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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 // 26 // >> 27 // $Id: G4StatMFFragment.cc,v 1.6 2006/06/29 20:24:47 gunter Exp $ >> 28 // GEANT4 tag $Name: geant4-08-03-patch-02 $ 27 // 29 // 28 // Hadronic Process: Nuclear De-excitations 30 // Hadronic Process: Nuclear De-excitations 29 // by V. Lara 31 // by V. Lara 30 32 31 #include "G4StatMFFragment.hh" 33 #include "G4StatMFFragment.hh" 32 #include "G4PhysicalConstants.hh" << 33 #include "G4HadronicException.hh" 34 #include "G4HadronicException.hh" 34 #include "G4Pow.hh" << 35 35 36 36 // Copy constructor 37 // Copy constructor 37 G4StatMFFragment::G4StatMFFragment(const G4Sta 38 G4StatMFFragment::G4StatMFFragment(const G4StatMFFragment & ) 38 { 39 { 39 throw G4HadronicException(__FILE__, __LINE << 40 throw G4HadronicException(__FILE__, __LINE__, "G4StatMFFragment::copy_constructor meant to not be accessable"); 40 } 41 } 41 42 42 // Operators 43 // Operators 43 44 44 G4StatMFFragment & G4StatMFFragment:: 45 G4StatMFFragment & G4StatMFFragment:: 45 operator=(const G4StatMFFragment & ) 46 operator=(const G4StatMFFragment & ) 46 { 47 { 47 throw G4HadronicException(__FILE__, __LINE << 48 throw G4HadronicException(__FILE__, __LINE__, "G4StatMFFragment::operator= meant to not be accessable"); 48 return *this; 49 return *this; 49 } 50 } 50 51 >> 52 51 G4bool G4StatMFFragment::operator==(const G4St 53 G4bool G4StatMFFragment::operator==(const G4StatMFFragment & ) const 52 { 54 { 53 // throw G4HadronicException(__FILE__, __LINE << 55 // throw G4HadronicException(__FILE__, __LINE__, "G4StatMFFragment::operator== meant to not be accessable"); 54 return false; 56 return false; 55 } 57 } 56 58 >> 59 57 G4bool G4StatMFFragment::operator!=(const G4St 60 G4bool G4StatMFFragment::operator!=(const G4StatMFFragment & ) const 58 { 61 { 59 // throw G4HadronicException(__FILE__, __LINE << 62 // throw G4HadronicException(__FILE__, __LINE__, "G4StatMFFragment::operator!= meant to not be accessable"); 60 return true; 63 return true; 61 } 64 } 62 65 >> 66 >> 67 63 G4double G4StatMFFragment::GetCoulombEnergy(vo 68 G4double G4StatMFFragment::GetCoulombEnergy(void) const 64 { 69 { 65 G4double res = 0.0; << 70 if (theZ <= 0.1) return 0.0; 66 if (theZ >= 1) { << 71 G4double Coulomb = (3./5.)*(elm_coupling*theZ*theZ)* 67 res = G4StatMFParameters::GetCoulomb(); << 72 std::pow(1.0+G4StatMFParameters::GetKappaCoulomb(),1./3.)/ 68 } << 73 (G4StatMFParameters::Getr0()*std::pow(theA,1./3.)); 69 return res; << 74 >> 75 return Coulomb; 70 } 76 } 71 77 >> 78 72 G4double G4StatMFFragment::GetEnergy(const G4d 79 G4double G4StatMFFragment::GetEnergy(const G4double T) const 73 { 80 { 74 if (theA < 1 || theZ < 0 || theZ > theA) { << 81 if (theA < 1 || theZ < 0 || theZ > theA) { 75 G4cout << "G4StatMFFragment::GetEnergy: A << 82 G4cerr << "G4StatMFFragment::GetEnergy: A = " << theA 76 << ", Z = " << theZ << G4endl; << 83 << ", Z = " << theZ << G4endl; 77 throw G4HadronicException(__FILE__, __LINE << 84 throw G4HadronicException(__FILE__, __LINE__, 78 "G4StatMFFragment::GetEnergy: Wron << 85 "G4StatMFFragment::GetEnergy: Wrong values for A and Z!"); 79 } << 86 } 80 G4double BulkEnergy = G4NucleiProperties::Ge << 87 G4double BulkEnergy = G4NucleiProperties::GetMassExcess(static_cast<G4int>(theA), 81 << 88 static_cast<G4int>(theZ)); 82 if (theA < 4) return BulkEnergy - GetCoulomb << 89 83 << 90 if (theA < 4) return BulkEnergy - GetCoulombEnergy(); 84 G4double SurfaceEnergy; << 91 85 if (G4StatMFParameters::DBetaDT(T) == 0.0) S << 92 G4double SurfaceEnergy; 86 else SurfaceEnergy = 2.5*G4Pow::GetInstance( << 93 if (G4StatMFParameters::DBetaDT(T) == 0.0) SurfaceEnergy = 0.0; 87 G4StatMFParameters::GetBeta0()/ << 94 else SurfaceEnergy = (5./2.)*std::pow(theA,2.0/3.0)*T*T* 88 (G4StatMFParameters::GetCriticalTemp()* << 95 G4StatMFParameters::GetBeta0()/ 89 G4StatMFParameters::GetCriticalTemp()); << 96 (G4StatMFParameters::GetCriticalTemp()* 90 << 97 G4StatMFParameters::GetCriticalTemp()); 91 G4double ExchangeEnergy = theA*T*T/GetInvLev << 98 92 if (theA != 4) ExchangeEnergy += SurfaceEner << 99 93 return BulkEnergy + ExchangeEnergy - GetCoul << 100 G4double ExchangeEnergy = theA*T*T/GetInvLevelDensity(); >> 101 if (theA != 4) ExchangeEnergy += SurfaceEnergy; >> 102 >> 103 return BulkEnergy + ExchangeEnergy - GetCoulombEnergy(); >> 104 94 } 105 } 95 106 >> 107 96 G4double G4StatMFFragment::GetInvLevelDensity( 108 G4double G4StatMFFragment::GetInvLevelDensity(void) const 97 { 109 { 98 G4double res = 0.0; << 110 // Calculate Inverse Density Level 99 if (theA > 1) { << 111 // Epsilon0*(1 + 3 /(Af - 1)) 100 res = G4StatMFParameters::GetEpsilon0()*( << 112 if (theA == 1) return 0.0; 101 } << 113 else return 102 return res; << 114 G4StatMFParameters::GetEpsilon0()*(1.0+3.0/(theA - 1.0)); 103 } 115 } 104 116 >> 117 >> 118 105 G4Fragment * G4StatMFFragment::GetFragment(con 119 G4Fragment * G4StatMFFragment::GetFragment(const G4double T) 106 { 120 { 107 G4double U = CalcExcitationEnergy(T); << 121 G4double U = CalcExcitationEnergy(T); 108 G4double M = GetNuclearMass(); << 122 109 G4LorentzVector FourMomentum(_momentum,std:: << 123 G4double M = GetNuclearMass(); 110 G4Fragment * theFragment = new G4Fragment(th << 124 111 return theFragment; << 125 G4LorentzVector FourMomentum(_momentum,std::sqrt(_momentum.mag2()+(M+U)*(M+U))); >> 126 >> 127 G4Fragment * theFragment = new G4Fragment(static_cast<G4int>(theA),static_cast<G4int>(theZ),FourMomentum); >> 128 >> 129 return theFragment; 112 } 130 } 113 131 >> 132 114 G4double G4StatMFFragment::CalcExcitationEnerg 133 G4double G4StatMFFragment::CalcExcitationEnergy(const G4double T) 115 { 134 { 116 if (theA <= 3) return 0.0; << 135 if (theA <= 3) return 0.0; >> 136 >> 137 G4double BulkEnergy = theA*T*T/GetInvLevelDensity(); 117 138 118 G4double BulkEnergy = theA*T*T/GetInvLevelDe << 139 // if it is an alpha particle: done >> 140 if (theA == 4) return BulkEnergy; 119 141 120 // if it is an alpha particle: done << 142 // Term connected with surface energy 121 if (theA == 4) return BulkEnergy; << 143 G4double SurfaceEnergy = 0.0; 122 << 144 if (std::abs(G4StatMFParameters::DBetaDT(T)) > 1.0e-20) 123 // Term connected with surface energy << 145 // SurfaceEnergy = (5./2.)*std::pow(theA,2.0/3.0)*T*T*G4StatMFParameters::GetBeta0()/ 124 G4double SurfaceEnergy = 0.0; << 146 // (G4StatMFParameters::GetCriticalTemp()*G4StatMFParameters::GetCriticalTemp()); 125 G4double q = G4StatMFParameters::DBetaDT(T); << 147 SurfaceEnergy = (5./2.)*std::pow(theA,2.0/3.0)*(G4StatMFParameters::Beta(T) - 126 if (std::abs(q) > 1.0e-20) { << 148 T*G4StatMFParameters::DBetaDT(T) - G4StatMFParameters::GetBeta0()); 127 SurfaceEnergy = 2.5*G4Pow::GetInstance()-> << 149 128 *(G4StatMFParameters::Beta(T) - T*q - G4 << 150 return BulkEnergy + SurfaceEnergy; 129 } << 130 return BulkEnergy + SurfaceEnergy; << 131 } 151 } >> 152 >> 153 132 154