Geant4 Cross Reference |
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Please see the license in the file LICENSE and URL above * 16 // * for the full disclaimer and the limitatio 16 // * for the full disclaimer and the limitation of liability. * 17 // * 17 // * * 18 // * This code implementation is the result 18 // * This code implementation is the result of the scientific and * 19 // * technical work of the GEANT4 collaboratio 19 // * technical work of the GEANT4 collaboration. * 20 // * By using, copying, modifying or distri 20 // * By using, copying, modifying or distributing the software (or * 21 // * any work based on the software) you ag 21 // * any work based on the software) you agree to acknowledge its * 22 // * use in resulting scientific publicati 22 // * use in resulting scientific publications, and indicate your * 23 // * acceptance of all terms of the Geant4 Sof 23 // * acceptance of all terms of the Geant4 Software license. * 24 // ******************************************* 24 // ******************************************************************** 25 // 25 // 26 // 18-Sep-2003 First version is written by T. 26 // 18-Sep-2003 First version is written by T. Koi 27 // 12-Nov-2003 Add energy check at lower side 27 // 12-Nov-2003 Add energy check at lower side T. Koi 28 // 15-Nov-2006 Above 10GeV/n Cross Section bec 28 // 15-Nov-2006 Above 10GeV/n Cross Section become constant T. Koi (SLAC/SCCS) 29 // 23-Dec-2006 Isotope dependence adde by D. W 29 // 23-Dec-2006 Isotope dependence adde by D. Wright 30 // 14-Mar-2011 Moved constructor, destructor a << 31 // 19-Aug-2011 V.Ivanchenko move to new design << 32 // 30 // 33 31 34 #include "G4IonsShenCrossSection.hh" 32 #include "G4IonsShenCrossSection.hh" 35 #include "G4PhysicalConstants.hh" << 33 #include "G4ParticleTable.hh" 36 #include "G4SystemOfUnits.hh" << 34 #include "G4IonTable.hh" 37 #include "G4DynamicParticle.hh" << 38 #include "G4NucleiProperties.hh" << 39 #include "G4HadTmpUtil.hh" << 40 #include "G4NistManager.hh" << 41 << 42 G4IonsShenCrossSection::G4IonsShenCrossSection << 43 : G4VCrossSectionDataSet("IonsShen"), << 44 upperLimit( 10*GeV ), << 45 // lowerLimit( 10*MeV ), << 46 r0 ( 1.1 ) << 47 {} << 48 35 49 G4IonsShenCrossSection::~G4IonsShenCrossSectio << 50 {} << 51 << 52 void << 53 G4IonsShenCrossSection::CrossSectionDescriptio << 54 { << 55 outFile << "G4IonsShenCrossSection calculate << 56 << "section for nucleus-nucleus scat << 57 << "parameterization. It is valid f << 58 << "all Z, and projectile energies u << 59 << "the cross section is constant. << 60 << "is returned.\n"; << 61 } << 62 << 63 G4bool G4IonsShenCrossSection::IsElementApplic << 64 G4int, const G4Material*) << 65 { << 66 return (1 <= aDP->GetDefinition()->GetBaryon << 67 } << 68 << 69 G4double << 70 G4IonsShenCrossSection::GetElementCrossSection << 71 G4int Z, << 72 const G4Material*) << 73 { << 74 G4int A = G4lrint(G4NistManager::Instance()- << 75 return GetIsoCrossSection(aParticle, Z, A); << 76 } << 77 << 78 G4double G4IonsShenCrossSection::GetIsoCrossSe << 79 G4int Zt, G4int At, << 80 const G4Isotope*, << 81 const G4Element*, << 82 const G4Material*) << 83 36 >> 37 G4double G4IonsShenCrossSection:: >> 38 GetIsoZACrossSection(const G4DynamicParticle* aParticle, G4double ZZ, >> 39 G4double AA, G4double /*temperature*/) 84 { 40 { 85 G4double xsection = 0.0; 41 G4double xsection = 0.0; 86 42 87 G4int Ap = aParticle->GetDefinition()->GetB 43 G4int Ap = aParticle->GetDefinition()->GetBaryonNumber(); 88 G4int Zp = G4lrint(aParticle->GetDefinition << 44 G4int Zp = int ( aParticle->GetDefinition()->GetPDGCharge() / eplus + 0.5 ); 89 G4double ke_per_N = aParticle->GetKineticEn 45 G4double ke_per_N = aParticle->GetKineticEnergy() / Ap; 90 if ( ke_per_N > upperLimit ) { ke_per_N = u << 46 if ( ke_per_N > 10*GeV ) ke_per_N = 10*GeV; 91 47 92 // Apply energy check, if less than lower l << 48 // Apply energy check, if less than lower limit then 0 value is returned 93 //if ( ke_per_N < lowerLimit ) { return xs << 49 // if ( ke_per_N < lowerLimit ) return xsection; 94 50 95 G4Pow* g4pow = G4Pow::GetInstance(); << 51 G4int At = G4int(AA); 96 << 52 G4int Zt = G4int(ZZ); 97 G4double cubicrAt = g4pow->Z13(At); << 98 G4double cubicrAp = g4pow->Z13(Ap); << 99 53 >> 54 G4double one_third = 1.0 / 3.0; >> 55 >> 56 G4double cubicrAt = std::pow ( G4double(At) , G4double(one_third) ); >> 57 G4double cubicrAp = std::pow ( G4double(Ap) , G4double(one_third) ); >> 58 100 G4double Rt = 1.12 * cubicrAt - 0.94 * ( 1. 59 G4double Rt = 1.12 * cubicrAt - 0.94 * ( 1.0 / cubicrAt ); 101 G4double Rp = 1.12 * cubicrAp - 0.94 * ( 1. 60 G4double Rp = 1.12 * cubicrAp - 0.94 * ( 1.0 / cubicrAp ); 102 61 103 G4double r = Rt + Rp + 3.2; // in fm 62 G4double r = Rt + Rp + 3.2; // in fm 104 G4double b = 1.0; // in MeV/fm 63 G4double b = 1.0; // in MeV/fm 105 G4double targ_mass = G4NucleiProperties::Ge << 64 G4double targ_mass = G4ParticleTable::GetParticleTable()->GetIonTable()->GetIonMass( Zt , At ); 106 << 107 G4double proj_mass = aParticle->GetMass(); 65 G4double proj_mass = aParticle->GetMass(); 108 G4double proj_momentum = aParticle->GetMome 66 G4double proj_momentum = aParticle->GetMomentum().mag(); 109 67 110 G4double Ecm = calEcmValue (proj_mass, targ << 68 G4double Ecm = calEcmValue ( proj_mass , targ_mass , proj_momentum ); 111 69 112 G4double B = 1.44 * Zt * Zp / r - b * Rt * 70 G4double B = 1.44 * Zt * Zp / r - b * Rt * Rp / ( Rt + Rp ); 113 if(Ecm <= B) { return xsection; } << 71 if(Ecm <= B) return xsection; >> 72 //G4double ke_per_N = aParticle->GetKineticEnergy() / Ap; 114 73 115 G4double c = calCeValue ( ke_per_N / MeV ) 74 G4double c = calCeValue ( ke_per_N / MeV ); 116 75 117 G4double R1 = r0 * (cubicrAt + cubicrAp + 1 << 76 G4double R1 = r0 * ( cubicrAt + cubicrAp + 1.85 * cubicrAt * cubicrAp / ( cubicrAt + cubicrAp ) - c); 118 77 119 G4double R2 = 1.0 * ( At - 2 * Zt ) * Zp / 78 G4double R2 = 1.0 * ( At - 2 * Zt ) * Zp / ( Ap * At ); 120 79 121 80 122 G4double R3 = (0.176 / g4pow->A13(Ecm)) * c << 81 G4double R3 = 0.176 / std::pow ( G4double(Ecm) , G4double(one_third) ) * cubicrAt * cubicrAp / ( cubicrAt + cubicrAp ); 123 82 124 G4double R = R1 + R2 + R3; 83 G4double R = R1 + R2 + R3; 125 84 126 xsection = 10 * pi * R * R * ( 1 - B / Ecm 85 xsection = 10 * pi * R * R * ( 1 - B / Ecm ); 127 xsection = xsection * millibarn; // mulit << 86 xsection = xsection * millibarn; // mulitply xsection by millibarn 128 << 87 129 return xsection; 88 return xsection; 130 } 89 } 131 90 132 G4double << 91 133 G4IonsShenCrossSection::calEcmValue(const G4do << 92 G4double G4IonsShenCrossSection:: 134 const G4do << 93 GetCrossSection(const G4DynamicParticle* aParticle, const G4Element* anElement, >> 94 G4double temperature) >> 95 { >> 96 G4int nIso = anElement->GetNumberOfIsotopes(); >> 97 G4double xsection = 0; >> 98 >> 99 if (nIso) { >> 100 G4double sig; >> 101 G4IsotopeVector* isoVector = anElement->GetIsotopeVector(); >> 102 G4double* abundVector = anElement->GetRelativeAbundanceVector(); >> 103 G4double ZZ; >> 104 G4double AA; >> 105 >> 106 for (G4int i = 0; i < nIso; i++) { >> 107 ZZ = G4double( (*isoVector)[i]->GetZ() ); >> 108 AA = G4double( (*isoVector)[i]->GetN() ); >> 109 sig = GetIsoZACrossSection(aParticle, ZZ, AA, temperature); >> 110 xsection += sig*abundVector[i]; >> 111 } >> 112 >> 113 } else { >> 114 xsection = >> 115 GetIsoZACrossSection(aParticle, anElement->GetZ(), anElement->GetN(), >> 116 temperature); >> 117 } >> 118 >> 119 return xsection; >> 120 } >> 121 >> 122 >> 123 G4double G4IonsShenCrossSection::calEcmValue( const G4double mp , const G4double mt , const G4double Plab ) 135 { 124 { 136 G4double Elab = std::sqrt ( mp * mp + Plab 125 G4double Elab = std::sqrt ( mp * mp + Plab * Plab ); 137 G4double Ecm = std::sqrt ( mp * mp + mt * m 126 G4double Ecm = std::sqrt ( mp * mp + mt * mt + 2 * Elab * mt ); 138 G4double Pcm = Plab * mt / Ecm; 127 G4double Pcm = Plab * mt / Ecm; 139 G4double KEcm = std::sqrt ( Pcm * Pcm + mp 128 G4double KEcm = std::sqrt ( Pcm * Pcm + mp * mp ) - mp; 140 return KEcm; 129 return KEcm; 141 } 130 } 142 131 143 132 144 G4double G4IonsShenCrossSection::calCeValue(co << 133 G4double G4IonsShenCrossSection::calCeValue( const G4double ke ) 145 { 134 { 146 // Calculate c value << 135 // Calculate c value 147 // This value is indepenent from projectile << 136 // This value is indepenent from projectile and target particle 148 // ke is projectile kinetic energy per nucle << 137 // ke is projectile kinetic energy per nucleon in the Lab system with MeV unit 149 // with MeV unit << 138 // fitting function is made by T. Koi 150 // fitting function is made by T. Koi << 139 // There are no data below 30 MeV/n in Kox et al., 151 // There are no data below 30 MeV/n in Kox e << 152 140 153 G4double Ce; 141 G4double Ce; 154 G4double log10_ke = std::log10 ( ke ); 142 G4double log10_ke = std::log10 ( ke ); 155 if (log10_ke > 1.5) << 143 if ( log10_ke > 1.5 ) 156 { 144 { 157 Ce = -10.0/std::pow(G4double(log10_ke), G << 145 Ce = - 10.0 / std::pow ( G4double(log10_ke) , G4double(5) ) + 2.0; 158 } 146 } 159 else 147 else 160 { 148 { 161 Ce = (-10.0/std::pow(G4double(1.5), G4dou << 149 Ce = ( - 10.0 / std::pow ( G4double(1.5) , G4double(5) ) + 2.0 ) / std::pow ( G4double(1.5) , G4double(3) ) * std::pow ( G4double(log10_ke) , G4double(3) ); 162 std::pow(G4double(1.5) , G4double(3)) << 163 } 150 } 164 return Ce; 151 return Ce; 165 } 152 } 166 << 167 153