G4VPreCompoundFragment.cc

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//
//
// J. M. Quesada (August 2008).  Based  on previous work by V. Lara
//
// Modified:
// 20.08.2010 V.Ivanchenko added G4Pow and G4PreCompoundParameters pointers
//                         use int Z and A and cleanup
 
#include "G4VPreCompoundFragment.hh"
#include "G4SystemOfUnits.hh"
#include "G4NucleiProperties.hh"
#include "G4NuclearLevelData.hh"
#include "G4DeexPrecoParameters.hh"
#include "G4VCoulombBarrier.hh"
 
G4VPreCompoundFragment::G4VPreCompoundFragment(
  const G4ParticleDefinition* part, G4VCoulombBarrier* aCoulombBarrier)
  : theA(part->GetBaryonNumber()),
    theZ(G4lrint(part->GetPDGCharge()/CLHEP::eplus)),
    particle(part),
    theCoulombBarrierPtr(aCoulombBarrier)
{
  theMass = particle->GetPDGMass();
  fNucData = G4NuclearLevelData::GetInstance();
  theParameters = fNucData->GetParameters();
  g4calc = G4Pow::GetInstance();
}
 
G4VPreCompoundFragment::~G4VPreCompoundFragment()
{
  delete theCoulombBarrierPtr;
}
 
std::ostream& 
operator << (std::ostream &out, const G4VPreCompoundFragment &theFragment)
{
  out << &theFragment;
  return out; 
}
 
std::ostream& 
operator << (std::ostream &out, const G4VPreCompoundFragment *theFragment)
{
  out 
    << "PreCompoundModel Emitted Fragment: Z= " << theFragment->GetZ() 
    << " A= " << theFragment->GetA()
    << " Mass(GeV)= " << theFragment->GetNuclearMass()/CLHEP::GeV;
  return out;
}
 
void 
G4VPreCompoundFragment::Initialize(const G4Fragment& aFragment)
{
  theFragA = aFragment.GetA_asInt();
  theFragZ = aFragment.GetZ_asInt();
  theResA = theFragA - theA;
  theResZ = theFragZ - theZ;
 
  theMinKinEnergy = theMaxKinEnergy = theCoulombBarrier = 0.0;
  if ((theResA < theResZ) || (theResA < theA) || (theResZ < theZ)) {
    return;
  }
 
  theResA13 = g4calc->Z13(theResA);
 
  if (0 < theZ) {
    theCoulombBarrier = theCoulombBarrierPtr->
      GetCoulombBarrier(theResA, theResZ, aFragment.GetExcitationEnergy());
  }
  G4double elim = (0 == OPTxs) ? theCoulombBarrier : theCoulombBarrier*0.6;
  
  // Calculate masses
  theResMass = G4NucleiProperties::GetNuclearMass(theResA, theResZ);
  theReducedMass = theResMass*theMass/(theResMass + theMass);
 
  // Compute Binding Energies for fragments 
  // needed to separate a fragment from the nucleus
  theBindingEnergy = theResMass + theMass - aFragment.GetGroundStateMass();
    
  // Compute Maximal Kinetic Energy which can be carried by fragments 
  // after separation - the true assimptotic value
  G4double Ecm = aFragment.GetMomentum().m();
  G4double twoEcm = Ecm + Ecm;
  theMaxKinEnergy = std::max(((Ecm-theResMass)*(Ecm+theResMass) +
                  theMass*theMass)/twoEcm - theMass, 0.0);
  theMinKinEnergy = (elim == 0.0) ? 0.0 :
    std::max(((theMass+elim)*(twoEcm-theMass-elim) +
          theMass*theMass)/twoEcm - theMass, 0.0);
}