G4StatMFMacroNucleon.cc

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// $Id: G4StatMFMacroNucleon.cc 68724 2013-04-05 09:26:32Z gcosmo $
//
// Hadronic Process: Nuclear De-excitations
// by V. Lara

#include "G4StatMFMacroNucleon.hh"
#include "G4PhysicalConstants.hh"
#include "G4SystemOfUnits.hh"

G4StatMFMacroNucleon::G4StatMFMacroNucleon() 
  : G4VStatMFMacroCluster(1), _NeutronMeanMultiplicity(0.0),
    _ProtonMeanMultiplicity(0.0)
{}

G4StatMFMacroNucleon::~G4StatMFMacroNucleon() 
{}
        
G4double 
G4StatMFMacroNucleon::CalcMeanMultiplicity(const G4double FreeVol, 
                                           const G4double mu, 
                                           const G4double nu, const G4double T)
{
  if (T <= 0.0) {
    throw G4HadronicException(__FILE__, __LINE__, 
                              "G4StatMFMacroNucleon::CalcMeanMultiplicity: Temperature less or equal 0");
  }

  G4double ThermalWaveLenght = 16.15*fermi/std::sqrt(T);
        
  G4double lambda3 = ThermalWaveLenght*ThermalWaveLenght*ThermalWaveLenght;
        
  static const G4double degeneracy = 2.0;
        
  G4double Coulomb = (3./5.)*(elm_coupling/G4StatMFParameters::Getr0())*
    (1.0 - 1.0/std::pow(1.0+G4StatMFParameters::GetKappaCoulomb(),1./3.));

  G4double exponent_proton = (mu+nu-Coulomb)/T;
  G4double exponent_neutron = mu/T;

  if (exponent_neutron > 700.0) exponent_neutron = 700.0;
  if (exponent_proton > 700.0) exponent_proton = 700.0;

  _NeutronMeanMultiplicity = 
    (degeneracy*FreeVol/lambda3)*std::exp(exponent_neutron);
        
  _ProtonMeanMultiplicity = 
    (degeneracy*FreeVol/lambda3)*std::exp(exponent_proton);

  return _MeanMultiplicity = _NeutronMeanMultiplicity + _ProtonMeanMultiplicity;
}


G4double G4StatMFMacroNucleon::CalcEnergy(const G4double T)
{
  G4double Coulomb = (3./5.)*(elm_coupling/G4StatMFParameters::Getr0())*
    (1.0 - 1.0/std::pow(1.0+G4StatMFParameters::GetKappaCoulomb(),1./3.));
                                                                        
  return _Energy = Coulomb * theZARatio * theZARatio + (3./2.) * T;
}

G4double 
G4StatMFMacroNucleon::CalcEntropy(const G4double T, const G4double FreeVol)
{
  G4double ThermalWaveLenght = 16.15*fermi/std::sqrt(T);
  G4double lambda3 = ThermalWaveLenght*ThermalWaveLenght*ThermalWaveLenght;

  G4double NeutronEntropy = 0.0;
  if (_NeutronMeanMultiplicity > 0.0)
    NeutronEntropy = _NeutronMeanMultiplicity*(5./2.+
                      std::log(2.0*static_cast<G4double>(theA)*FreeVol/
                               (lambda3*_NeutronMeanMultiplicity)));
                                
  G4double ProtonEntropy = 0.0;
  if (_ProtonMeanMultiplicity > 0.0)
    ProtonEntropy = _ProtonMeanMultiplicity*(5./2.+
                      std::log(2.0*static_cast<G4double>(theA)*FreeVol/
                               (lambda3*_ProtonMeanMultiplicity)));
                                
  return NeutronEntropy+ProtonEntropy;
}