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39 // 42 // 40 // Class Description: 43 // Class Description: 41 // 44 // 42 // Implementation of gamma conversion to e+e- << 45 // Implementation of gamma convertion to e+e- in the field of a nucleus 43 // For details see Physics Reference Manual << 46 // 44 47 45 // ------------------------------------------- 48 // ------------------------------------------------------------------- 46 // 49 // 47 50 48 #ifndef G4BetheHeitlerModel_h 51 #ifndef G4BetheHeitlerModel_h 49 #define G4BetheHeitlerModel_h 1 52 #define G4BetheHeitlerModel_h 1 50 53 51 #include "G4VEmModel.hh" 54 #include "G4VEmModel.hh" 52 #include "G4PhysicsTable.hh" 55 #include "G4PhysicsTable.hh" 53 #include "G4Log.hh" << 54 << 55 #include <vector> << 56 56 57 class G4ParticleChangeForGamma; 57 class G4ParticleChangeForGamma; 58 class G4Pow; << 59 class G4EmElementXS; << 60 58 61 class G4BetheHeitlerModel : public G4VEmModel 59 class G4BetheHeitlerModel : public G4VEmModel 62 { 60 { 63 61 64 public: 62 public: 65 63 66 explicit G4BetheHeitlerModel(const G4Particl << 64 G4BetheHeitlerModel(const G4ParticleDefinition* p = 0, 67 const G4String& << 65 const G4String& nam = "Bethe-Heitler"); 68 66 69 ~G4BetheHeitlerModel() override; << 67 virtual ~G4BetheHeitlerModel(); 70 68 71 void Initialise(const G4ParticleDefinition*, << 69 virtual void Initialise(const G4ParticleDefinition*, const G4DataVector&); 72 70 73 void InitialiseLocal(const G4ParticleDefinit << 71 virtual G4double ComputeCrossSectionPerAtom( 74 G4VEmModel* masterModel) override; << 72 const G4ParticleDefinition*, >> 73 G4double kinEnergy, >> 74 G4double Z, >> 75 G4double A=0., >> 76 G4double cut=0., >> 77 G4double emax=DBL_MAX); 75 78 76 G4double ComputeCrossSectionPerAtom(const G4 << 79 virtual std::vector<G4DynamicParticle*>* SampleSecondaries( 77 G4double kinEnergy, << 80 const G4MaterialCutsCouple*, 78 G4double Z, << 81 const G4DynamicParticle*, 79 G4double A=0., << 82 G4double tmin, 80 G4double cut=0., << 83 G4double maxEnergy); 81 G4double emax=DBL_MAX) override; << 82 << 83 void SampleSecondaries(std::vector<G4Dynamic << 84 const G4MaterialCutsCouple*, << 85 const G4DynamicParticle*, << 86 G4double tmin, << 87 G4double maxEnergy) override; << 88 84 89 // hide assignment operator << 85 private: 90 G4BetheHeitlerModel & operator=(const G4Beth << 91 G4BetheHeitlerModel(const G4BetheHeitlerMod << 92 86 93 protected: << 87 G4double ScreenFunction1(G4double ScreenVariable); 94 88 95 inline G4double ScreenFunction1(const G4doub << 89 G4double ScreenFunction2(G4double ScreenVariable); 96 90 97 inline G4double ScreenFunction2(const G4doub << 91 // hide assignment operator >> 92 G4BetheHeitlerModel & operator=(const G4BetheHeitlerModel &right); >> 93 G4BetheHeitlerModel(const G4BetheHeitlerModel&); 98 94 99 inline void ScreenFunction12(const G4double << 95 G4ParticleDefinition* theGamma; >> 96 G4ParticleDefinition* theElectron; >> 97 G4ParticleDefinition* thePositron; >> 98 G4ParticleChangeForGamma* fParticleChange; >> 99 G4PhysicsTable* theCrossSectionTable; 100 100 101 void InitialiseElementData(); << 101 G4double lowGammaEnergy; 102 << 102 G4double highGammaEnergy; 103 struct ElementData { << 103 104 G4double fDeltaMaxLow; << 104 G4int nbins; 105 G4double fDeltaMaxHigh; << 105 size_t indexZ[120]; 106 }; << 107 << 108 static const G4int gMaxZet; << 109 106 110 G4Pow* fG4Calc; << 107 }; 111 const G4ParticleDefinition* fTheGamma; << 112 const G4ParticleDefinition* fTheElectr << 113 const G4ParticleDefinition* fThePositr << 114 G4ParticleChangeForGamma* fParticleC << 115 G4EmElementXS* fXSection{ << 116 108 117 G4bool isFirstInstance{false}; << 109 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 118 G4bool useEPICS2017{false}; << 119 110 120 static std::vector<ElementData*> gElementDa << 111 inline G4double G4BetheHeitlerModel::ScreenFunction1(G4double ScreenVariable) 121 }; << 122 112 123 // << 113 // compute the value of the screening function 3*PHI1 - PHI2 124 // Bethe screening functions for the elastic ( << 125 // Bethe's phi1, phi2 coherent screening funct << 126 // by using (the universal) atomic form factor << 127 // Fermi model of the atom (using numerical so << 128 // screening function instead of Moliere's ana << 129 // numerical results can be well approximated << 130 // especially near the delta=1 limit) by: << 131 // ## if delta <= 1.4 << 132 // phi1(delta) = 20.806 - delta*(3.190 - 0.57 << 133 // phi2(delta) = 20.234 - delta*(2.126 - 0.09 << 134 // ## if delta > 1.4 << 135 // phi1(delta) = phi2(delta) = 21.0190 - 4.14 << 136 // with delta = 136mc^2kZ^{-1/3}/[E(Eg-E)] = 1 << 137 // Eg is the initial photon energy, E is the t << 138 // the e-/e+ pair, eps0 = mc^2/Eg and eps = E/ << 139 114 140 // Compute the value of the screening function << 141 inline G4double G4BetheHeitlerModel::ScreenFun << 142 { 115 { 143 return (delta > 1.4) ? 42.038 - 8.29*G4Log(d << 116 G4double screenVal; 144 : 42.184 - delta*(7.444 << 145 } << 146 117 147 // Compute the value of the screening function << 118 if (ScreenVariable > 1.) 148 inline G4double G4BetheHeitlerModel::ScreenFun << 119 screenVal = 42.24 - 8.368*std::log(ScreenVariable+0.952); 149 { << 120 else 150 return (delta > 1.4) ? 42.038 - 8.29*G4Log(d << 121 screenVal = 42.392 - ScreenVariable*(7.796 - 1.961*ScreenVariable); 151 : 41.326 - delta*(5.848 << 122 >> 123 return screenVal; 152 } 124 } 153 125 154 // Same as ScreenFunction1 and ScreenFunction2 << 126 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... 155 inline void G4BetheHeitlerModel::ScreenFunctio << 127 156 << 128 inline G4double G4BetheHeitlerModel::ScreenFunction2(G4double ScreenVariable) >> 129 >> 130 // compute the value of the screening function 1.5*PHI1 - 0.5*PHI2 >> 131 157 { 132 { 158 if (delta > 1.4) { << 133 G4double screenVal; 159 f1 = 42.038 - 8.29*G4Log(delta + 0.958); << 134 160 f2 = f1; << 135 if (ScreenVariable > 1.) 161 } else { << 136 screenVal = 42.24 - 8.368*std::log(ScreenVariable+0.952); 162 f1 = 42.184 - delta*(7.444 - 1.623*delta); << 137 else 163 f2 = 41.326 - delta*(5.848 - 0.902*delta); << 138 screenVal = 41.405 - ScreenVariable*(5.828 - 0.8945*ScreenVariable); 164 } << 139 >> 140 return screenVal; 165 } 141 } >> 142 >> 143 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 166 144 167 #endif 145 #endif 168 146