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Lara 31 // by V. Lara 30 32 >> 33 31 #include "G4StatMFMacroChemicalPotential.hh" 34 #include "G4StatMFMacroChemicalPotential.hh" 32 #include "G4PhysicalConstants.hh" << 33 #include "G4Pow.hh" << 34 35 35 // operators definitions 36 // operators definitions 36 G4StatMFMacroChemicalPotential & 37 G4StatMFMacroChemicalPotential & 37 G4StatMFMacroChemicalPotential::operator=(cons 38 G4StatMFMacroChemicalPotential::operator=(const G4StatMFMacroChemicalPotential & ) 38 { 39 { 39 throw G4HadronicException(__FILE__, __LINE << 40 throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroChemicalPotential::operator= meant to not be accessable"); 40 return *this; 41 return *this; 41 } 42 } 42 43 43 G4bool G4StatMFMacroChemicalPotential::operato 44 G4bool G4StatMFMacroChemicalPotential::operator==(const G4StatMFMacroChemicalPotential & ) const 44 { 45 { 45 throw G4HadronicException(__FILE__, __LINE << 46 throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroChemicalPotential::operator== meant to not be accessable"); 46 return false; 47 return false; 47 } 48 } 48 49 49 50 50 G4bool G4StatMFMacroChemicalPotential::operato 51 G4bool G4StatMFMacroChemicalPotential::operator!=(const G4StatMFMacroChemicalPotential & ) const 51 { 52 { 52 throw G4HadronicException(__FILE__, __LINE << 53 throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroChemicalPotential::operator!= meant to not be accessable"); 53 return true; 54 return true; 54 } 55 } 55 56 >> 57 >> 58 >> 59 56 G4double G4StatMFMacroChemicalPotential::CalcC 60 G4double G4StatMFMacroChemicalPotential::CalcChemicalPotentialNu(void) 57 // Calculate Chemical potential \nu << 61 // Calculate Chemical potential \nu 58 { 62 { 59 G4Pow* g4calc = G4Pow::GetInstance(); << 63 G4double CP = ((3./5.)*elm_coupling/G4StatMFParameters::Getr0())* 60 G4double CP = G4StatMFParameters::GetCoulomb << 64 (1.0-1.0/std::pow(1.0+G4StatMFParameters::GetKappaCoulomb(),1.0/3.0)); 61 65 62 // Initial value for _ChemPotentialNu << 66 // Initial value for _ChemPotentialNu 63 _ChemPotentialNu = (theZ/theA)*(8.0*G4StatMF << 67 _ChemPotentialNu = (theZ/theA)*(8.0*G4StatMFParameters::GetGamma0()+2.0*CP*std::pow(theA,2./3.)) - 64 +2.0*CP*g4calc->Z23(theA)) << 68 4.0*G4StatMFParameters::GetGamma0(); 65 - 4.0*G4StatMFParameters::GetGamma0(); << 66 69 67 G4double ChemPa = _ChemPotentialNu; << 70 68 G4double ChemPb = 0.5*_ChemPotentialNu; << 71 G4double ChemPa = _ChemPotentialNu; >> 72 G4double ChemPb = 0.5*_ChemPotentialNu; 69 73 70 G4double fChemPa = this->operator()(ChemPa); << 74 G4double fChemPa = this->operator()(ChemPa); 71 G4double fChemPb = this->operator()(ChemPb); << 75 G4double fChemPb = this->operator()(ChemPb); 72 76 73 if (fChemPa*fChemPb > 0.0) { << 77 if (fChemPa*fChemPb > 0.0) { 74 // bracketing the solution << 78 // bracketing the solution 75 if (fChemPa < 0.0) { << 79 if (fChemPa < 0.0) { 76 do { << 80 do { 77 ChemPb -= 1.5*std::abs(ChemPb-ChemPa); << 81 ChemPb -= 1.5*std::abs(ChemPb-ChemPa); 78 fChemPb = this->operator()(ChemPb); << 82 fChemPb = this->operator()(ChemPb); 79 // Loop checking, 05-Aug-2015, Vladimir Ivan << 83 } while (fChemPb < 0.0); 80 } while (fChemPb < 0.0); << 84 } else { 81 } else { << 85 do { 82 do { << 86 ChemPb += 1.5*std::abs(ChemPb-ChemPa); 83 ChemPb += 1.5*std::abs(ChemPb-ChemPa); << 87 fChemPb = this->operator()(ChemPb); 84 fChemPb = this->operator()(ChemPb); << 88 } while (fChemPb > 0.0); 85 // Loop checking, 05-Aug-2015, Vladimir Ivan << 89 } 86 } while (fChemPb > 0.0); << 87 } 90 } 88 } << 89 91 90 G4Solver<G4StatMFMacroChemicalPotential> * t << 92 G4Solver<G4StatMFMacroChemicalPotential> * theSolver = 91 new G4Solver<G4StatMFMacroChemicalPotentia << 93 new G4Solver<G4StatMFMacroChemicalPotential>(100,1.e-4); 92 theSolver->SetIntervalLimits(ChemPa,ChemPb); << 94 theSolver->SetIntervalLimits(ChemPa,ChemPb); 93 // if (!theSolver->Crenshaw(*this)) << 95 // if (!theSolver->Crenshaw(*this)) 94 if (!theSolver->Brent(*this)){ << 96 if (!theSolver->Brent(*this)){ 95 G4cout <<"G4StatMFMacroChemicalPotential:" << 97 G4cerr <<"G4StatMFMacroChemicalPotential:"<<" ChemPa="<<ChemPa<<" ChemPb="<<ChemPb<< G4endl; 96 <<" ChemPb="<<ChemPb<< G4endl; << 98 G4cerr <<"G4StatMFMacroChemicalPotential:"<<" fChemPa="<<fChemPa<<" fChemPb="<<fChemPb<< G4endl; 97 G4cout <<"G4StatMFMacroChemicalPotential:" << 99 throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroChemicalPotential::CalcChemicalPotentialNu: I couldn't find the root."); 98 <<" fChemPb="<<fChemPb<< G4endl; << 100 } 99 throw G4HadronicException(__FILE__, __LINE << 101 _ChemPotentialNu = theSolver->GetRoot(); 100 } << 102 delete theSolver; 101 _ChemPotentialNu = theSolver->GetRoot(); << 103 return _ChemPotentialNu; 102 delete theSolver; << 103 return _ChemPotentialNu; << 104 } 104 } 105 105 106 106 107 107 108 G4double G4StatMFMacroChemicalPotential::CalcM 108 G4double G4StatMFMacroChemicalPotential::CalcMeanZ(const G4double nu) 109 { 109 { 110 std::vector<G4VStatMFMacroCluster*>::iterato 110 std::vector<G4VStatMFMacroCluster*>::iterator i; 111 for (i= _theClusters->begin()+1; i != _theCl 111 for (i= _theClusters->begin()+1; i != _theClusters->end(); ++i) 112 { 112 { 113 (*i)->CalcZARatio(nu); 113 (*i)->CalcZARatio(nu); 114 } 114 } 115 CalcChemicalPotentialMu(nu); 115 CalcChemicalPotentialMu(nu); 116 // This is important, the Z over A ratio for 116 // This is important, the Z over A ratio for proton and neutron depends on the 117 // chemical potential Mu, while for the firs 117 // chemical potential Mu, while for the first guess for Chemical potential mu 118 // some values of Z over A ratio. This is th 118 // some values of Z over A ratio. This is the reason for that. 119 (*_theClusters->begin())->CalcZARatio(nu); 119 (*_theClusters->begin())->CalcZARatio(nu); 120 120 121 G4double MeanZ = 0.0; 121 G4double MeanZ = 0.0; 122 G4int n = 1; 122 G4int n = 1; 123 for (i = _theClusters->begin(); i != _theClu 123 for (i = _theClusters->begin(); i != _theClusters->end(); ++i) 124 { 124 { 125 MeanZ += (n++) * (*i)->GetZARatio() * (* << 125 MeanZ += static_cast<G4double>(n++) * >> 126 (*i)->GetZARatio() * >> 127 (*i)->GetMeanMultiplicity(); 126 } 128 } 127 return MeanZ; 129 return MeanZ; 128 } 130 } 129 131 >> 132 130 void G4StatMFMacroChemicalPotential::CalcChemi 133 void G4StatMFMacroChemicalPotential::CalcChemicalPotentialMu(const G4double nu) 131 // Calculate Chemical potential \mu << 134 // Calculate Chemical potential \mu 132 // For that is necesary to calculate mean mult << 135 // For that is necesary to calculate mean multiplicities 133 { 136 { 134 G4StatMFMacroMultiplicity * theMultip = new 137 G4StatMFMacroMultiplicity * theMultip = new 135 G4StatMFMacroMultiplicity(theA,_Kappa,_Mea 138 G4StatMFMacroMultiplicity(theA,_Kappa,_MeanTemperature,nu,_theClusters); 136 139 137 _ChemPotentialMu = theMultip->CalcChemicalPo 140 _ChemPotentialMu = theMultip->CalcChemicalPotentialMu(); 138 _MeanMultiplicity = theMultip->GetMeanMultip 141 _MeanMultiplicity = theMultip->GetMeanMultiplicity(); 139 142 140 delete theMultip; 143 delete theMultip; 141 144 142 return; << 145 return; >> 146 143 } 147 } 144 148