G4StatMFParameters.cc

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// $Id$
//
// Hadronic Process: Nuclear De-excitations
// by V. Lara
 
 
#include "G4StatMFParameters.hh"
#include "G4SystemOfUnits.hh"
 
const G4double G4StatMFParameters::_Kappa = 1.0; // dimensionless
 
const G4double G4StatMFParameters::_KappaCoulomb = 2.0; // dimensionless
 
const G4double G4StatMFParameters::_Epsilon0 = 16.0*MeV;
 
// Bethe-Weizsacker coefficients
const G4double G4StatMFParameters::_E0 = 16.0*MeV;
 
const G4double G4StatMFParameters::_Beta0 = 18.0*MeV;
 
const G4double G4StatMFParameters::_Gamma0 = 25.0*MeV;
 
// Critical temperature (for liquid-gas phase transitions)
const G4double G4StatMFParameters::_CriticalTemp = 18.0*MeV;
 
// Nuclear radius
const G4double G4StatMFParameters::_r0 = 1.17*fermi;
 
G4double G4StatMFParameters::Beta(const G4double T)
{
  if (T > _CriticalTemp) return 0.0;
  else {
    G4double CriticalTempSqr = _CriticalTemp*_CriticalTemp;
    G4double TempSqr = T*T;
    G4double tmp = (CriticalTempSqr-TempSqr)/(CriticalTempSqr+TempSqr);
        
    return _Beta0*tmp*std::pow(tmp,1.0/4.0);
  }
}
 
G4double G4StatMFParameters::DBetaDT(const G4double T) 
{
  if (T > _CriticalTemp) return 0.0;
  else {
    G4double CriticalTempSqr = _CriticalTemp*_CriticalTemp;
    G4double TempSqr = T*T;
    G4double tmp = (CriticalTempSqr-TempSqr)/(CriticalTempSqr+TempSqr);
        
    return -5.0*_Beta0*std::pow(tmp,1.0/4.0)*(CriticalTempSqr*T)/
      ((CriticalTempSqr+TempSqr)*(CriticalTempSqr+TempSqr));
  }
}
 
G4double G4StatMFParameters::GetMaxAverageMultiplicity(const G4int A)
{
  // Maximun average multiplicity: M_0 = 2.6 for A ~ 200 
  // and M_0 = 3.3 for A <= 110
  G4double MaxAverageMultiplicity = 2.6;
  if (A <= 110) MaxAverageMultiplicity = 3.3;
  return MaxAverageMultiplicity;
}
 
G4StatMFParameters G4StatMFParameters::theStatMFParameters;
 
 
G4StatMFParameters * G4StatMFParameters::GetAddress()
{ return &theStatMFParameters; }