G4ANSTOecpssrLixsModel.cc

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//
// History:
// -----------
//  10 Nov 2021   S. Guatelli & S. Bakr, Wollongong University - 1st implementation
//
// Class description
// ----------------
//  Computation of K, L & M shell ECPSSR ionisation cross sections for protons and alphas
//  Based on the work of
//  - S. Bakr et al. (2021) NIM B, 507:11-19.
//  - S. Bakr et al (2018), NIMB B, 436: 285-291. 
// ---------------------------------------------------------------------------------------
 
#include <fstream>
#include <iomanip>
 
#include "G4ANSTOecpssrLixsModel.hh"
 
#include "globals.hh"
#include "G4SystemOfUnits.hh"
#include "G4ios.hh"
 
#include "G4EMDataSet.hh"
#include "G4LinInterpolation.hh"
#include "G4Proton.hh"
#include "G4Alpha.hh"
 
//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 
G4ANSTOecpssrLixsModel::G4ANSTOecpssrLixsModel()
{
  G4cout << "Using ANSTO L Cross Sections! "<< G4endl;
 
  interpolation = new G4LinInterpolation();
 
  for (G4int i=26; i<93; i++)
  {
      protonL1DataSetMap[i] = new G4EMDataSet(i,interpolation);
      protonL1DataSetMap[i]->LoadData("pixe_ANSTO/proton/l1-");
 
      protonL2DataSetMap[i] = new G4EMDataSet(i,interpolation);
      protonL2DataSetMap[i]->LoadData("pixe_ANSTO/proton/l2-");
 
      protonL3DataSetMap[i] = new G4EMDataSet(i,interpolation);
      protonL3DataSetMap[i]->LoadData("pixe_ANSTO/proton/l3-");
  }
 
  for (G4int i=26; i<93; i++)
  {
      alphaL1DataSetMap[i] = new G4EMDataSet(i,interpolation);
      alphaL1DataSetMap[i]->LoadData("pixe_ANSTO/alpha/l1-");
 
      alphaL2DataSetMap[i] = new G4EMDataSet(i,interpolation);
      alphaL2DataSetMap[i]->LoadData("pixe_ANSTO/alpha/l2-");
 
      alphaL3DataSetMap[i] = new G4EMDataSet(i,interpolation);
      alphaL3DataSetMap[i]->LoadData("pixe_ANSTO/alpha/l3-");
  }
 
}
 
//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 
G4ANSTOecpssrLixsModel::~G4ANSTOecpssrLixsModel()
{
  protonL1DataSetMap.clear();
  alphaL1DataSetMap.clear();
 
  protonL2DataSetMap.clear();
  alphaL2DataSetMap.clear();
 
  protonL3DataSetMap.clear();
  alphaL3DataSetMap.clear();
 
  delete interpolation;
}
 
//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 
G4double G4ANSTOecpssrLixsModel::CalculateL1CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
{
  G4Proton* aProton = G4Proton::Proton();
  G4Alpha* aAlpha = G4Alpha::Alpha();
  G4double sigma = 0;
 
  if (massIncident == aProton->GetPDGMass())
    {
 
  if (energyIncident > 0.2*MeV && energyIncident < 5.*MeV && zTarget < 93 && zTarget > 25) {
 
    sigma = protonL1DataSetMap[zTarget]->FindValue(energyIncident/MeV);
        if (sigma !=0 && energyIncident > protonL1DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
      }
 
    else if (massIncident == aAlpha->GetPDGMass())
      {
 
        if (energyIncident > 0.2*MeV && energyIncident < 40.*MeV && zTarget < 93 && zTarget > 25) {
 
        sigma = alphaL1DataSetMap[zTarget]->FindValue(energyIncident/MeV);
        if (sigma !=0 && energyIncident > alphaL1DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
      }
    else
      {
    sigma = 0.;
      }
  }
}
  // sigma is in internal units: it has been converted from
  // the input file in barns bt the EmDataset
  return sigma;
}
 
//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 
G4double G4ANSTOecpssrLixsModel::CalculateL2CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
{
  G4Proton* aProton = G4Proton::Proton();
  G4Alpha* aAlpha = G4Alpha::Alpha();
  G4double sigma = 0;
 
  if (massIncident == aProton->GetPDGMass())
    {
  if (energyIncident > 0.2*MeV && energyIncident < 5.*MeV && zTarget < 93 && zTarget > 25) {
 
    sigma = protonL2DataSetMap[zTarget]->FindValue(energyIncident/MeV);
        if (sigma !=0 && energyIncident > protonL2DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
      }
 
    else if (massIncident == aAlpha->GetPDGMass())
      {
        if (energyIncident > 0.2*MeV && energyIncident < 40.*MeV && zTarget < 93 && zTarget > 25) {
 
        sigma = alphaL2DataSetMap[zTarget]->FindValue(energyIncident/MeV);
        if (sigma !=0 && energyIncident > alphaL2DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
      }
    else
      {
    sigma = 0.;
      }
  }
}
  // sigma is in internal units: it has been converted from
  // the input file in barns bt the EmDataset
  return sigma;
}
 
//....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 
G4double G4ANSTOecpssrLixsModel::CalculateL3CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
{
  G4Proton* aProton = G4Proton::Proton();
  G4Alpha* aAlpha = G4Alpha::Alpha();
  G4double sigma = 0;
 
  if (massIncident == aProton->GetPDGMass())
    {
     if (energyIncident > 0.2*MeV && energyIncident < 5.*MeV && zTarget < 93 && zTarget > 25) {
 
          sigma = protonL3DataSetMap[zTarget]->FindValue(energyIncident/MeV);
        if (sigma !=0 && energyIncident > protonL3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
      }
    }
    
  else if (massIncident == aAlpha->GetPDGMass())
          {
           if (energyIncident > 0.2*MeV && energyIncident < 40.*MeV && zTarget < 93 && zTarget > 25) {
 
        sigma = alphaL3DataSetMap[zTarget]->FindValue(energyIncident/MeV);
        if (sigma !=0 && energyIncident > alphaL3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
             }
          }
    
  else
      {
         sigma = 0.;
      }
     
 
  // sigma is in internal units: it has been converted from
  // the input file in barns bt the EmDataset
  return sigma;
}