source: trunk/source/processes/cuts/src/G4RToEConvForPositron.cc@ 968

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// $Id: G4RToEConvForPositron.cc,v 1.5 2006/06/29 19:30:28 gunter Exp $
// GEANT4 tag $Name: geant4-09-02-ref-02 $
//
//
// --------------------------------------------------------------
//      GEANT 4 class implementation file/  History:
//    5 Oct. 2002, H.Kuirashige : Structure created based on object model
// --------------------------------------------------------------

#include "G4RToEConvForPositron.hh"
#include "G4ParticleDefinition.hh"
#include "G4ParticleTable.hh"
#include "G4Material.hh"
#include "G4PhysicsLogVector.hh"

#include "G4ios.hh"

G4RToEConvForPositron::G4RToEConvForPositron() : G4VRangeToEnergyConverter()
{    
  theParticle =  G4ParticleTable::GetParticleTable()->FindParticle("e+");
  if (theParticle ==0) {
#ifdef G4VERBOSE
    if (GetVerboseLevel()>0) {
      G4cout << " G4RToEConvForPositron::G4RToEConvForPositron() ";
      G4cout << " Positron is not defined !!" << G4endl;
    }
#endif
  } 
}

G4RToEConvForPositron::~G4RToEConvForPositron()
{ 
}




// **********************************************************************
// ************************* ComputeLoss ********************************
// **********************************************************************
G4double G4RToEConvForPositron::ComputeLoss(G4double AtomicNumber,
                                            G4double KineticEnergy) const
{
  static G4double Z;  
  static G4double taul, ionpot, ionpotlog;
  const  G4double cbr1=0.02, cbr2=-5.7e-5, cbr3=1., cbr4=0.072;
  const  G4double Tlow=10.*keV, Thigh=1.*GeV;
  static G4double bremfactor = 0.1 ;

  G4double Mass = theParticle->GetPDGMass();       
  //  calculate dE/dx for electrons
  if( std::abs(AtomicNumber-Z)>0.1 ) {
    Z = AtomicNumber;
    taul = Tlow/Mass;
    ionpot = 1.6e-5*MeV*std::exp(0.9*std::log(Z))/Mass;
    ionpotlog = std::log(ionpot);
  } 

  G4double tau = KineticEnergy/Mass;
  G4double dEdx;

 if(tau<taul)
  {
    G4double t1 = taul+1.;
    G4double t2 = taul+2.;
    G4double tsq = taul*taul;
    G4double beta2 = taul*t2/(t1*t1);
    G4double     f = 2.*std::log(taul)
                     -(6.*taul+1.5*tsq-taul*(1.-tsq/3.)/t2-tsq*(0.5-tsq/12.)/
                       (t2*t2))/(t1*t1);
    dEdx = (std::log(2.*taul+4.)-2.*ionpotlog+f)/beta2;
    dEdx = twopi_mc2_rcl2*Z*dEdx;
    G4double clow = dEdx*std::sqrt(taul);
    dEdx = clow/std::sqrt(KineticEnergy/Mass);

  } else {
   G4double t1 = tau+1.;
    G4double t2 = tau+2.;
    G4double tsq = tau*tau;
    G4double beta2 = tau*t2/(t1*t1);
    G4double f = 2.*std::log(tau)
                 - (6.*tau+1.5*tsq-tau*(1.-tsq/3.)/t2-tsq*(0.5-tsq/12.)/
                     (t2*t2))/(t1*t1);
    dEdx = (std::log(2.*tau+4.)-2.*ionpotlog+f)/beta2;
    dEdx = twopi_mc2_rcl2*Z*dEdx;

    // loss from bremsstrahlung follows
    G4double cbrem = (cbr1+cbr2*Z)
                       *(cbr3+cbr4*std::log(KineticEnergy/Thigh));
    cbrem = Z*(Z+1.)*cbrem*tau/beta2;
    cbrem *= bremfactor ;
    dEdx += twopi_mc2_rcl2*cbrem;
  }
  return dEdx;
}



void G4RToEConvForPositron::BuildRangeVector(const G4Material* aMaterial,
                                             G4double       maxEnergy,
                                             G4double       aMass,
                                             G4PhysicsLogVector* rangeVector)
{
  //  create range vector for a material
  const G4double tlim = 10.*keV;
  const G4int maxnbint = 100;

  const G4ElementVector* elementVector = aMaterial->GetElementVector();
  const G4double* atomicNumDensityVector = aMaterial->GetAtomicNumDensityVector();
  G4int NumEl = aMaterial->GetNumberOfElements();

  // calculate parameters of the low energy part first
  size_t i;
  G4double loss=0.;
  for (i=0; i<size_t(NumEl); i++) {
    G4bool isOut;
    G4int IndEl = (*elementVector)[i]->GetIndex();
    loss += atomicNumDensityVector[i]*
           (*theLossTable)[IndEl]->GetValue(tlim,isOut);
  }
  G4double taulim = tlim/aMass;
  G4double clim = std::sqrt(taulim)*loss;
  G4double taumax = maxEnergy/aMass;

  // now the range vector can be filled
  for ( i=0; i<size_t(TotBin); i++) {
    G4double LowEdgeEnergy = rangeVector->GetLowEdgeEnergy(i);
    G4double tau = LowEdgeEnergy/aMass;

    if ( tau <= taulim ) {
      G4double Value = 2.*aMass*tau*std::sqrt(tau)/(3.*clim);
      rangeVector->PutValue(i,Value);
    } else {
      G4double rangelim = 2.*aMass*taulim*std::sqrt(taulim)/(3.*clim);
      G4double ltaulow = std::log(taulim);
      G4double ltauhigh = std::log(tau);
      G4double ltaumax = std::log(taumax);
      G4int    nbin = G4int(maxnbint*(ltauhigh-ltaulow)/(ltaumax-ltaulow));
      if( nbin < 1 ) nbin = 1;
      G4double Value = RangeLogSimpson( NumEl, elementVector,
                                        atomicNumDensityVector, aMass,
                                        ltaulow,       ltauhigh, nbin) 
                     + rangelim;
      rangeVector->PutValue(i,Value);
    }
  }
}