G4JAEAPolarizedElasticScatteringModel Class Reference

#include <G4JAEAPolarizedElasticScatteringModel.hh>

Inheritance diagram for G4JAEAPolarizedElasticScatteringModel:

Public Member Functions
	G4JAEAPolarizedElasticScatteringModel ()
virtual	~G4JAEAPolarizedElasticScatteringModel ()
void	Initialise (const G4ParticleDefinition *, const G4DataVector &) override
void	InitialiseLocal (const G4ParticleDefinition *, G4VEmModel *masterModel) override
void	InitialiseForElement (const G4ParticleDefinition *, G4int Z) override
G4double	ComputeCrossSectionPerAtom (const G4ParticleDefinition *, G4double kinEnergy, G4double Z, G4double A=0, G4double cut=0, G4double emax=DBL_MAX) override
void	SampleSecondaries (std::vector< G4DynamicParticle * > *, const G4MaterialCutsCouple *, const G4DynamicParticle *, G4double tmin, G4double maxEnergy) override
void	SetLowEnergyThreshold (G4double val)
void	SetPolarizationSensitvity (G4bool, G4bool, G4bool)
void	SetDebugVerbosity (G4int val)
G4JAEAPolarizedElasticScatteringModel &	operator= (const G4JAEAPolarizedElasticScatteringModel &right)=delete
	G4JAEAPolarizedElasticScatteringModel (const G4JAEAPolarizedElasticScatteringModel &)=delete
Public Member Functions inherited from G4VEmModel
	G4VEmModel (const G4String &nam)
virtual	~G4VEmModel ()
virtual void	Initialise (const G4ParticleDefinition *, const G4DataVector &)=0
virtual void	SampleSecondaries (std::vector< G4DynamicParticle * > *, const G4MaterialCutsCouple *, const G4DynamicParticle *, G4double tmin=0.0, G4double tmax=DBL_MAX)=0
virtual void	InitialiseLocal (const G4ParticleDefinition *, G4VEmModel *masterModel)
virtual void	InitialiseForMaterial (const G4ParticleDefinition *, const G4Material *)
virtual void	InitialiseForElement (const G4ParticleDefinition *, G4int Z)
virtual G4double	ComputeDEDXPerVolume (const G4Material *, const G4ParticleDefinition *, G4double kineticEnergy, G4double cutEnergy=DBL_MAX)
virtual G4double	CrossSectionPerVolume (const G4Material *, const G4ParticleDefinition *, G4double kineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
virtual G4double	GetPartialCrossSection (const G4Material *, G4int level, const G4ParticleDefinition *, G4double kineticEnergy)
virtual G4double	ComputeCrossSectionPerAtom (const G4ParticleDefinition *, G4double kinEnergy, G4double Z, G4double A=0., G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
virtual G4double	ComputeCrossSectionPerShell (const G4ParticleDefinition *, G4int Z, G4int shellIdx, G4double kinEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
virtual G4double	ChargeSquareRatio (const G4Track &)
virtual G4double	GetChargeSquareRatio (const G4ParticleDefinition *, const G4Material *, G4double kineticEnergy)
virtual G4double	GetParticleCharge (const G4ParticleDefinition *, const G4Material *, G4double kineticEnergy)
virtual void	StartTracking (G4Track *)
virtual void	CorrectionsAlongStep (const G4MaterialCutsCouple *, const G4DynamicParticle *, const G4double &length, G4double &eloss)
virtual G4double	Value (const G4MaterialCutsCouple *, const G4ParticleDefinition *, G4double kineticEnergy)
virtual G4double	MinPrimaryEnergy (const G4Material *, const G4ParticleDefinition *, G4double cut=0.0)
virtual G4double	MinEnergyCut (const G4ParticleDefinition *, const G4MaterialCutsCouple *)
virtual void	SetupForMaterial (const G4ParticleDefinition *, const G4Material *, G4double kineticEnergy)
virtual void	DefineForRegion (const G4Region *)
virtual void	FillNumberOfSecondaries (G4int &numberOfTriplets, G4int &numberOfRecoil)
virtual void	ModelDescription (std::ostream &outFile) const
void	InitialiseElementSelectors (const G4ParticleDefinition *, const G4DataVector &)
std::vector< G4EmElementSelector * > *	GetElementSelectors ()
void	SetElementSelectors (std::vector< G4EmElementSelector * > *)
G4double	ComputeDEDX (const G4MaterialCutsCouple *, const G4ParticleDefinition *, G4double kineticEnergy, G4double cutEnergy=DBL_MAX)
G4double	CrossSection (const G4MaterialCutsCouple *, const G4ParticleDefinition *, G4double kineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
G4double	ComputeMeanFreePath (const G4ParticleDefinition *, G4double kineticEnergy, const G4Material *, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
G4double	ComputeCrossSectionPerAtom (const G4ParticleDefinition *, const G4Element *, G4double kinEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
const G4Element *	SelectRandomAtom (const G4MaterialCutsCouple *, const G4ParticleDefinition *, G4double kineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
const G4Element *	SelectTargetAtom (const G4MaterialCutsCouple *, const G4ParticleDefinition *, G4double kineticEnergy, G4double logKineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
const G4Element *	SelectRandomAtom (const G4Material *, const G4ParticleDefinition *, G4double kineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
const G4Element *	GetCurrentElement (const G4Material *mat=nullptr) const
G4int	SelectRandomAtomNumber (const G4Material *) const
const G4Isotope *	GetCurrentIsotope (const G4Element *elm=nullptr) const
G4int	SelectIsotopeNumber (const G4Element *) const
void	SetParticleChange (G4VParticleChange *, G4VEmFluctuationModel *f=nullptr)
void	SetCrossSectionTable (G4PhysicsTable *, G4bool isLocal)
G4ElementData *	GetElementData ()
G4PhysicsTable *	GetCrossSectionTable ()
G4VEmFluctuationModel *	GetModelOfFluctuations ()
G4VEmAngularDistribution *	GetAngularDistribution ()
G4VEmModel *	GetTripletModel ()
void	SetTripletModel (G4VEmModel *)
void	SetAngularDistribution (G4VEmAngularDistribution *)
G4double	HighEnergyLimit () const
G4double	LowEnergyLimit () const
G4double	HighEnergyActivationLimit () const
G4double	LowEnergyActivationLimit () const
G4double	PolarAngleLimit () const
G4double	SecondaryThreshold () const
G4bool	LPMFlag () const
G4bool	DeexcitationFlag () const
G4bool	ForceBuildTableFlag () const
G4bool	UseAngularGeneratorFlag () const
void	SetAngularGeneratorFlag (G4bool)
void	SetHighEnergyLimit (G4double)
void	SetLowEnergyLimit (G4double)
void	SetActivationHighEnergyLimit (G4double)
void	SetActivationLowEnergyLimit (G4double)
G4bool	IsActive (G4double kinEnergy) const
void	SetPolarAngleLimit (G4double)
void	SetSecondaryThreshold (G4double)
void	SetLPMFlag (G4bool val)
void	SetDeexcitationFlag (G4bool val)
void	SetForceBuildTable (G4bool val)
void	SetFluctuationFlag (G4bool val)
void	SetMasterThread (G4bool val)
G4bool	IsMaster () const
void	SetUseBaseMaterials (G4bool val)
G4bool	UseBaseMaterials () const
G4double	MaxSecondaryKinEnergy (const G4DynamicParticle *dynParticle)
const G4String &	GetName () const
void	SetCurrentCouple (const G4MaterialCutsCouple *)
G4bool	IsLocked () const
void	SetLocked (G4bool)
G4VEmModel &	operator= (const G4VEmModel &right)=delete
	G4VEmModel (const G4VEmModel &)=delete

Additional Inherited Members
Protected Member Functions inherited from G4VEmModel
G4ParticleChangeForLoss *	GetParticleChangeForLoss ()
G4ParticleChangeForGamma *	GetParticleChangeForGamma ()
virtual G4double	MaxSecondaryEnergy (const G4ParticleDefinition *, G4double kineticEnergy)
const G4MaterialCutsCouple *	CurrentCouple () const
void	SetCurrentElement (const G4Element *)
Protected Attributes inherited from G4VEmModel
G4ElementData *	fElementData = nullptr
G4VParticleChange *	pParticleChange = nullptr
G4PhysicsTable *	xSectionTable = nullptr
const G4Material *	pBaseMaterial = nullptr
const std::vector< G4double > *	theDensityFactor = nullptr
const std::vector< G4int > *	theDensityIdx = nullptr
G4double	inveplus
G4double	pFactor = 1.0
size_t	currentCoupleIndex = 0
size_t	basedCoupleIndex = 0
G4bool	lossFlucFlag = true

Detailed Description

Definition at line 46 of file G4JAEAPolarizedElasticScatteringModel.hh.

Constructor & Destructor Documentation

G4JAEAPolarizedElasticScatteringModel() [1/2]

G4JAEAPolarizedElasticScatteringModel::G4JAEAPolarizedElasticScatteringModel ( )

explicit

Definition at line 49 of file G4JAEAPolarizedElasticScatteringModel.cc.

  :G4VEmModel("G4JAEAPolarizedElasticScatteringModel"),isInitialised(false)
{
  fParticleChange = 0;
  lowEnergyLimit  = 100 * keV;   //low energy limit for JAEAElasticScattering cross section data
  fLinearPolarizationSensitvity1=1;
  fLinearPolarizationSensitvity2=1;
  fCircularPolarizationSensitvity=1;
 
  verboseLevel= 0;
  // Verbosity scale for debugging purposes:
  // 0 = nothing
  // 1 = calculation of cross sections, file openings...
  // 2 = entering in methods
 
  if(verboseLevel > 0)
    {
      G4cout << "G4JAEAPolarizedElasticScatteringModel is constructed " << G4endl;
    }
 
}

~G4JAEAPolarizedElasticScatteringModel()

G4JAEAPolarizedElasticScatteringModel::~G4JAEAPolarizedElasticScatteringModel ( )

virtual

Definition at line 73 of file G4JAEAPolarizedElasticScatteringModel.cc.

{
  if(IsMaster()) {
    for(G4int i=0; i<=maxZ; ++i) {
      if(dataCS[i]) {
    delete dataCS[i];
    dataCS[i] = nullptr;
      }
      if (Polarized_ES_Data[i]){
    delete Polarized_ES_Data[i];
    Polarized_ES_Data[i] = nullptr;
      }
    }
  }
}

G4JAEAPolarizedElasticScatteringModel() [2/2]

G4JAEAPolarizedElasticScatteringModel::G4JAEAPolarizedElasticScatteringModel ( const G4JAEAPolarizedElasticScatteringModel &  )

delete

Member Function Documentation

ComputeCrossSectionPerAtom()

G4double G4JAEAPolarizedElasticScatteringModel::ComputeCrossSectionPerAtom ( const G4ParticleDefinition *  , G4double  kinEnergy, G4double  Z, G4double  A = 0, G4double  cut = 0, G4double  emax = DBL_MAX  )

overridevirtual

Reimplemented from G4VEmModel.

Definition at line 212 of file G4JAEAPolarizedElasticScatteringModel.cc.

{
  //Select the energy-grid point closest to the photon energy
  //        G4double *whichenergy = lower_bound(ESdata[0],ESdata[0]+300,GammaEnergy);
  //        int energyindex = max(0,(int)(whichenergy-ESdata[0]-1));
  
  if (verboseLevel > 1)
    {
      G4cout << "G4JAEAPolarizedElasticScatteringModel::ComputeCrossSectionPerAtom()"
         << G4endl;
    }
  
  if(GammaEnergy < lowEnergyLimit) { return 0.0; }
  
  G4double xs = 0.0;
  
  G4int intZ = G4lrint(Z);
  
  if(intZ < 1 || intZ > maxZ) { return xs; }
 
  G4PhysicsFreeVector* pv = dataCS[intZ];
 
  // if element was not initialised
  // do initialisation safely for MT mode
  if(!pv) {
    InitialiseForElement(0, intZ);
    pv = dataCS[intZ];
    if(!pv) { return xs; }
  }
 
  std::size_t n = pv->GetVectorLength() - 1;
 
  G4double e = GammaEnergy;
  if(e >= pv->Energy(n)) {
    xs = (*pv)[n];
  } else if(e >= pv->Energy(0)) {
    xs = pv->Value(e);
  }
 
  if(verboseLevel > 0)
    {
      G4cout  <<  "****** DEBUG: tcs value for Z=" << Z << " at energy (MeV)="
          << e << G4endl;
      G4cout  <<  "  cs (Geant4 internal unit)=" << xs << G4endl;
      G4cout  <<  "    -> first E*E*cs value in CS data file (iu) =" << (*pv)[0]
          << G4endl;
      G4cout  <<  "    -> last  E*E*cs value in CS data file (iu) =" << (*pv)[n]
          << G4endl;
      G4cout  <<  "*********************************************************"
          << G4endl;
    }
 
  return (xs);
}

Initialise()

void G4JAEAPolarizedElasticScatteringModel::Initialise ( const G4ParticleDefinition *  particle, const G4DataVector &  cuts  )

overridevirtual

Implements G4VEmModel.

Definition at line 91 of file G4JAEAPolarizedElasticScatteringModel.cc.

{
  if (verboseLevel > 1)
    {
      G4cout << "Calling Initialise() of G4JAEAPolarizedElasticScatteringModel." << G4endl
         << "Energy range: "
         << LowEnergyLimit() / eV << " eV - "
         << HighEnergyLimit() / GeV << " GeV"
         << G4endl;
    }
 
  if(IsMaster()) {
 
    // Initialise element selector
    InitialiseElementSelectors(particle, cuts);
 
    // Access to elements
    const char* path = G4FindDataDir("G4LEDATA");
    G4ProductionCutsTable* theCoupleTable =
      G4ProductionCutsTable::GetProductionCutsTable();
    G4int numOfCouples = (G4int)theCoupleTable->GetTableSize();
 
    for(G4int i=0; i<numOfCouples; ++i)
      {
    const G4MaterialCutsCouple* couple =
      theCoupleTable->GetMaterialCutsCouple(i);
    const G4Material* material = couple->GetMaterial();
    const G4ElementVector* theElementVector = material->GetElementVector();
    std::size_t nelm = material->GetNumberOfElements();
 
    for (std::size_t j=0; j<nelm; ++j)
      {
        G4int Z = G4lrint((*theElementVector)[j]->GetZ());
        if(Z < 1)          { Z = 1; }
        else if(Z > maxZ)  { Z = maxZ; }
        if( (!dataCS[Z]) ) { ReadData(Z, path); }
      }
      }
  }
 
  if(isInitialised) { return; }
  fParticleChange = GetParticleChangeForGamma();
  isInitialised = true;
 
}

InitialiseForElement()

void G4JAEAPolarizedElasticScatteringModel::InitialiseForElement ( const G4ParticleDefinition *  , G4int  Z  )

overridevirtual

Reimplemented from G4VEmModel.

Definition at line 589 of file G4JAEAPolarizedElasticScatteringModel.cc.

{
  G4AutoLock l(&G4JAEAPolarizedElasticScatteringModelMutex);
  //  G4cout << "G4JAEAPolarizedElasticScatteringModel::InitialiseForElement Z= "
  //   << Z << G4endl;
  if(!dataCS[Z]) { ReadData(Z); }
  l.unlock();
}

Referenced by ComputeCrossSectionPerAtom().

InitialiseLocal()

void G4JAEAPolarizedElasticScatteringModel::InitialiseLocal ( const G4ParticleDefinition *  , G4VEmModel *  masterModel  )

overridevirtual

Reimplemented from G4VEmModel.

Definition at line 140 of file G4JAEAPolarizedElasticScatteringModel.cc.

{
  SetElementSelectors(masterModel->GetElementSelectors());
}

operator=()

G4JAEAPolarizedElasticScatteringModel & G4JAEAPolarizedElasticScatteringModel::operator= ( const G4JAEAPolarizedElasticScatteringModel &  right )

delete

SampleSecondaries()

void G4JAEAPolarizedElasticScatteringModel::SampleSecondaries ( std::vector< G4DynamicParticle * > *  , const G4MaterialCutsCouple *  couple, const G4DynamicParticle *  aDynamicGamma, G4double  tmin, G4double  maxEnergy  )

overridevirtual

Implements G4VEmModel.

Definition at line 273 of file G4JAEAPolarizedElasticScatteringModel.cc.

{
  if (verboseLevel > 1) {
 
    G4cout << "Calling SampleSecondaries() of G4JAEAPolarizedElasticScatteringModel."
       << G4endl;
  }
  G4double photonEnergy0 = aDynamicGamma->GetKineticEnergy();
 
  // absorption of low-energy gamma
  if (photonEnergy0 <= lowEnergyLimit)
    {
      fParticleChange->ProposeTrackStatus(fStopAndKill);
      fParticleChange->SetProposedKineticEnergy(0.);
      fParticleChange->ProposeLocalEnergyDeposit(photonEnergy0);
      return ;
    }
 
  const G4ParticleDefinition* particle =  aDynamicGamma->GetDefinition();
  const G4Element* elm = SelectRandomAtom(couple,particle,photonEnergy0);
  G4int Z = G4lrint(elm->GetZ());
 
  //Getting the corresponding distrbution
  G4int energyindex=round(100*photonEnergy0)-1;
  G4double a1=0, a2=0, a3=0,a4=0;
  for (G4int i=0;i<=180;++i)
    {
      a1=Polarized_ES_Data[Z]->at(4*i+300+181*4*(energyindex));
      a2=Polarized_ES_Data[Z]->at(4*i+1+300+181*4*(energyindex));
      a3=Polarized_ES_Data[Z]->at(4*i+2+300+181*4*(energyindex));
      a4=Polarized_ES_Data[Z]->at(4*i+3+300+181*4*(energyindex));
      distribution[i]=a1*a1+a2*a2+a3*a3+a4*a4;
    }
 
  CLHEP::RandGeneral GenThetaDist(distribution,180);
  //Intial sampling of the scattering angle. To be updated for the circular polarization
  G4double theta = CLHEP::pi*GenThetaDist.shoot();
  //G4double theta =45.*CLHEP::pi/180.;
  //Theta is in degree to call scattering amplitudes
  G4int theta_in_degree =round(theta*180./CLHEP::pi);
 
  //theta_in_degree=45;
 
  G4double am1=0,am2=0,am3=0,am4=0,aparaSquare=0,aperpSquare=0,
    apara_aper_Asterisk=0,img_apara_aper_Asterisk=0;
  am1=Polarized_ES_Data[Z]->at(4*theta_in_degree+300+181*4*(energyindex));
  am2=Polarized_ES_Data[Z]->at(4*theta_in_degree+1+300+181*4*(energyindex));
  am3=Polarized_ES_Data[Z]->at(4*theta_in_degree+2+300+181*4*(energyindex));
  am4=Polarized_ES_Data[Z]->at(4*theta_in_degree+3+300+181*4*(energyindex));
  aparaSquare=am1*am1+am2*am2;
  aperpSquare=am3*am3+am4*am4;
  apara_aper_Asterisk=2*a1*a3+2*a2*a4;
  img_apara_aper_Asterisk=2*a1*a4-2*a2*a3;
 
  G4ThreeVector Direction_Unpolarized(0.,0.,0.);
  G4ThreeVector Direction_Linear1(0.,0.,0.);
  G4ThreeVector Direction_Linear2(0.,0.,0.);
  G4ThreeVector Direction_Circular(0.,0.,0.);
  G4ThreeVector Polarization_Unpolarized(0.,0.,0.);
  G4ThreeVector Polarization_Linear1(0.,0.,0.);
  G4ThreeVector Polarization_Linear2(0.,0.,0.);
  G4ThreeVector Polarization_Circular(0.,0.,0.);
 
  //Stokes parameters for the incoming and outgoing photon
  G4double Xi1=0, Xi2=0, Xi3=0, Xi1_Prime=0,Xi2_Prime=0,Xi3_Prime=0;
    
  //Getting the Stokes parameters for the incoming photon
  G4ThreeVector gammaPolarization0 = aDynamicGamma->GetPolarization();
  Xi1=gammaPolarization0.x();
  Xi2=gammaPolarization0.y();
  Xi3=gammaPolarization0.z();
    
  //Polarization vector must be unit vector (5% tolerance)    
  if ((gammaPolarization0.mag())>1.05 || (Xi1*Xi1>1.05) || (Xi2*Xi2>1.05) || (Xi3*Xi3>1.05))
    {
      G4Exception("G4JAEAPolarizedElasticScatteringModel::SampleSecondaries()","em1006",
          JustWarning,
          "WARNING: G4JAEAPolarizedElasticScatteringModel is only compatible with a unit polarization vector.");
      return;
    }
  //Unpolarized gamma rays
  if (Xi1==0 && Xi2==0 && Xi3==0)
    {
      G4double Phi_Unpolarized=0;
      if (fLinearPolarizationSensitvity1)
    Phi_Unpolarized=GeneratePolarizedPhi(aparaSquare,aperpSquare,0.);
      else
    Phi_Unpolarized=CLHEP::twopi*G4UniformRand();
      Direction_Unpolarized.setX(sin(theta)*cos(Phi_Unpolarized));
      Direction_Unpolarized.setY(sin(theta)*sin(Phi_Unpolarized));
      Direction_Unpolarized.setZ(cos(theta));
      Direction_Unpolarized.rotateUz(aDynamicGamma->GetMomentumDirection());
      Xi1_Prime=(aparaSquare-aperpSquare)/(aparaSquare+aperpSquare);
      Polarization_Unpolarized.setX(Xi1_Prime);
      Polarization_Unpolarized.setY(0.);
      Polarization_Unpolarized.setZ(0.);
      fParticleChange->ProposeMomentumDirection(Direction_Unpolarized);
      fParticleChange->ProposePolarization(Polarization_Unpolarized);
      return;
    }
 
  //Linear polarization defined by first Stokes parameter
  G4double InitialAzimuth=aDynamicGamma->GetMomentumDirection().phi();
  if(InitialAzimuth<0) InitialAzimuth=InitialAzimuth+CLHEP::twopi;
    
  G4double Phi_Linear1=0.;
 
  Phi_Linear1 = GeneratePolarizedPhi(aparaSquare+aperpSquare+Xi1*(aparaSquare-aperpSquare),
                     aparaSquare+aperpSquare-Xi1*(aparaSquare-aperpSquare),InitialAzimuth);
 
  Xi1_Prime=((aparaSquare-aperpSquare)+Xi1*(aparaSquare+aperpSquare)*cos(2*Phi_Linear1))/
    ((aparaSquare+aperpSquare)+Xi1*(aparaSquare-aperpSquare)*cos(2*Phi_Linear1));
  Xi2_Prime=(-Xi1*apara_aper_Asterisk*sin(2*Phi_Linear1))/
    ((aparaSquare+aperpSquare)+Xi1*(aparaSquare-aperpSquare)*cos(2*Phi_Linear1));
  Xi3_Prime=(-Xi1*img_apara_aper_Asterisk*sin(2*Phi_Linear1))/
    ((aparaSquare+aperpSquare)+Xi1*(aparaSquare-aperpSquare)*cos(2*Phi_Linear1));
  //Store momentum direction and po;arization
  Direction_Linear1.setX(sin(theta)*cos(Phi_Linear1));
  Direction_Linear1.setY(sin(theta)*sin(Phi_Linear1));
  Direction_Linear1.setZ(cos(theta));
  Polarization_Linear1.setX(Xi1_Prime);
  Polarization_Linear1.setY(Xi2_Prime);
  Polarization_Linear1.setZ(Xi3_Prime);
    
  //Set scattered photon polarization sensitivity
  Xi1_Prime=Xi1_Prime*fLinearPolarizationSensitvity1;
  Xi2_Prime=Xi2_Prime*fLinearPolarizationSensitvity2;
  Xi3_Prime=Xi3_Prime*fCircularPolarizationSensitvity;
    
  G4double dsigmaL1=0.0;
  if(abs(Xi1)>0.0) dsigmaL1=0.25*((aparaSquare+aperpSquare)*
                  (1+Xi1*Xi1_Prime*cos(2*Phi_Linear1))+
                  (aparaSquare-aperpSquare)*(Xi1*cos(2*Phi_Linear1)+Xi1_Prime)
                  -Xi1*Xi2_Prime*apara_aper_Asterisk*sin(2*Phi_Linear1)-
                  Xi1*Xi3_Prime*img_apara_aper_Asterisk*sin(2*Phi_Linear1));
 
  //Linear polarization defined by second Stokes parameter
  //G4double IntialAzimuth=aDynamicGamma->GetMomentumDirection().phi();
  G4double Phi_Linear2=0.;
 
  InitialAzimuth=InitialAzimuth-CLHEP::pi/4.;
  if(InitialAzimuth<0) InitialAzimuth=InitialAzimuth+CLHEP::twopi;
 
  Phi_Linear2 = GeneratePolarizedPhi(aparaSquare+aperpSquare+Xi1*(aparaSquare-aperpSquare)
                     ,aparaSquare+aperpSquare-Xi1*(aparaSquare-aperpSquare),InitialAzimuth);
    
  Xi1_Prime=((aparaSquare-aperpSquare)+Xi2*(aparaSquare+aperpSquare)*sin(2*Phi_Linear2))/
    ((aparaSquare+aperpSquare)+Xi2*(aparaSquare-aperpSquare)*sin(2*Phi_Linear2));
  Xi2_Prime=(Xi2*apara_aper_Asterisk*cos(2*Phi_Linear2))/
    ((aparaSquare+aperpSquare)+Xi2*(aparaSquare-aperpSquare)*sin(2*Phi_Linear2));
  Xi3_Prime=(Xi2*img_apara_aper_Asterisk*cos(2*Phi_Linear2))/
    ((aparaSquare+aperpSquare)+Xi2*(aparaSquare-aperpSquare)*sin(2*Phi_Linear2));
  //Store momentum direction and polarization
  Direction_Linear2.setX(sin(theta)*cos(Phi_Linear2));
  Direction_Linear2.setY(sin(theta)*sin(Phi_Linear2));
  Direction_Linear2.setZ(cos(theta));
  Polarization_Linear2.setX(Xi1_Prime);
  Polarization_Linear2.setY(Xi2_Prime);
  Polarization_Linear2.setZ(Xi3_Prime);
 
  //Set scattered photon polarization sensitivity
  Xi1_Prime=Xi1_Prime*fLinearPolarizationSensitvity1;
  Xi2_Prime=Xi2_Prime*fLinearPolarizationSensitvity2;
  Xi3_Prime=Xi3_Prime*fCircularPolarizationSensitvity;
 
  G4double dsigmaL2=0.0;
  if(abs(Xi2)>0.0)
    dsigmaL2=0.25*((aparaSquare+aperpSquare)*(1+Xi2*Xi1_Prime*sin(2*Phi_Linear2))+
           (aparaSquare-aperpSquare)*(Xi2*sin(2*Phi_Linear2)+Xi1_Prime)
           +Xi2*Xi2_Prime*apara_aper_Asterisk*cos(2*Phi_Linear2)-
           Xi2*Xi3_Prime*img_apara_aper_Asterisk*cos(2*Phi_Linear2));
 
  //Circular polarization
  G4double Phi_Circular = CLHEP::twopi*G4UniformRand();
  G4double Theta_Circular = 0.;
    
  Xi1_Prime=(aparaSquare-aperpSquare)/(aparaSquare+aperpSquare);
  Xi2_Prime=(-Xi3*img_apara_aper_Asterisk)/(aparaSquare+aperpSquare);
  Xi3_Prime=(Xi3*apara_aper_Asterisk)/(aparaSquare+aperpSquare);
    
  Polarization_Circular.setX(Xi1_Prime);
  Polarization_Circular.setY(Xi2_Prime);
  Polarization_Circular.setZ(Xi3_Prime);
    
  //Set scattered photon polarization sensitivity
  Xi1_Prime=Xi1_Prime*fLinearPolarizationSensitvity1;
  Xi2_Prime=Xi2_Prime*fLinearPolarizationSensitvity2;
  Xi3_Prime=Xi3_Prime*fCircularPolarizationSensitvity;
    
  G4double dsigmaC=0.0;
  if(abs(Xi3)>0.0)
    dsigmaC=0.25*(aparaSquare+aperpSquare+Xi1_Prime*(aparaSquare-aperpSquare)-
          Xi3*Xi2_Prime*img_apara_aper_Asterisk
          +Xi3*Xi3_Prime*apara_aper_Asterisk);
 
  if (abs(Xi3)==0.0 && abs(Xi1_Prime)==0.0)
    {
      Direction_Circular.setX(sin(theta)*cos(Phi_Circular));
      Direction_Circular.setY(sin(theta)*sin(Phi_Circular));
      Direction_Circular.setZ(cos(theta));
    }
  else
    {
      G4double c1=0, c2=0, c3=0,c4=0;
      for (G4int i=0;i<=180;++i)
    {
      c1=Polarized_ES_Data[Z]->at(4*i+300+181*4*(energyindex));
      c2=Polarized_ES_Data[Z]->at(4*i+1+300+181*4*(energyindex));
      c3=Polarized_ES_Data[Z]->at(4*i+2+300+181*4*(energyindex));
      c4=Polarized_ES_Data[Z]->at(4*i+3+300+181*4*(energyindex));
      cdistribution[i]=0.25*((c1*c1+c2*c2+c3*c3+c4*c4)+
                 Xi1_Prime*(c1*c1+c2*c2-c3*c3-c4*c4)-
                 Xi3*Xi2_Prime*(2*c1*c4-2*c2*c3)
                 +Xi3*Xi3_Prime*(2*c1*c4-2*c2*c3));
    }
      CLHEP::RandGeneral GenTheta_Circ_Dist(cdistribution,180);
      Theta_Circular=CLHEP::pi*GenTheta_Circ_Dist.shoot();
      Direction_Circular.setX(sin(Theta_Circular)*cos(Phi_Circular));
      Direction_Circular.setY(sin(Theta_Circular)*sin(Phi_Circular));
      Direction_Circular.setZ(cos(Theta_Circular));
    }
 
  // Sampling scattered photon direction based on asymmetry arising from polarization mixing
  G4double totalSigma= dsigmaL1+dsigmaL2+dsigmaC;
  G4double prob1=dsigmaL1/totalSigma;
  G4double prob2=dsigmaL2/totalSigma;
  G4double probc=1-(prob1+prob2);
    
  //Check the Probability of polarization mixing
  if (abs(probc - dsigmaC/totalSigma)>=0.0001)
    {
      G4Exception("G4JAEAPolarizedElasticScatteringModel::SampleSecondaries()","em1007",
          JustWarning,
          "WARNING: Polarization mixing might be incorrect.");
    }
    
  // Generate outgoing photon direction
  G4ThreeVector finaldirection(0.0,0.0,0.0);
  G4ThreeVector outcomingPhotonPolarization(0.0,0.0,0.0);
    
  //Polarization mixing
  G4double polmix=G4UniformRand();
  if (polmix<=prob1)
    {
      finaldirection.setX(Direction_Linear1.x());
      finaldirection.setY(Direction_Linear1.y());
      finaldirection.setZ(Direction_Linear1.z());
      outcomingPhotonPolarization.setX(Polarization_Linear1.x());
      outcomingPhotonPolarization.setY(Polarization_Linear1.y());
      outcomingPhotonPolarization.setZ(Polarization_Linear1.z());
    }
  else if ((polmix>prob1) && (polmix<=prob1+prob2))
    {
      finaldirection.setX(Direction_Linear2.x());
      finaldirection.setY(Direction_Linear2.y());
      finaldirection.setZ(Direction_Linear2.z());
      outcomingPhotonPolarization.setX(Polarization_Linear2.x());
      outcomingPhotonPolarization.setY(Polarization_Linear2.y());
      outcomingPhotonPolarization.setZ(Polarization_Linear2.z());
    }
  else if (polmix>prob1+prob2)
    {
      finaldirection.setX(Direction_Circular.x());
      finaldirection.setY(Direction_Circular.y());
      finaldirection.setZ(Direction_Circular.z());
      outcomingPhotonPolarization.setX(Polarization_Circular.x());
      outcomingPhotonPolarization.setY(Polarization_Circular.y());
      outcomingPhotonPolarization.setZ(Polarization_Circular.z());
    }
 
  //Sampling the Final State
  finaldirection.rotateUz(aDynamicGamma->GetMomentumDirection());
  fParticleChange->ProposeMomentumDirection(finaldirection);
  fParticleChange->SetProposedKineticEnergy(photonEnergy0);
  fParticleChange->ProposePolarization(outcomingPhotonPolarization);
    
}

SetDebugVerbosity()

void G4JAEAPolarizedElasticScatteringModel::SetDebugVerbosity ( G4int  val )

inline

Definition at line 76 of file G4JAEAPolarizedElasticScatteringModel.hh.

{verboseLevel = val;};

SetLowEnergyThreshold()

void G4JAEAPolarizedElasticScatteringModel::SetLowEnergyThreshold ( G4double  val )

inline

Definition at line 73 of file G4JAEAPolarizedElasticScatteringModel.hh.

{lowEnergyLimit = val;};

SetPolarizationSensitvity()

void G4JAEAPolarizedElasticScatteringModel::SetPolarizationSensitvity ( G4bool  linear1, G4bool  linear2, G4bool  circular  )

inline

Definition at line 104 of file G4JAEAPolarizedElasticScatteringModel.hh.

{
  fLinearPolarizationSensitvity1=linear1;
  fLinearPolarizationSensitvity2=linear2;
  fCircularPolarizationSensitvity=circular;
}

---

The documentation for this class was generated from the following files:

• G4JAEAPolarizedElasticScatteringModel.hh
• G4JAEAPolarizedElasticScatteringModel.cc