1 | // |
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2 | // ******************************************************************** |
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3 | // * License and Disclaimer * |
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4 | // * * |
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5 | // * The Geant4 software is copyright of the Copyright Holders of * |
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6 | // * the Geant4 Collaboration. It is provided under the terms and * |
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7 | // * conditions of the Geant4 Software License, included in the file * |
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8 | // * LICENSE and available at http://cern.ch/geant4/license . These * |
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9 | // * include a list of copyright holders. * |
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10 | // * * |
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11 | // * Neither the authors of this software system, nor their employing * |
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12 | // * institutes,nor the agencies providing financial support for this * |
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13 | // * work make any representation or warranty, express or implied, * |
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14 | // * regarding this software system or assume any liability for its * |
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15 | // * use. Please see the license in the file LICENSE and URL above * |
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16 | // * for the full disclaimer and the limitation of liability. * |
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17 | // * * |
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18 | // * This code implementation is the result of the scientific and * |
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19 | // * technical work of the GEANT4 collaboration. * |
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20 | // * By using, copying, modifying or distributing the software (or * |
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21 | // * any work based on the software) you agree to acknowledge its * |
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22 | // * use in resulting scientific publications, and indicate your * |
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23 | // * acceptance of all terms of the Geant4 Software license. * |
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24 | // ******************************************************************** |
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25 | // |
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26 | // $Id: G4UrbanMscModel90.cc,v 1.13 2009/04/10 18:10:58 vnivanch Exp $ |
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27 | // GEANT4 tag $Name: geant4-09-03 $ |
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28 | // |
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29 | // ------------------------------------------------------------------- |
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30 | // |
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31 | // GEANT4 Class file |
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32 | // |
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33 | // |
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34 | // File name: G4UrbanMscModel90 |
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35 | // |
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36 | // Author: V.Ivanchenko clone Laszlo Urban model |
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37 | // |
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38 | // Creation date: 07.12.2007 |
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39 | // |
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40 | // Modifications: |
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41 | // |
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42 | // |
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43 | |
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44 | // Class Description: |
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45 | // |
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46 | // Implementation of the model of multiple scattering based on |
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47 | // H.W.Lewis Phys Rev 78 (1950) 526 and others |
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48 | |
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49 | // ------------------------------------------------------------------- |
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50 | // |
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51 | |
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52 | |
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53 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
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54 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
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55 | |
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56 | #include "G4UrbanMscModel90.hh" |
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57 | #include "Randomize.hh" |
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58 | #include "G4Electron.hh" |
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59 | |
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60 | #include "G4LossTableManager.hh" |
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61 | #include "G4ParticleChangeForMSC.hh" |
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62 | |
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63 | #include "G4Poisson.hh" |
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64 | |
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65 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
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66 | |
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67 | using namespace std; |
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68 | |
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69 | G4UrbanMscModel90::G4UrbanMscModel90(const G4String& nam) |
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70 | : G4VMscModel(nam), |
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71 | isInitialized(false) |
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72 | { |
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73 | taubig = 8.0; |
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74 | tausmall = 1.e-20; |
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75 | taulim = 1.e-6; |
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76 | currentTau = taulim; |
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77 | tlimitminfix = 1.e-6*mm; |
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78 | stepmin = tlimitminfix; |
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79 | smallstep = 1.e10; |
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80 | currentRange = 0. ; |
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81 | frscaling2 = 0.25; |
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82 | frscaling1 = 1.-frscaling2; |
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83 | tlimit = 1.e10*mm; |
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84 | tlimitmin = 10.*tlimitminfix; |
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85 | nstepmax = 25.; |
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86 | geombig = 1.e50*mm; |
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87 | geommin = 1.e-3*mm; |
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88 | geomlimit = geombig; |
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89 | presafety = 0.*mm; |
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90 | Zeff = 1.; |
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91 | particle = 0; |
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92 | theManager = G4LossTableManager::Instance(); |
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93 | inside = false; |
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94 | insideskin = false; |
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95 | } |
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96 | |
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97 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
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98 | |
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99 | G4UrbanMscModel90::~G4UrbanMscModel90() |
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100 | {} |
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101 | |
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102 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
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103 | |
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104 | void G4UrbanMscModel90::Initialise(const G4ParticleDefinition* p, |
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105 | const G4DataVector&) |
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106 | { |
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107 | skindepth = skin*stepmin; |
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108 | if(isInitialized) return; |
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109 | |
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110 | // set values of some data members |
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111 | SetParticle(p); |
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112 | |
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113 | fParticleChange = GetParticleChangeForMSC(); |
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114 | InitialiseSafetyHelper(); |
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115 | |
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116 | isInitialized = true; |
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117 | } |
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118 | |
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119 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
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120 | |
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121 | G4double G4UrbanMscModel90::ComputeCrossSectionPerAtom( |
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122 | const G4ParticleDefinition* part, |
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123 | G4double KineticEnergy, |
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124 | G4double AtomicNumber,G4double, |
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125 | G4double, G4double) |
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126 | { |
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127 | const G4double sigmafactor = twopi*classic_electr_radius*classic_electr_radius; |
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128 | const G4double epsfactor = 2.*electron_mass_c2*electron_mass_c2* |
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129 | Bohr_radius*Bohr_radius/(hbarc*hbarc); |
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130 | const G4double epsmin = 1.e-4 , epsmax = 1.e10; |
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131 | |
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132 | const G4double Zdat[15] = { 4., 6., 13., 20., 26., 29., 32., 38., 47., |
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133 | 50., 56., 64., 74., 79., 82. }; |
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134 | |
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135 | const G4double Tdat[22] = { 100*eV, 200*eV, 400*eV, 700*eV, |
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136 | 1*keV, 2*keV, 4*keV, 7*keV, |
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137 | 10*keV, 20*keV, 40*keV, 70*keV, |
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138 | 100*keV, 200*keV, 400*keV, 700*keV, |
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139 | 1*MeV, 2*MeV, 4*MeV, 7*MeV, |
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140 | 10*MeV, 20*MeV}; |
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141 | |
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142 | // corr. factors for e-/e+ lambda for T <= Tlim |
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143 | G4double celectron[15][22] = |
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144 | {{1.125,1.072,1.051,1.047,1.047,1.050,1.052,1.054, |
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145 | 1.054,1.057,1.062,1.069,1.075,1.090,1.105,1.111, |
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146 | 1.112,1.108,1.100,1.093,1.089,1.087 }, |
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147 | {1.408,1.246,1.143,1.096,1.077,1.059,1.053,1.051, |
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148 | 1.052,1.053,1.058,1.065,1.072,1.087,1.101,1.108, |
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149 | 1.109,1.105,1.097,1.090,1.086,1.082 }, |
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150 | {2.833,2.268,1.861,1.612,1.486,1.309,1.204,1.156, |
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151 | 1.136,1.114,1.106,1.106,1.109,1.119,1.129,1.132, |
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152 | 1.131,1.124,1.113,1.104,1.099,1.098 }, |
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153 | {3.879,3.016,2.380,2.007,1.818,1.535,1.340,1.236, |
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154 | 1.190,1.133,1.107,1.099,1.098,1.103,1.110,1.113, |
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155 | 1.112,1.105,1.096,1.089,1.085,1.098 }, |
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156 | {6.937,4.330,2.886,2.256,1.987,1.628,1.395,1.265, |
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157 | 1.203,1.122,1.080,1.065,1.061,1.063,1.070,1.073, |
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158 | 1.073,1.070,1.064,1.059,1.056,1.056 }, |
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159 | {9.616,5.708,3.424,2.551,2.204,1.762,1.485,1.330, |
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160 | 1.256,1.155,1.099,1.077,1.070,1.068,1.072,1.074, |
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161 | 1.074,1.070,1.063,1.059,1.056,1.052 }, |
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162 | {11.72,6.364,3.811,2.806,2.401,1.884,1.564,1.386, |
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163 | 1.300,1.180,1.112,1.082,1.073,1.066,1.068,1.069, |
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164 | 1.068,1.064,1.059,1.054,1.051,1.050 }, |
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165 | {18.08,8.601,4.569,3.183,2.662,2.025,1.646,1.439, |
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166 | 1.339,1.195,1.108,1.068,1.053,1.040,1.039,1.039, |
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167 | 1.039,1.037,1.034,1.031,1.030,1.036 }, |
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168 | {18.22,10.48,5.333,3.713,3.115,2.367,1.898,1.631, |
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169 | 1.498,1.301,1.171,1.105,1.077,1.048,1.036,1.033, |
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170 | 1.031,1.028,1.024,1.022,1.021,1.024 }, |
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171 | {14.14,10.65,5.710,3.929,3.266,2.453,1.951,1.669, |
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172 | 1.528,1.319,1.178,1.106,1.075,1.040,1.027,1.022, |
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173 | 1.020,1.017,1.015,1.013,1.013,1.020 }, |
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174 | {14.11,11.73,6.312,4.240,3.478,2.566,2.022,1.720, |
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175 | 1.569,1.342,1.186,1.102,1.065,1.022,1.003,0.997, |
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176 | 0.995,0.993,0.993,0.993,0.993,1.011 }, |
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177 | {22.76,20.01,8.835,5.287,4.144,2.901,2.219,1.855, |
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178 | 1.677,1.410,1.224,1.121,1.073,1.014,0.986,0.976, |
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179 | 0.974,0.972,0.973,0.974,0.975,0.987 }, |
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180 | {50.77,40.85,14.13,7.184,5.284,3.435,2.520,2.059, |
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181 | 1.837,1.512,1.283,1.153,1.091,1.010,0.969,0.954, |
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182 | 0.950,0.947,0.949,0.952,0.954,0.963 }, |
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183 | {65.87,59.06,15.87,7.570,5.567,3.650,2.682,2.182, |
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184 | 1.939,1.579,1.325,1.178,1.108,1.014,0.965,0.947, |
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185 | 0.941,0.938,0.940,0.944,0.946,0.954 }, |
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186 | {55.60,47.34,15.92,7.810,5.755,3.767,2.760,2.239, |
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187 | 1.985,1.609,1.343,1.188,1.113,1.013,0.960,0.939, |
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188 | 0.933,0.930,0.933,0.936,0.939,0.949 }}; |
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189 | |
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190 | G4double cpositron[15][22] = { |
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191 | {2.589,2.044,1.658,1.446,1.347,1.217,1.144,1.110, |
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192 | 1.097,1.083,1.080,1.086,1.092,1.108,1.123,1.131, |
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193 | 1.131,1.126,1.117,1.108,1.103,1.100 }, |
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194 | {3.904,2.794,2.079,1.710,1.543,1.325,1.202,1.145, |
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195 | 1.122,1.096,1.089,1.092,1.098,1.114,1.130,1.137, |
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196 | 1.138,1.132,1.122,1.113,1.108,1.102 }, |
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197 | {7.970,6.080,4.442,3.398,2.872,2.127,1.672,1.451, |
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198 | 1.357,1.246,1.194,1.179,1.178,1.188,1.201,1.205, |
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199 | 1.203,1.190,1.173,1.159,1.151,1.145 }, |
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200 | {9.714,7.607,5.747,4.493,3.815,2.777,2.079,1.715, |
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201 | 1.553,1.353,1.253,1.219,1.211,1.214,1.225,1.228, |
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202 | 1.225,1.210,1.191,1.175,1.166,1.174 }, |
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203 | {17.97,12.95,8.628,6.065,4.849,3.222,2.275,1.820, |
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204 | 1.624,1.382,1.259,1.214,1.202,1.202,1.214,1.219, |
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205 | 1.217,1.203,1.184,1.169,1.160,1.151 }, |
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206 | {24.83,17.06,10.84,7.355,5.767,3.707,2.546,1.996, |
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207 | 1.759,1.465,1.311,1.252,1.234,1.228,1.238,1.241, |
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208 | 1.237,1.222,1.201,1.184,1.174,1.159 }, |
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209 | {23.26,17.15,11.52,8.049,6.375,4.114,2.792,2.155, |
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210 | 1.880,1.535,1.353,1.281,1.258,1.247,1.254,1.256, |
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211 | 1.252,1.234,1.212,1.194,1.183,1.170 }, |
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212 | {22.33,18.01,12.86,9.212,7.336,4.702,3.117,2.348, |
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213 | 2.015,1.602,1.385,1.297,1.268,1.251,1.256,1.258, |
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214 | 1.254,1.237,1.214,1.195,1.185,1.179 }, |
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215 | {33.91,24.13,15.71,10.80,8.507,5.467,3.692,2.808, |
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216 | 2.407,1.873,1.564,1.425,1.374,1.330,1.324,1.320, |
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217 | 1.312,1.288,1.258,1.235,1.221,1.205 }, |
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218 | {32.14,24.11,16.30,11.40,9.015,5.782,3.868,2.917, |
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219 | 2.490,1.925,1.596,1.447,1.391,1.342,1.332,1.327, |
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220 | 1.320,1.294,1.264,1.240,1.226,1.214 }, |
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221 | {29.51,24.07,17.19,12.28,9.766,6.238,4.112,3.066, |
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222 | 2.602,1.995,1.641,1.477,1.414,1.356,1.342,1.336, |
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223 | 1.328,1.302,1.270,1.245,1.231,1.233 }, |
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224 | {38.19,30.85,21.76,15.35,12.07,7.521,4.812,3.498, |
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225 | 2.926,2.188,1.763,1.563,1.484,1.405,1.382,1.371, |
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226 | 1.361,1.330,1.294,1.267,1.251,1.239 }, |
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227 | {49.71,39.80,27.96,19.63,15.36,9.407,5.863,4.155, |
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228 | 3.417,2.478,1.944,1.692,1.589,1.480,1.441,1.423, |
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229 | 1.409,1.372,1.330,1.298,1.280,1.258 }, |
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230 | {59.25,45.08,30.36,20.83,16.15,9.834,6.166,4.407, |
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231 | 3.641,2.648,2.064,1.779,1.661,1.531,1.482,1.459, |
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232 | 1.442,1.400,1.354,1.319,1.299,1.272 }, |
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233 | {56.38,44.29,30.50,21.18,16.51,10.11,6.354,4.542, |
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234 | 3.752,2.724,2.116,1.817,1.692,1.554,1.499,1.474, |
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235 | 1.456,1.412,1.364,1.328,1.307,1.282 }}; |
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236 | |
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237 | //data/corrections for T > Tlim |
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238 | G4double Tlim = 10.*MeV; |
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239 | G4double beta2lim = Tlim*(Tlim+2.*electron_mass_c2)/ |
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240 | ((Tlim+electron_mass_c2)*(Tlim+electron_mass_c2)); |
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241 | G4double bg2lim = Tlim*(Tlim+2.*electron_mass_c2)/ |
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242 | (electron_mass_c2*electron_mass_c2); |
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243 | |
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244 | G4double sig0[15] = {0.2672*barn, 0.5922*barn, 2.653*barn, 6.235*barn, |
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245 | 11.69*barn , 13.24*barn , 16.12*barn, 23.00*barn , |
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246 | 35.13*barn , 39.95*barn , 50.85*barn, 67.19*barn , |
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247 | 91.15*barn , 104.4*barn , 113.1*barn}; |
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248 | |
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249 | G4double hecorr[15] = {120.70, 117.50, 105.00, 92.92, 79.23, 74.510, 68.29, |
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250 | 57.39, 41.97, 36.14, 24.53, 10.21, -7.855, -16.84, |
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251 | -22.30}; |
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252 | |
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253 | G4double sigma; |
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254 | SetParticle(part); |
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255 | |
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256 | G4double Z23 = 2.*log(AtomicNumber)/3.; Z23 = exp(Z23); |
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257 | |
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258 | // correction if particle .ne. e-/e+ |
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259 | // compute equivalent kinetic energy |
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260 | // lambda depends on p*beta .... |
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261 | |
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262 | G4double eKineticEnergy = KineticEnergy; |
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263 | |
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264 | if(mass > electron_mass_c2) |
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265 | { |
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266 | G4double TAU = KineticEnergy/mass ; |
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267 | G4double c = mass*TAU*(TAU+2.)/(electron_mass_c2*(TAU+1.)) ; |
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268 | G4double w = c-2. ; |
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269 | G4double tau = 0.5*(w+sqrt(w*w+4.*c)) ; |
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270 | eKineticEnergy = electron_mass_c2*tau ; |
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271 | } |
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272 | |
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273 | G4double ChargeSquare = charge*charge; |
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274 | |
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275 | G4double eTotalEnergy = eKineticEnergy + electron_mass_c2 ; |
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276 | G4double beta2 = eKineticEnergy*(eTotalEnergy+electron_mass_c2) |
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277 | /(eTotalEnergy*eTotalEnergy); |
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278 | G4double bg2 = eKineticEnergy*(eTotalEnergy+electron_mass_c2) |
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279 | /(electron_mass_c2*electron_mass_c2); |
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280 | |
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281 | G4double eps = epsfactor*bg2/Z23; |
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282 | |
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283 | if (eps<epsmin) sigma = 2.*eps*eps; |
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284 | else if(eps<epsmax) sigma = log(1.+2.*eps)-2.*eps/(1.+2.*eps); |
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285 | else sigma = log(2.*eps)-1.+1./eps; |
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286 | |
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287 | sigma *= ChargeSquare*AtomicNumber*AtomicNumber/(beta2*bg2); |
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288 | |
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289 | // interpolate in AtomicNumber and beta2 |
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290 | G4double c1,c2,cc1,cc2,corr; |
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291 | |
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292 | // get bin number in Z |
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293 | G4int iZ = 14; |
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294 | while ((iZ>=0)&&(Zdat[iZ]>=AtomicNumber)) iZ -= 1; |
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295 | if (iZ==14) iZ = 13; |
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296 | if (iZ==-1) iZ = 0 ; |
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297 | |
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298 | G4double Z1 = Zdat[iZ]; |
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299 | G4double Z2 = Zdat[iZ+1]; |
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300 | G4double ratZ = (AtomicNumber-Z1)*(AtomicNumber+Z1)/ |
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301 | ((Z2-Z1)*(Z2+Z1)); |
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302 | |
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303 | if(eKineticEnergy <= Tlim) |
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304 | { |
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305 | // get bin number in T (beta2) |
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306 | G4int iT = 21; |
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307 | while ((iT>=0)&&(Tdat[iT]>=eKineticEnergy)) iT -= 1; |
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308 | if(iT==21) iT = 20; |
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309 | if(iT==-1) iT = 0 ; |
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310 | |
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311 | // calculate betasquare values |
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312 | G4double T = Tdat[iT], E = T + electron_mass_c2; |
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313 | G4double b2small = T*(E+electron_mass_c2)/(E*E); |
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314 | |
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315 | T = Tdat[iT+1]; E = T + electron_mass_c2; |
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316 | G4double b2big = T*(E+electron_mass_c2)/(E*E); |
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317 | G4double ratb2 = (beta2-b2small)/(b2big-b2small); |
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318 | |
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319 | if (charge < 0.) |
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320 | { |
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321 | c1 = celectron[iZ][iT]; |
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322 | c2 = celectron[iZ+1][iT]; |
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323 | cc1 = c1+ratZ*(c2-c1); |
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324 | |
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325 | c1 = celectron[iZ][iT+1]; |
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326 | c2 = celectron[iZ+1][iT+1]; |
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327 | cc2 = c1+ratZ*(c2-c1); |
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328 | |
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329 | corr = cc1+ratb2*(cc2-cc1); |
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330 | |
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331 | sigma *= sigmafactor/corr; |
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332 | } |
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333 | else |
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334 | { |
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335 | c1 = cpositron[iZ][iT]; |
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336 | c2 = cpositron[iZ+1][iT]; |
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337 | cc1 = c1+ratZ*(c2-c1); |
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338 | |
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339 | c1 = cpositron[iZ][iT+1]; |
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340 | c2 = cpositron[iZ+1][iT+1]; |
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341 | cc2 = c1+ratZ*(c2-c1); |
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342 | |
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343 | corr = cc1+ratb2*(cc2-cc1); |
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344 | |
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345 | sigma *= sigmafactor/corr; |
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346 | } |
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347 | } |
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348 | else |
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349 | { |
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350 | c1 = bg2lim*sig0[iZ]*(1.+hecorr[iZ]*(beta2-beta2lim))/bg2; |
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351 | c2 = bg2lim*sig0[iZ+1]*(1.+hecorr[iZ+1]*(beta2-beta2lim))/bg2; |
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352 | if((AtomicNumber >= Z1) && (AtomicNumber <= Z2)) |
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353 | sigma = c1+ratZ*(c2-c1) ; |
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354 | else if(AtomicNumber < Z1) |
---|
355 | sigma = AtomicNumber*AtomicNumber*c1/(Z1*Z1); |
---|
356 | else if(AtomicNumber > Z2) |
---|
357 | sigma = AtomicNumber*AtomicNumber*c2/(Z2*Z2); |
---|
358 | } |
---|
359 | return sigma; |
---|
360 | |
---|
361 | } |
---|
362 | |
---|
363 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
364 | |
---|
365 | G4double G4UrbanMscModel90::ComputeTruePathLengthLimit( |
---|
366 | const G4Track& track, |
---|
367 | G4PhysicsTable* theTable, |
---|
368 | G4double currentMinimalStep) |
---|
369 | { |
---|
370 | tPathLength = currentMinimalStep; |
---|
371 | const G4DynamicParticle* dp = track.GetDynamicParticle(); |
---|
372 | G4StepPoint* sp = track.GetStep()->GetPreStepPoint(); |
---|
373 | G4StepStatus stepStatus = sp->GetStepStatus(); |
---|
374 | |
---|
375 | if(stepStatus == fUndefined) { |
---|
376 | inside = false; |
---|
377 | insideskin = false; |
---|
378 | tlimit = geombig; |
---|
379 | SetParticle( dp->GetDefinition() ); |
---|
380 | } |
---|
381 | |
---|
382 | theLambdaTable = theTable; |
---|
383 | couple = track.GetMaterialCutsCouple(); |
---|
384 | currentMaterialIndex = couple->GetIndex(); |
---|
385 | currentKinEnergy = dp->GetKineticEnergy(); |
---|
386 | currentRange = |
---|
387 | theManager->GetRangeFromRestricteDEDX(particle,currentKinEnergy,couple); |
---|
388 | lambda0 = GetLambda(currentKinEnergy); |
---|
389 | |
---|
390 | // stop here if small range particle |
---|
391 | if(inside) return tPathLength; |
---|
392 | |
---|
393 | if(tPathLength > currentRange) tPathLength = currentRange; |
---|
394 | |
---|
395 | presafety = sp->GetSafety(); |
---|
396 | /* |
---|
397 | G4cout << "G4UrbanMscModel90::ComputeTruePathLengthLimit tPathLength= " |
---|
398 | <<tPathLength<<" safety= " << presafety |
---|
399 | << " range= " <<currentRange<<G4endl; |
---|
400 | */ |
---|
401 | // far from geometry boundary |
---|
402 | if(currentRange < presafety) |
---|
403 | { |
---|
404 | inside = true; |
---|
405 | return tPathLength; |
---|
406 | } |
---|
407 | |
---|
408 | // standard version |
---|
409 | // |
---|
410 | if (steppingAlgorithm == fUseDistanceToBoundary) |
---|
411 | { |
---|
412 | //compute geomlimit and presafety |
---|
413 | G4double geomlimit = ComputeGeomLimit(track, presafety, currentRange); |
---|
414 | |
---|
415 | // is far from boundary |
---|
416 | if(currentRange <= presafety) |
---|
417 | { |
---|
418 | inside = true; |
---|
419 | return tPathLength; |
---|
420 | } |
---|
421 | |
---|
422 | smallstep += 1.; |
---|
423 | insideskin = false; |
---|
424 | |
---|
425 | if((stepStatus == fGeomBoundary) || (stepStatus == fUndefined)) |
---|
426 | { |
---|
427 | |
---|
428 | if(stepStatus == fUndefined) smallstep = 1.e10; |
---|
429 | else smallstep = 1.; |
---|
430 | |
---|
431 | // facrange scaling in lambda |
---|
432 | // not so strong step restriction above lambdalimit |
---|
433 | G4double facr = facrange; |
---|
434 | if(lambda0 > lambdalimit) |
---|
435 | facr *= frscaling1+frscaling2*lambda0/lambdalimit; |
---|
436 | |
---|
437 | // constraint from the physics |
---|
438 | if (currentRange > lambda0) tlimit = facr*currentRange; |
---|
439 | else tlimit = facr*lambda0; |
---|
440 | |
---|
441 | // constraint from the geometry (if tlimit above is too big) |
---|
442 | G4double tgeom = geombig; |
---|
443 | if(geomlimit > geommin) |
---|
444 | { |
---|
445 | if(stepStatus == fGeomBoundary) |
---|
446 | tgeom = geomlimit/facgeom; |
---|
447 | else |
---|
448 | tgeom = 2.*geomlimit/facgeom; |
---|
449 | } |
---|
450 | |
---|
451 | //define stepmin here (it depends on lambda!) |
---|
452 | //rough estimation of lambda_elastic/lambda_transport |
---|
453 | G4double rat = currentKinEnergy/MeV ; |
---|
454 | rat = 1.e-3/(rat*(10.+rat)) ; |
---|
455 | //stepmin ~ lambda_elastic |
---|
456 | stepmin = rat*lambda0; |
---|
457 | skindepth = skin*stepmin; |
---|
458 | |
---|
459 | //define tlimitmin |
---|
460 | tlimitmin = lambda0/nstepmax; |
---|
461 | if(tlimitmin < stepmin) tlimitmin = 1.01*stepmin; |
---|
462 | if(tlimitmin < tlimitminfix) tlimitmin = tlimitminfix; |
---|
463 | |
---|
464 | //lower limit for tlimit |
---|
465 | if(tlimit < tlimitmin) tlimit = tlimitmin; |
---|
466 | |
---|
467 | //check against geometry limit |
---|
468 | if(tlimit > tgeom) tlimit = tgeom; |
---|
469 | } |
---|
470 | |
---|
471 | //if track starts far from boundaries increase tlimit! |
---|
472 | if(tlimit < facsafety*presafety) tlimit = facsafety*presafety ; |
---|
473 | |
---|
474 | // G4cout << "tgeom= " << tgeom << " geomlimit= " << geomlimit |
---|
475 | // << " tlimit= " << tlimit << " presafety= " << presafety << G4endl; |
---|
476 | |
---|
477 | // shortcut |
---|
478 | if((tPathLength < tlimit) && (tPathLength < presafety)) |
---|
479 | return tPathLength; |
---|
480 | |
---|
481 | G4double tnow = tlimit; |
---|
482 | // optimization ... |
---|
483 | if(geomlimit < geombig) tnow = max(tlimit,facsafety*geomlimit); |
---|
484 | |
---|
485 | // step reduction near to boundary |
---|
486 | if(smallstep < skin) |
---|
487 | { |
---|
488 | tnow = stepmin; |
---|
489 | insideskin = true; |
---|
490 | } |
---|
491 | else if(geomlimit < geombig) |
---|
492 | { |
---|
493 | if(geomlimit > skindepth) |
---|
494 | { |
---|
495 | if(tnow > geomlimit-0.999*skindepth) |
---|
496 | tnow = geomlimit-0.999*skindepth; |
---|
497 | } |
---|
498 | else |
---|
499 | { |
---|
500 | insideskin = true; |
---|
501 | if(tnow > stepmin) tnow = stepmin; |
---|
502 | } |
---|
503 | } |
---|
504 | |
---|
505 | if(tnow < stepmin) tnow = stepmin; |
---|
506 | |
---|
507 | if(tPathLength > tnow) tPathLength = tnow ; |
---|
508 | } |
---|
509 | // for 'normal' simulation with or without magnetic field |
---|
510 | // there no small step/single scattering at boundaries |
---|
511 | else if(steppingAlgorithm == fUseSafety) |
---|
512 | { |
---|
513 | // compute presafety again if presafety <= 0 and no boundary |
---|
514 | // i.e. when it is needed for optimization purposes |
---|
515 | if((stepStatus != fGeomBoundary) && (presafety < tlimitminfix)) |
---|
516 | presafety = ComputeSafety(sp->GetPosition(),tPathLength); |
---|
517 | |
---|
518 | // is far from boundary |
---|
519 | if(currentRange < presafety) |
---|
520 | { |
---|
521 | inside = true; |
---|
522 | return tPathLength; |
---|
523 | } |
---|
524 | |
---|
525 | if((stepStatus == fGeomBoundary) || (stepStatus == fUndefined)) |
---|
526 | { |
---|
527 | // facrange scaling in lambda |
---|
528 | // not so strong step restriction above lambdalimit |
---|
529 | G4double facr = facrange; |
---|
530 | if(lambda0 > lambdalimit) |
---|
531 | facr *= frscaling1+frscaling2*lambda0/lambdalimit; |
---|
532 | |
---|
533 | // constraint from the physics |
---|
534 | if (currentRange > lambda0) tlimit = facr*currentRange; |
---|
535 | else tlimit = facr*lambda0; |
---|
536 | |
---|
537 | //lower limit for tlimit |
---|
538 | tlimitmin = std::max(tlimitminfix,lambda0/nstepmax); |
---|
539 | if(tlimit < tlimitmin) tlimit = tlimitmin; |
---|
540 | } |
---|
541 | |
---|
542 | //if track starts far from boundaries increase tlimit! |
---|
543 | if(tlimit < facsafety*presafety) tlimit = facsafety*presafety ; |
---|
544 | |
---|
545 | if(tPathLength > tlimit) tPathLength = tlimit; |
---|
546 | } |
---|
547 | |
---|
548 | // version similar to 7.1 (needed for some experiments) |
---|
549 | else |
---|
550 | { |
---|
551 | if (stepStatus == fGeomBoundary) |
---|
552 | { |
---|
553 | if (currentRange > lambda0) tlimit = facrange*currentRange; |
---|
554 | else tlimit = facrange*lambda0; |
---|
555 | |
---|
556 | if(tlimit < tlimitmin) tlimit = tlimitmin; |
---|
557 | if(tPathLength > tlimit) tPathLength = tlimit; |
---|
558 | } |
---|
559 | } |
---|
560 | // G4cout << "tPathLength= " << tPathLength << " geomlimit= " << geomlimit |
---|
561 | // << " currentMinimalStep= " << currentMinimalStep << G4endl; |
---|
562 | return tPathLength ; |
---|
563 | } |
---|
564 | |
---|
565 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
566 | |
---|
567 | G4double G4UrbanMscModel90::ComputeGeomPathLength(G4double) |
---|
568 | { |
---|
569 | lambdaeff = lambda0; |
---|
570 | par1 = -1. ; |
---|
571 | par2 = par3 = 0. ; |
---|
572 | |
---|
573 | // do the true -> geom transformation |
---|
574 | zPathLength = tPathLength; |
---|
575 | |
---|
576 | // z = t for very small tPathLength |
---|
577 | if(tPathLength < tlimitminfix) return zPathLength; |
---|
578 | |
---|
579 | // this correction needed to run MSC with eIoni and eBrem inactivated |
---|
580 | // and makes no harm for a normal run |
---|
581 | if(tPathLength > currentRange) |
---|
582 | tPathLength = currentRange ; |
---|
583 | |
---|
584 | G4double tau = tPathLength/lambda0 ; |
---|
585 | |
---|
586 | if ((tau <= tausmall) || insideskin) { |
---|
587 | zPathLength = tPathLength; |
---|
588 | if(zPathLength > lambda0) zPathLength = lambda0; |
---|
589 | return zPathLength; |
---|
590 | } |
---|
591 | |
---|
592 | G4double zmean = tPathLength; |
---|
593 | if (tPathLength < currentRange*dtrl) { |
---|
594 | if(tau < taulim) zmean = tPathLength*(1.-0.5*tau) ; |
---|
595 | else zmean = lambda0*(1.-exp(-tau)); |
---|
596 | } else if(currentKinEnergy < mass) { |
---|
597 | par1 = 1./currentRange ; |
---|
598 | par2 = 1./(par1*lambda0) ; |
---|
599 | par3 = 1.+par2 ; |
---|
600 | if(tPathLength < currentRange) |
---|
601 | zmean = (1.-exp(par3*log(1.-tPathLength/currentRange)))/(par1*par3) ; |
---|
602 | else |
---|
603 | zmean = 1./(par1*par3) ; |
---|
604 | } else { |
---|
605 | G4double T1 = theManager->GetEnergy(particle,currentRange-tPathLength,couple); |
---|
606 | G4double lambda1 = GetLambda(T1); |
---|
607 | |
---|
608 | par1 = (lambda0-lambda1)/(lambda0*tPathLength) ; |
---|
609 | par2 = 1./(par1*lambda0) ; |
---|
610 | par3 = 1.+par2 ; |
---|
611 | zmean = (1.-exp(par3*log(lambda1/lambda0)))/(par1*par3) ; |
---|
612 | } |
---|
613 | |
---|
614 | zPathLength = zmean ; |
---|
615 | |
---|
616 | // sample z |
---|
617 | if(samplez) |
---|
618 | { |
---|
619 | const G4double ztmax = 0.99, onethird = 1./3. ; |
---|
620 | G4double zt = zmean/tPathLength ; |
---|
621 | |
---|
622 | if (tPathLength > stepmin && zt < ztmax) |
---|
623 | { |
---|
624 | G4double u,cz1; |
---|
625 | if(zt >= onethird) |
---|
626 | { |
---|
627 | G4double cz = 0.5*(3.*zt-1.)/(1.-zt) ; |
---|
628 | cz1 = 1.+cz ; |
---|
629 | G4double u0 = cz/cz1 ; |
---|
630 | G4double grej ; |
---|
631 | do { |
---|
632 | u = exp(log(G4UniformRand())/cz1) ; |
---|
633 | grej = exp(cz*log(u/u0))*(1.-u)/(1.-u0) ; |
---|
634 | } while (grej < G4UniformRand()) ; |
---|
635 | } |
---|
636 | else |
---|
637 | { |
---|
638 | cz1 = 1./zt-1.; |
---|
639 | u = 1.-exp(log(G4UniformRand())/cz1) ; |
---|
640 | } |
---|
641 | zPathLength = tPathLength*u ; |
---|
642 | } |
---|
643 | } |
---|
644 | |
---|
645 | if(zPathLength > lambda0) zPathLength = lambda0; |
---|
646 | |
---|
647 | return zPathLength; |
---|
648 | } |
---|
649 | |
---|
650 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
651 | |
---|
652 | G4double G4UrbanMscModel90::ComputeTrueStepLength(G4double geomStepLength) |
---|
653 | { |
---|
654 | // step defined other than transportation |
---|
655 | if(geomStepLength == zPathLength && tPathLength <= currentRange) |
---|
656 | return tPathLength; |
---|
657 | |
---|
658 | // t = z for very small step |
---|
659 | zPathLength = geomStepLength; |
---|
660 | tPathLength = geomStepLength; |
---|
661 | if(geomStepLength < tlimitminfix) return tPathLength; |
---|
662 | |
---|
663 | // recalculation |
---|
664 | if((geomStepLength > lambda0*tausmall) && !insideskin) |
---|
665 | { |
---|
666 | if(par1 < 0.) |
---|
667 | tPathLength = -lambda0*log(1.-geomStepLength/lambda0) ; |
---|
668 | else |
---|
669 | { |
---|
670 | if(par1*par3*geomStepLength < 1.) |
---|
671 | tPathLength = (1.-exp(log(1.-par1*par3*geomStepLength)/par3))/par1 ; |
---|
672 | else |
---|
673 | tPathLength = currentRange; |
---|
674 | } |
---|
675 | } |
---|
676 | if(tPathLength < geomStepLength) tPathLength = geomStepLength; |
---|
677 | |
---|
678 | return tPathLength; |
---|
679 | } |
---|
680 | |
---|
681 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
682 | |
---|
683 | G4double G4UrbanMscModel90::ComputeTheta0(G4double trueStepLength, |
---|
684 | G4double KineticEnergy) |
---|
685 | { |
---|
686 | // for all particles take the width of the central part |
---|
687 | // from a parametrization similar to the Highland formula |
---|
688 | // ( Highland formula: Particle Physics Booklet, July 2002, eq. 26.10) |
---|
689 | const G4double c_highland = 13.6*MeV ; |
---|
690 | G4double betacp = sqrt(currentKinEnergy*(currentKinEnergy+2.*mass)* |
---|
691 | KineticEnergy*(KineticEnergy+2.*mass)/ |
---|
692 | ((currentKinEnergy+mass)*(KineticEnergy+mass))); |
---|
693 | G4double y = trueStepLength/currentRadLength; |
---|
694 | G4double theta0 = c_highland*std::abs(charge)*sqrt(y)/betacp; |
---|
695 | y = log(y); |
---|
696 | theta0 *= sqrt(1.+y*(0.105+0.0035*y)); |
---|
697 | |
---|
698 | //correction for small Zeff (based on high energy |
---|
699 | // proton scattering data) |
---|
700 | // see G.Shen at al. Phys.Rev.D20(1979) p.1584 |
---|
701 | theta0 *= 1.-0.24/(Zeff*(Zeff+1.)); |
---|
702 | |
---|
703 | return theta0; |
---|
704 | |
---|
705 | } |
---|
706 | |
---|
707 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
708 | |
---|
709 | void G4UrbanMscModel90::SampleScattering(const G4DynamicParticle* dynParticle, |
---|
710 | G4double safety) |
---|
711 | { |
---|
712 | G4double kineticEnergy = dynParticle->GetKineticEnergy(); |
---|
713 | if((kineticEnergy <= 0.0) || (tPathLength <= tlimitminfix) || |
---|
714 | (tPathLength/tausmall < lambda0) ) return; |
---|
715 | |
---|
716 | G4double cth = SampleCosineTheta(tPathLength,kineticEnergy); |
---|
717 | // protection against 'bad' cth values |
---|
718 | if(std::abs(cth) > 1.) return; |
---|
719 | |
---|
720 | G4double sth = sqrt((1.0 - cth)*(1.0 + cth)); |
---|
721 | G4double phi = twopi*G4UniformRand(); |
---|
722 | G4double dirx = sth*cos(phi); |
---|
723 | G4double diry = sth*sin(phi); |
---|
724 | |
---|
725 | G4ThreeVector oldDirection = dynParticle->GetMomentumDirection(); |
---|
726 | G4ThreeVector newDirection(dirx,diry,cth); |
---|
727 | newDirection.rotateUz(oldDirection); |
---|
728 | fParticleChange->ProposeMomentumDirection(newDirection); |
---|
729 | |
---|
730 | if (latDisplasment && safety > tlimitminfix) { |
---|
731 | |
---|
732 | G4double r = SampleDisplacement(); |
---|
733 | /* |
---|
734 | G4cout << "G4UrbanMscModel90::SampleSecondaries: e(MeV)= " << kineticEnergy |
---|
735 | << " sinTheta= " << sth << " r(mm)= " << r |
---|
736 | << " trueStep(mm)= " << truestep |
---|
737 | << " geomStep(mm)= " << zPathLength |
---|
738 | << G4endl; |
---|
739 | */ |
---|
740 | if(r > 0.) |
---|
741 | { |
---|
742 | G4double latcorr = LatCorrelation(); |
---|
743 | if(latcorr > r) latcorr = r; |
---|
744 | |
---|
745 | // sample direction of lateral displacement |
---|
746 | // compute it from the lateral correlation |
---|
747 | G4double Phi = 0.; |
---|
748 | if(std::abs(r*sth) < latcorr) { |
---|
749 | Phi = twopi*G4UniformRand(); |
---|
750 | } else { |
---|
751 | G4double psi = std::acos(latcorr/(r*sth)); |
---|
752 | if(G4UniformRand() < 0.5) Phi = phi+psi; |
---|
753 | else Phi = phi-psi; |
---|
754 | } |
---|
755 | |
---|
756 | dirx = std::cos(Phi); |
---|
757 | diry = std::sin(Phi); |
---|
758 | |
---|
759 | G4ThreeVector latDirection(dirx,diry,0.0); |
---|
760 | latDirection.rotateUz(oldDirection); |
---|
761 | ComputeDisplacement(fParticleChange, latDirection, r, safety); |
---|
762 | } |
---|
763 | } |
---|
764 | } |
---|
765 | |
---|
766 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
767 | |
---|
768 | G4double G4UrbanMscModel90::SampleCosineTheta(G4double trueStepLength, |
---|
769 | G4double KineticEnergy) |
---|
770 | { |
---|
771 | G4double cth = 1. ; |
---|
772 | G4double tau = trueStepLength/lambda0 ; |
---|
773 | |
---|
774 | Zeff = couple->GetMaterial()->GetTotNbOfElectPerVolume()/ |
---|
775 | couple->GetMaterial()->GetTotNbOfAtomsPerVolume() ; |
---|
776 | |
---|
777 | if(insideskin) |
---|
778 | { |
---|
779 | //no scattering, single or plural scattering |
---|
780 | G4double mean = trueStepLength/stepmin ; |
---|
781 | |
---|
782 | G4int n = G4Poisson(mean); |
---|
783 | if(n > 0) |
---|
784 | { |
---|
785 | G4double tm = KineticEnergy/electron_mass_c2; |
---|
786 | // ascr - screening parameter |
---|
787 | G4double ascr = exp(log(Zeff)/3.)/(137.*sqrt(tm*(tm+2.))); |
---|
788 | G4double ascr1 = 1.+0.5*ascr*ascr; |
---|
789 | G4double bp1=ascr1+1.; |
---|
790 | G4double bm1=ascr1-1.; |
---|
791 | // single scattering from screened Rutherford x-section |
---|
792 | G4double ct,st,phi; |
---|
793 | G4double sx=0.,sy=0.,sz=0.; |
---|
794 | for(G4int i=1; i<=n; i++) |
---|
795 | { |
---|
796 | ct = ascr1-bp1*bm1/(2.*G4UniformRand()+bm1); |
---|
797 | if(ct < -1.) ct = -1.; |
---|
798 | if(ct > 1.) ct = 1.; |
---|
799 | st = sqrt(1.-ct*ct); |
---|
800 | phi = twopi*G4UniformRand(); |
---|
801 | sx += st*cos(phi); |
---|
802 | sy += st*sin(phi); |
---|
803 | sz += ct; |
---|
804 | } |
---|
805 | cth = sz/sqrt(sx*sx+sy*sy+sz*sz); |
---|
806 | } |
---|
807 | } |
---|
808 | else |
---|
809 | { |
---|
810 | if(trueStepLength >= currentRange*dtrl) { |
---|
811 | if(par1*trueStepLength < 1.) |
---|
812 | tau = -par2*log(1.-par1*trueStepLength) ; |
---|
813 | // for the case if ioni/brems are inactivated |
---|
814 | // see the corresponding condition in ComputeGeomPathLength |
---|
815 | else if(1.-KineticEnergy/currentKinEnergy > taulim) |
---|
816 | tau = taubig ; |
---|
817 | } |
---|
818 | currentTau = tau ; |
---|
819 | lambdaeff = trueStepLength/currentTau; |
---|
820 | currentRadLength = couple->GetMaterial()->GetRadlen(); |
---|
821 | |
---|
822 | if (tau >= taubig) cth = -1.+2.*G4UniformRand(); |
---|
823 | else if (tau >= tausmall) |
---|
824 | { |
---|
825 | G4double b,bx,b1,ebx,eb1; |
---|
826 | G4double prob = 0., qprob = 1. ; |
---|
827 | G4double a = 1., ea = 0., eaa = 1.; |
---|
828 | G4double xmean1 = 1., xmean2 = 0.; |
---|
829 | G4double xsi = 3.; |
---|
830 | |
---|
831 | G4double theta0 = ComputeTheta0(trueStepLength,KineticEnergy); |
---|
832 | |
---|
833 | // protexction for very small angles |
---|
834 | if(theta0 < tausmall) return cth; |
---|
835 | |
---|
836 | G4double sth = sin(0.5*theta0); |
---|
837 | a = 0.25/(sth*sth); |
---|
838 | |
---|
839 | G4double xmeanth = exp(-tau); |
---|
840 | |
---|
841 | G4double c = 3. ; |
---|
842 | G4double c1 = c-1.; |
---|
843 | |
---|
844 | G4double x0 = 1.-xsi/a ; |
---|
845 | if(x0 < 0.) |
---|
846 | { |
---|
847 | // 1 model function |
---|
848 | b = exp(tau); |
---|
849 | bx = b-1.; |
---|
850 | b1 = b+1.; |
---|
851 | ebx=exp((c1)*log(bx)) ; |
---|
852 | eb1=exp((c1)*log(b1)) ; |
---|
853 | } |
---|
854 | else |
---|
855 | { |
---|
856 | //empirical tail parameter |
---|
857 | // based some exp. data |
---|
858 | c = 2.40-0.027*exp(2.*log(Zeff)/3.); |
---|
859 | |
---|
860 | if(c == 2.) c = 2.+taulim ; |
---|
861 | if(c <= 1.) c = 1.+taulim ; |
---|
862 | c1 = c-1.; |
---|
863 | |
---|
864 | ea = exp(-xsi) ; |
---|
865 | eaa = 1.-ea ; |
---|
866 | xmean1 = 1.-(1.-(1.+xsi)*ea)/(eaa*a) ; |
---|
867 | |
---|
868 | // from the continuity of the 1st derivative at x=x0 |
---|
869 | b = 1.+(c-xsi)/a ; |
---|
870 | |
---|
871 | b1 = b+1. ; |
---|
872 | bx = c/a ; |
---|
873 | eb1=exp((c1)*log(b1)) ; |
---|
874 | ebx=exp((c1)*log(bx)) ; |
---|
875 | xmean2 = (x0*eb1+ebx-(eb1*bx-b1*ebx)/(c-2.))/(eb1-ebx) ; |
---|
876 | |
---|
877 | G4double f1x0 = a*ea/eaa ; |
---|
878 | G4double f2x0 = c1*eb1*ebx/(eb1-ebx)/exp(c*log(bx)) ; |
---|
879 | |
---|
880 | // from continuity at x=x0 |
---|
881 | prob = f2x0/(f1x0+f2x0) ; |
---|
882 | |
---|
883 | // from xmean = xmeanth |
---|
884 | qprob = (f1x0+f2x0)*xmeanth/(f2x0*xmean1+f1x0*xmean2) ; |
---|
885 | } |
---|
886 | |
---|
887 | // sampling of costheta |
---|
888 | if (G4UniformRand() < qprob) |
---|
889 | { |
---|
890 | if (G4UniformRand() < prob) |
---|
891 | cth = 1.+log(ea+G4UniformRand()*eaa)/a ; |
---|
892 | else |
---|
893 | cth = b-b1*bx/exp(log(ebx-G4UniformRand()*(ebx-eb1))/c1) ; |
---|
894 | } |
---|
895 | else |
---|
896 | { |
---|
897 | cth = -1.+2.*G4UniformRand(); |
---|
898 | } |
---|
899 | } |
---|
900 | } |
---|
901 | |
---|
902 | return cth ; |
---|
903 | } |
---|
904 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
905 | |
---|
906 | G4double G4UrbanMscModel90::SampleDisplacement() |
---|
907 | { |
---|
908 | const G4double kappa = 2.5; |
---|
909 | const G4double kappapl1 = kappa+1.; |
---|
910 | const G4double kappami1 = kappa-1.; |
---|
911 | G4double rmean = 0.0; |
---|
912 | if ((currentTau >= tausmall) && !insideskin) { |
---|
913 | if (currentTau < taulim) { |
---|
914 | rmean = kappa*currentTau*currentTau*currentTau* |
---|
915 | (1.-kappapl1*currentTau*0.25)/6. ; |
---|
916 | |
---|
917 | } else { |
---|
918 | G4double etau = 0.0; |
---|
919 | if (currentTau<taubig) etau = exp(-currentTau); |
---|
920 | rmean = -kappa*currentTau; |
---|
921 | rmean = -exp(rmean)/(kappa*kappami1); |
---|
922 | rmean += currentTau-kappapl1/kappa+kappa*etau/kappami1; |
---|
923 | } |
---|
924 | if (rmean>0.) rmean = 2.*lambdaeff*sqrt(rmean/3.0); |
---|
925 | else rmean = 0.; |
---|
926 | } |
---|
927 | |
---|
928 | // protection against z > t ........................... |
---|
929 | if(rmean > 0.) { |
---|
930 | G4double zt = (tPathLength-zPathLength)*(tPathLength+zPathLength); |
---|
931 | if(zt <= 0.) |
---|
932 | rmean = 0.; |
---|
933 | else if(rmean*rmean > zt) |
---|
934 | rmean = sqrt(zt); |
---|
935 | } |
---|
936 | return rmean; |
---|
937 | } |
---|
938 | |
---|
939 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
940 | |
---|
941 | G4double G4UrbanMscModel90::LatCorrelation() |
---|
942 | { |
---|
943 | const G4double kappa = 2.5; |
---|
944 | const G4double kappami1 = kappa-1.; |
---|
945 | |
---|
946 | G4double latcorr = 0.; |
---|
947 | if((currentTau >= tausmall) && !insideskin) |
---|
948 | { |
---|
949 | if(currentTau < taulim) |
---|
950 | latcorr = lambdaeff*kappa*currentTau*currentTau* |
---|
951 | (1.-(kappa+1.)*currentTau/3.)/3.; |
---|
952 | else |
---|
953 | { |
---|
954 | G4double etau = 0.; |
---|
955 | if(currentTau < taubig) etau = exp(-currentTau); |
---|
956 | latcorr = -kappa*currentTau; |
---|
957 | latcorr = exp(latcorr)/kappami1; |
---|
958 | latcorr += 1.-kappa*etau/kappami1 ; |
---|
959 | latcorr *= 2.*lambdaeff/3. ; |
---|
960 | } |
---|
961 | } |
---|
962 | |
---|
963 | return latcorr; |
---|
964 | } |
---|
965 | |
---|
966 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|
967 | |
---|
968 | void G4UrbanMscModel90::SampleSecondaries(std::vector<G4DynamicParticle*>*, |
---|
969 | const G4MaterialCutsCouple*, |
---|
970 | const G4DynamicParticle*, |
---|
971 | G4double, |
---|
972 | G4double) |
---|
973 | {} |
---|
974 | |
---|
975 | //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... |
---|