |
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| 10 | ! Part of QuickBeam v1.03 by John Haynes |
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| 11 | ! http://reef.atmos.colostate.edu/haynes/radarsim |
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| 12 | ! |
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| 13 | ! Inputs: |
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| 14 | ! [freq] radar frequency (GHz) |
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| 15 | ! [D] discrete drop sizes (um) |
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| 16 | ! [N] discrete concentrations (cm^-3 um^-1) |
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| 17 | ! [nsizes] number of discrete drop sizes |
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| 18 | ! [k2] |K|^2, -1=use frequency dependent default |
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[2428] | 19 | ! [tt] hydrometeor temperature (K) |
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[1262] | 20 | ! [ice] indicates volume consists of ice |
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| 21 | ! [xr] perform Rayleigh calculations? |
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| 22 | ! [qe] if using a mie table, these contain ext/sca ... |
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| 23 | ! [qs] ... efficiencies; otherwise set to -1 |
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| 24 | ! [rho_e] medium effective density (kg m^-3) (-1 = pure) |
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| 25 | ! |
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| 26 | ! Outputs: |
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| 27 | ! [z_eff] unattenuated effective reflectivity factor (mm^6/m^3) |
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| 28 | ! [z_ray] reflectivity factor, Rayleigh only (mm^6/m^3) |
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| 29 | ! [kr] attenuation coefficient (db km^-1) |
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| 30 | ! |
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| 31 | ! Created: |
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| 32 | ! 11/28/05 John Haynes (haynes@atmos.colostate.edu) |
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| 33 | |
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| 34 | ! ----- INPUTS ----- |
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| 35 | integer, intent(in) :: ice, xr |
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| 36 | integer, intent(in) :: nsizes |
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[5095] | 37 | real*8, intent(in) :: freq,D(nsizes),N(nsizes),tt,qe(nsizes), & |
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[1262] | 38 | qs(nsizes), rho_e(nsizes) |
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[5095] | 39 | real*8, intent(inout) :: k2 |
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[1262] | 40 | |
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| 41 | ! ----- OUTPUTS ----- |
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[5095] | 42 | real*8, intent(out) :: z_eff,z_ray,kr |
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[1262] | 43 | |
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| 44 | ! ----- INTERNAL ----- |
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| 45 | integer :: & |
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[2428] | 46 | correct_for_rho ! correct for density flag |
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[5095] | 47 | real*8, dimension(nsizes) :: & |
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[2428] | 48 | D0, & ! D in (m) |
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| 49 | N0, & ! N in m^-3 m^-1 |
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| 50 | sizep, & ! size parameter |
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| 51 | qext, & ! extinction efficiency |
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| 52 | qbsca, & ! backscatter efficiency |
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| 53 | rho_ice, & ! bulk density ice (kg m^-3) |
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| 54 | f ! ice fraction |
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[5095] | 55 | real*8, dimension(nsizes) :: xtemp |
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| 56 | real*8 :: & |
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[2428] | 57 | wl, & ! wavelength (m) |
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[1262] | 58 | cr ! kr(dB/km) = cr * kr(1/km) |
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[5095] | 59 | complex*16 :: & |
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[2428] | 60 | m ! complex index of refraction of bulk form |
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[5095] | 61 | complex*16, dimension(nsizes) :: & |
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[2428] | 62 | m0 ! complex index of refraction |
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[1262] | 63 | |
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[5095] | 64 | integer*4 :: i,one |
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| 65 | real*8 :: pi |
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| 66 | real*8 :: eta_sum, eta_mie, const, z0_eff, z0_ray, k_sum, & |
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[2428] | 67 | n_r, n_i, dqv(1), dqsc, dg, dph(1) |
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[5095] | 68 | integer*4 :: err |
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| 69 | complex*16 :: Xs1(1), Xs2(1) |
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[1262] | 70 | |
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| 71 | one=1 |
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| 72 | pi = acos(-1.0) |
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| 73 | rho_ice(:) = 917 |
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| 74 | z0_ray = 0.0 |
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| 75 | |
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| 76 | ! // conversions |
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[2428] | 77 | D0 = d*1E-6 ! m |
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| 78 | N0 = n*1E12 ! 1/(m^3 m) |
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| 79 | wl = 2.99792458/(freq*10) ! m |
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[1262] | 80 | |
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| 81 | ! // dielectric constant |k^2| defaults |
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| 82 | if (k2 < 0) then |
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| 83 | k2 = 0.933 |
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| 84 | if (abs(94.-freq) < 3.) k2=0.75 |
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| 85 | if (abs(35.-freq) < 3.) k2=0.88 |
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| 86 | if (abs(13.8-freq) < 3.) k2=0.925 |
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| 87 | endif |
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| 88 | |
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| 89 | if (qe(1) < -9) then |
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| 90 | |
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| 91 | ! // get the refractive index of the bulk hydrometeors |
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| 92 | if (ice == 0) then |
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| 93 | call m_wat(freq,tt,n_r,n_i) |
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| 94 | else |
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| 95 | call m_ice(freq,tt,n_r,n_i) |
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| 96 | endif |
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| 97 | m = cmplx(n_r,-n_i) |
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| 98 | m0(:) = m |
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| 99 | |
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| 100 | correct_for_rho = 0 |
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| 101 | if ((ice == 1) .and. (minval(rho_e) >= 0)) correct_for_rho = 1 |
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| 102 | |
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| 103 | ! :: correct refractive index for ice density if needed |
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| 104 | if (correct_for_rho == 1) then |
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| 105 | f = rho_e/rho_ice |
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| 106 | m0 = ((2+m0**2+2*f*(m0**2-1))/(2+m0**2+f*(1-m0**2)))**(0.5) |
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| 107 | endif |
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| 108 | |
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| 109 | ! :: Mie calculations |
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| 110 | sizep = (pi*D0)/wl |
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| 111 | dqv(1) = 0. |
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| 112 | do i=1,nsizes |
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| 113 | call mieint(sizep(i), m0(i), one, dqv, qext(i), dqsc, qbsca(i), & |
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| 114 | dg, xs1, xs2, dph, err) |
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[5095] | 115 | end do |
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[1262] | 116 | |
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| 117 | else |
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| 118 | ! // Mie table used |
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| 119 | |
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| 120 | qext = qe |
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| 121 | qbsca = qs |
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| 122 | |
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| 123 | endif |
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| 124 | |
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| 125 | ! // eta_mie = 0.25*sum[qbsca*pi*D^2*N(D)*deltaD] |
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| 126 | ! <--------- eta_sum ---------> |
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| 127 | ! // z0_eff = (wl^4/!pi^5)*(1./k2)*eta_mie |
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| 128 | eta_sum = 0. |
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| 129 | if (size(D0) == 1) then |
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| 130 | eta_sum = qbsca(1)*(n(1)*1E6)*D0(1)**2 |
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| 131 | else |
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[2428] | 132 | xtemp = qbsca*N0*D0**2 |
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| 133 | call avint(xtemp,D0,nsizes,D0(1),D0(size(D0,1)),eta_sum) |
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[1262] | 134 | endif |
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| 135 | |
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| 136 | eta_mie = eta_sum*0.25*pi |
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| 137 | const = (wl**4/pi**5)*(1./k2) |
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| 138 | z0_eff = const*eta_mie |
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| 139 | |
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| 140 | ! // kr = 0.25*cr*sum[qext*pi*D^2*N(D)*deltaD] |
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| 141 | ! <---------- k_sum ---------> |
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| 142 | k_sum = 0. |
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| 143 | if (size(D0) == 1) then |
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| 144 | k_sum = qext(1)*(n(1)*1E6)*D0(1)**2 |
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| 145 | else |
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[2428] | 146 | xtemp = qext*N0*D0**2 |
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| 147 | call avint(xtemp,D0,nsizes,D0(1),D0(size(D0,1)),k_sum) |
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[1262] | 148 | endif |
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| 149 | cr = 10./log(10.) |
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| 150 | kr = k_sum*0.25*pi*(1000.*cr) |
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[2428] | 151 | |
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[1262] | 152 | ! // z_ray = sum[D^6*N(D)*deltaD] |
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| 153 | if (xr == 1) then |
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| 154 | z0_ray = 0. |
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| 155 | if (size(D0) == 1) then |
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| 156 | z0_ray = (n(1)*1E6)*D0(1)**6 |
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| 157 | else |
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[2428] | 158 | xtemp = N0*D0**6 |
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| 159 | call avint(xtemp,D0,nsizes,D0(1),D0(size(D0)),z0_ray) |
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[1262] | 160 | endif |
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| 161 | endif |
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| 162 | |
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| 163 | ! // convert to mm^6/m^3 |
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| 164 | z_eff = z0_eff*1E18 ! 10.*alog10(z0_eff*1E18) |
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| 165 | z_ray = z0_ray*1E18 ! 10.*alog10(z0_ray*1E18) |
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| 166 | |
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| 167 | end subroutine zeff |
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