10.00/html/_g4ecpssr_form_factor_mixs_model_8cc_source.html

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 // ********************************************************************

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 // * This  code  implementation is the result of  the  scientific and *

 // * technical work of the GEANT4 collaboration.                      *

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 //

 // History:

 // -----------

 //  01 Oct 2011   A.M., S.I. - 1st implementation

 //

 // Class description

 // ----------------

 //  Computation of K, L & M shell ECPSSR ionisation cross sections for protons and alphas

 //  Based on the work of A. Taborda et al.

 //  EXRS2012 proceedings

 // ---------------------------------------------------------------------------------------


 #include <fstream>

 #include <iomanip>


 #include "globals.hh"

 #include "G4ios.hh"

 #include "G4SystemOfUnits.hh"


 #include "G4EMDataSet.hh"

 #include "G4LinInterpolation.hh"

 #include "G4Proton.hh"

 #include "G4Alpha.hh"


 #include "G4ecpssrFormFactorMixsModel.hh"


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......


 G4ecpssrFormFactorMixsModel::G4ecpssrFormFactorMixsModel()

 {

   interpolation = new G4LinInterpolation();


   for (G4int i=62; i<93; i++)

   {

       protonM1DataSetMap[i] = new G4EMDataSet(i,interpolation);

       protonM1DataSetMap[i]->LoadData("pixe/ecpssr/proton/m1-");


       protonM2DataSetMap[i] = new G4EMDataSet(i,interpolation);

       protonM2DataSetMap[i]->LoadData("pixe/ecpssr/proton/m2-");


       protonM3DataSetMap[i] = new G4EMDataSet(i,interpolation);

       protonM3DataSetMap[i]->LoadData("pixe/ecpssr/proton/m3-");


       protonM4DataSetMap[i] = new G4EMDataSet(i,interpolation);

       protonM4DataSetMap[i]->LoadData("pixe/ecpssr/proton/m4-");


       protonM5DataSetMap[i] = new G4EMDataSet(i,interpolation);

       protonM5DataSetMap[i]->LoadData("pixe/ecpssr/proton/m5-");

   }


   protonMiXsVector.push_back(protonM1DataSetMap);

   protonMiXsVector.push_back(protonM2DataSetMap);

   protonMiXsVector.push_back(protonM3DataSetMap);

   protonMiXsVector.push_back(protonM4DataSetMap);

   protonMiXsVector.push_back(protonM5DataSetMap);


   for (G4int i=62; i<93; i++)

   {

       alphaM1DataSetMap[i] = new G4EMDataSet(i,interpolation);

       alphaM1DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m1-");


       alphaM2DataSetMap[i] = new G4EMDataSet(i,interpolation);

       alphaM2DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m2-");


       alphaM3DataSetMap[i] = new G4EMDataSet(i,interpolation);

       alphaM3DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m3-");


       alphaM4DataSetMap[i] = new G4EMDataSet(i,interpolation);

       alphaM4DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m4-");


       alphaM5DataSetMap[i] = new G4EMDataSet(i,interpolation);

       alphaM5DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m5-");


   }


   alphaMiXsVector.push_back(alphaM1DataSetMap);

   alphaMiXsVector.push_back(alphaM2DataSetMap);

   alphaMiXsVector.push_back(alphaM3DataSetMap);

   alphaMiXsVector.push_back(alphaM4DataSetMap);

   alphaMiXsVector.push_back(alphaM5DataSetMap);


 }


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......


 G4ecpssrFormFactorMixsModel::~G4ecpssrFormFactorMixsModel()

 {

   protonM1DataSetMap.clear();

   alphaM1DataSetMap.clear();


   protonM2DataSetMap.clear();

   alphaM2DataSetMap.clear();


   protonM3DataSetMap.clear();

   alphaM3DataSetMap.clear();


   protonM4DataSetMap.clear();

   alphaM4DataSetMap.clear();


   protonM5DataSetMap.clear();

   alphaM5DataSetMap.clear();


   delete interpolation;

 }


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......


 G4double G4ecpssrFormFactorMixsModel::CalculateMiCrossSection(G4int zTarget,G4double massIncident, G4double energyIncident, G4int mShellId)

 {

   G4Proton* aProton = G4Proton::Proton();

   G4Alpha* aAlpha = G4Alpha::Alpha();

   G4double sigma = 0;

   G4int mShellIndex = mShellId -1;


   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {


     if (massIncident == aProton->GetPDGMass())

       {

     sigma = protonMiXsVector[mShellIndex][zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > protonMiXsVector[mShellIndex][zTarget]->GetEnergies(0).back()*MeV) return 0.;

       }

     else if (massIncident == aAlpha->GetPDGMass())

       {

         sigma = alphaMiXsVector[mShellIndex][zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > protonMiXsVector[mShellIndex][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 G4ecpssrFormFactorMixsModel::CalculateM1CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)

 {


   // mShellId

   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 1);


 }


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......


 G4double G4ecpssrFormFactorMixsModel::CalculateM2CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)

 {


   // mShellId

   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 2);


   /*


   G4Proton* aProton = G4Proton::Proton();

   G4Alpha* aAlpha = G4Alpha::Alpha();

   G4double sigma = 0;


   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {


     if (massIncident == aProton->GetPDGMass())

       {

     sigma = protonM2DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > protonM2DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;

       }

     else if (massIncident == aAlpha->GetPDGMass())

       {

         sigma = alphaM2DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > alphaM2DataSetMap[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 G4ecpssrFormFactorMixsModel::CalculateM3CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)

 {


   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 3);

   /*


   G4Proton* aProton = G4Proton::Proton();

   G4Alpha* aAlpha = G4Alpha::Alpha();

   G4double sigma = 0;


   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {


     if (massIncident == aProton->GetPDGMass())

       {

     sigma = protonM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > protonM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;

       }

     else if (massIncident == aAlpha->GetPDGMass())

       {

         sigma = alphaM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > alphaM3DataSetMap[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 G4ecpssrFormFactorMixsModel::CalculateM4CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)

 {


   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 4);

   /*

   G4Proton* aProton = G4Proton::Proton();

   G4Alpha* aAlpha = G4Alpha::Alpha();

   G4double sigma = 0;


   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {


     if (massIncident == aProton->GetPDGMass())

       {

     sigma = protonM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > protonM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;

       }

     else if (massIncident == aAlpha->GetPDGMass())

       {

         sigma = alphaM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > alphaM3DataSetMap[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 G4ecpssrFormFactorMixsModel::CalculateM5CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)

 {


   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 5);

   /*

   G4Proton* aProton = G4Proton::Proton();

   G4Alpha* aAlpha = G4Alpha::Alpha();

   G4double sigma = 0;


   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {


     if (massIncident == aProton->GetPDGMass())

       {

     sigma = protonM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > protonM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;

       }

     else if (massIncident == aAlpha->GetPDGMass())

       {

         sigma = alphaM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);

         if (sigma !=0 && energyIncident > alphaM3DataSetMap[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;

   */

 }

G4Alpha
Definition: G4Alpha.hh:51

python.hepunit.MeV
MeV
Definition: hepunit.py:117

G4ecpssrFormFactorMixsModel::~G4ecpssrFormFactorMixsModel
virtual ~G4ecpssrFormFactorMixsModel()
Definition: G4ecpssrFormFactorMixsModel.cc:113

G4ecpssrFormFactorMixsModel::CalculateM4CrossSection
G4double CalculateM4CrossSection(G4int zTarget, G4double massIncident, G4double energyIncident)
Definition: G4ecpssrFormFactorMixsModel.cc:252

G4int
int G4int
Definition: G4Types.hh:78

G4ecpssrFormFactorMixsModel::CalculateM3CrossSection
G4double CalculateM3CrossSection(G4int zTarget, G4double massIncident, G4double energyIncident)
Definition: G4ecpssrFormFactorMixsModel.cc:215

G4Proton.hh

G4ecpssrFormFactorMixsModel::CalculateM1CrossSection
G4double CalculateM1CrossSection(G4int zTarget, G4double massIncident, G4double energyIncident)
Definition: G4ecpssrFormFactorMixsModel.cc:167

G4Alpha.hh

G4Proton::Proton
static G4Proton * Proton()
Definition: G4Proton.cc:93

G4ecpssrFormFactorMixsModel::CalculateM5CrossSection
G4double CalculateM5CrossSection(G4int zTarget, G4double massIncident, G4double energyIncident)
Definition: G4ecpssrFormFactorMixsModel.cc:287

globals.hh

G4Proton
Definition: G4Proton.hh:51

G4LinInterpolation
Definition: G4LinInterpolation.hh:52

G4ecpssrFormFactorMixsModel::G4ecpssrFormFactorMixsModel
G4ecpssrFormFactorMixsModel()
Definition: G4ecpssrFormFactorMixsModel.cc:53

G4ecpssrFormFactorMixsModel.hh

G4ParticleDefinition::GetPDGMass
G4double GetPDGMass() const
Definition: G4ParticleDefinition.hh:161

G4EMDataSet.hh

G4ios.hh

G4LinInterpolation.hh

G4Alpha::Alpha
static G4Alpha * Alpha()
Definition: G4Alpha.cc:89

G4double
double G4double
Definition: G4Types.hh:76

G4SystemOfUnits.hh

G4ecpssrFormFactorMixsModel::CalculateM2CrossSection
G4double CalculateM2CrossSection(G4int zTarget, G4double massIncident, G4double energyIncident)
Definition: G4ecpssrFormFactorMixsModel.cc:177

G4EMDataSet
Definition: G4EMDataSet.hh:58