#include <G4MicroElecInelasticModel_new.hh>

Inheritance diagram for G4MicroElecInelasticModel_new:

Public Member Functions
G4double	BKZ (G4double Ep, G4double mp, G4int Zp, G4double EF)

virtual G4double	ChargeSquareRatio (const G4Track &)

G4double	ComputeCrossSectionPerAtom (const G4ParticleDefinition , const G4Element , G4double kinEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)

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)

G4double	ComputeDEDX (const G4MaterialCutsCouple , const G4ParticleDefinition , G4double kineticEnergy, G4double cutEnergy=DBL_MAX)

virtual G4double	ComputeDEDXPerVolume (const G4Material , const G4ParticleDefinition , G4double kineticEnergy, G4double cutEnergy=DBL_MAX)

G4double	ComputeElasticQmax (G4double T1i, G4double T2i, G4double m1, G4double m2)

G4double	ComputeMeanFreePath (const G4ParticleDefinition , G4double kineticEnergy, const G4Material , G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)

G4double	ComputeRelativistVelocity (G4double E, G4double mass)

virtual void	CorrectionsAlongStep (const G4MaterialCutsCouple , const G4DynamicParticle , const G4double &length, G4double &eloss)

G4double	CrossSection (const G4MaterialCutsCouple , const G4ParticleDefinition , G4double kineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)

G4double	CrossSectionPerVolume (const G4Material material, const G4ParticleDefinition p, G4double ekin, G4double emin, G4double emax) override

G4bool	DeexcitationFlag () const

virtual void	DefineForRegion (const G4Region *)

G4double	DifferentialCrossSection (const G4ParticleDefinition *aParticleDefinition, G4double k, G4double energyTransfer, G4int shell)

virtual void	FillNumberOfSecondaries (G4int &numberOfTriplets, G4int &numberOfRecoil)

G4bool	ForceBuildTableFlag () const

	G4MicroElecInelasticModel_new (const G4MicroElecInelasticModel_new &)=delete

	G4MicroElecInelasticModel_new (const G4ParticleDefinition *p=nullptr, const G4String &nam="MicroElecInelasticModel")

G4VEmAngularDistribution *	GetAngularDistribution ()

virtual G4double	GetChargeSquareRatio (const G4ParticleDefinition , const G4Material , G4double kineticEnergy)

G4PhysicsTable *	GetCrossSectionTable ()

const G4Element *	GetCurrentElement () const

const G4Isotope *	GetCurrentIsotope () const

G4ElementData *	GetElementData ()

std::vector< G4EmElementSelector * > *	GetElementSelectors ()

G4VEmFluctuationModel *	GetModelOfFluctuations ()

const G4String &	GetName () const

virtual G4double	GetPartialCrossSection (const G4Material , G4int level, const G4ParticleDefinition , G4double kineticEnergy)

virtual G4double	GetParticleCharge (const G4ParticleDefinition , const G4Material , G4double kineticEnergy)

G4VEmModel *	GetTripletModel ()

G4double	HighEnergyActivationLimit () const

G4double	HighEnergyLimit () const

void	Initialise (const G4ParticleDefinition *, const G4DataVector &) override

void	InitialiseElementSelectors (const G4ParticleDefinition *, const G4DataVector &)

virtual void	InitialiseForElement (const G4ParticleDefinition *, G4int Z)

virtual void	InitialiseForMaterial (const G4ParticleDefinition , const G4Material )

virtual void	InitialiseLocal (const G4ParticleDefinition , G4VEmModel masterModel)

G4bool	IsActive (G4double kinEnergy) const

G4bool	IsLocked () const

G4bool	IsMaster () const

G4double	LowEnergyActivationLimit () const

G4double	LowEnergyLimit () const

G4bool	LPMFlag () const

G4double	MaxSecondaryKinEnergy (const G4DynamicParticle *dynParticle)

virtual G4double	MinEnergyCut (const G4ParticleDefinition , const G4MaterialCutsCouple )

virtual G4double	MinPrimaryEnergy (const G4Material , const G4ParticleDefinition , G4double cut=0.0)

virtual void	ModelDescription (std::ostream &outFile) const

G4MicroElecInelasticModel_new &	operator= (const G4MicroElecInelasticModel_new &right)=delete

G4double	PolarAngleLimit () const

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

G4double	SecondaryThreshold () const

G4int	SelectIsotopeNumber (const G4Element *)

const G4Element *	SelectRandomAtom (const G4Material , const G4ParticleDefinition , G4double kineticEnergy, 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)

G4int	SelectRandomAtomNumber (const G4Material *)

const G4Element *	SelectTargetAtom (const G4MaterialCutsCouple , const G4ParticleDefinition , G4double kineticEnergy, G4double logKineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)

void	SetActivationHighEnergyLimit (G4double)

void	SetActivationLowEnergyLimit (G4double)

void	SetAngularDistribution (G4VEmAngularDistribution *)

void	SetAngularGeneratorFlag (G4bool)

void	SetCrossSectionTable (G4PhysicsTable *, G4bool isLocal)

void	SetCurrentCouple (const G4MaterialCutsCouple *)

void	SetDeexcitationFlag (G4bool val)

void	SetElementSelectors (std::vector< G4EmElementSelector * > *)

void	SetFluctuationFlag (G4bool val)

void	SetForceBuildTable (G4bool val)

void	SetHighEnergyLimit (G4double)

void	SetLocked (G4bool)

void	SetLowEnergyLimit (G4double)

void	SetLPMFlag (G4bool val)

void	SetMasterThread (G4bool val)

void	SetParticleChange (G4VParticleChange , G4VEmFluctuationModel f=nullptr)

void	SetPolarAngleLimit (G4double)

void	SetSecondaryThreshold (G4double)

void	SetTripletModel (G4VEmModel *)

virtual void	SetupForMaterial (const G4ParticleDefinition , const G4Material , G4double kineticEnergy)

void	SetUseBaseMaterials (G4bool val)

virtual void	StartTracking (G4Track *)

G4double	stepFunc (G4double x)

G4bool	UseAngularGeneratorFlag () const

G4bool	UseBaseMaterials () const

virtual G4double	Value (const G4MaterialCutsCouple , const G4ParticleDefinition , G4double kineticEnergy)

G4double	vrkreussler (G4double v, G4double vF)

	~G4MicroElecInelasticModel_new () override

Protected Member Functions
const G4MaterialCutsCouple *	CurrentCouple () const

G4ParticleChangeForGamma *	GetParticleChangeForGamma ()

G4ParticleChangeForLoss *	GetParticleChangeForLoss ()

virtual G4double	MaxSecondaryEnergy (const G4ParticleDefinition *, G4double kineticEnergy)

void	SetCurrentElement (const G4Element *)

Protected Attributes
size_t	basedCoupleIndex = 0

size_t	currentCoupleIndex = 0

G4ElementData *	fElementData = nullptr

G4ParticleChangeForGamma *	fParticleChangeForGamma = nullptr

G4double	inveplus

G4bool	lossFlucFlag = true

const G4Material *	pBaseMaterial = nullptr

G4double	pFactor = 1.0

G4VParticleChange *	pParticleChange = nullptr

const std::vector< G4double > *	theDensityFactor = nullptr

const std::vector< G4int > *	theDensityIdx = nullptr

G4PhysicsTable *	xSectionTable = nullptr

Private Types
typedef std::map< G4String, std::vector< TriDimensionMap > * >	dataDiffCSMap

typedef std::map< G4String, std::vector< VecMap > * >	dataProbaShellMap

typedef std::map< G4String, std::vector< G4double > * >	incidentEnergyMap

typedef std::map< G4String, G4MicroElecCrossSectionDataSet_new *, std::less< G4String > >	MapData

typedef std::map< G4String, G4String, std::less< G4String > >	MapFile

typedef std::map< G4String, G4MicroElecMaterialStructure *, std::less< G4String > >	MapStructure

typedef std::map< G4String, MapData *, std::less< G4String > >	TCSMap

typedef std::map< G4String, VecMap * >	TranfEnergyMap

typedef std::map< G4double, std::map< G4double, G4double > >	TriDimensionMap

typedef std::map< G4double, std::vector< G4double > >	VecMap

Private Member Functions
G4double	Interpolate (G4double e1, G4double e2, G4double e, G4double xs1, G4double xs2)

G4double	QuadInterpolator (G4double e11, G4double e12, G4double e21, G4double e22, G4double x11, G4double x12, G4double x21, G4double x22, G4double t1, G4double t2, G4double t, G4double e)

G4double	RandomizeCreatedElectronEnergy (G4double secondaryKinetic)

G4double	RandomizeEjectedElectronEnergy (const G4ParticleDefinition *aParticleDefinition, G4double incomingParticleEnergy, G4int shell, G4double originalMass, G4int originalZ)

G4double	RandomizeEjectedElectronEnergyFromCumulatedDcs (const G4ParticleDefinition *, G4double k, G4int shell)

G4int	RandomSelect (G4double energy, const G4String &particle, G4double originalMass, G4int originalZ)

G4double	TransferedEnergy (const G4ParticleDefinition *, G4double k, G4int ionizationLevelIndex, G4double random)

Private Attributes
G4VEmAngularDistribution *	anglModel = nullptr

G4String	currentMaterial = ""

G4MicroElecMaterialStructure *	currentMaterialStructure = nullptr

dataDiffCSMap	eDiffDatatable

incidentEnergyMap	eIncidentEnergyStorage

std::vector< G4EmElementSelector * > *	elmSelectors = nullptr

G4double	eMaxActive = DBL_MAX

G4double	eMinActive = 0.0

dataDiffCSMap	eNrjTransStorage

dataProbaShellMap	eProbaShellStorage

TranfEnergyMap	eVecmStorage

G4bool	fasterCode

G4VAtomDeexcitation *	fAtomDeexcitation = nullptr

const G4MaterialCutsCouple *	fCurrentCouple = nullptr

const G4Element *	fCurrentElement = nullptr

const G4Isotope *	fCurrentIsotope = nullptr

G4LossTableManager *	fEmManager

G4bool	flagDeexcitation = false

G4bool	flagForceBuildTable = false

G4VEmFluctuationModel *	flucModel = nullptr

G4VEmModel *	fTripletModel = nullptr

std::map< G4String, G4double, std::less< G4String > >	highEnergyLimit

G4double	highLimit

G4bool	isInitialised

G4bool	isLocked = false

G4bool	isMaster = true

G4bool	localElmSelectors = true

G4bool	localTable = true

std::map< G4String, G4double, std::less< G4String > >	lowEnergyLimit

G4double	lowLimit

const G4String	name

G4Material *	nistSi = nullptr

G4int	nsec = 5

G4int	nSelectors = 0

dataDiffCSMap	pDiffDatatable

incidentEnergyMap	pIncidentEnergyStorage

dataDiffCSMap	pNrjTransStorage

G4double	polarAngleLimit

dataProbaShellMap	pProbaShellStorage

TranfEnergyMap	pVecmStorage

G4double	secondaryThreshold = DBL_MAX

G4bool	SEFromFermiLevel

MapStructure	tableMaterialsStructures

TCSMap	tableTCS

G4bool	theLPMflag = false

G4bool	useAngularGenerator = false

G4bool	useBaseMaterials = false

G4int	verboseLevel

std::vector< G4double >	xsec

Detailed Description

Definition at line 93 of file G4MicroElecInelasticModel_new.hh.

Member Typedef Documentation

◆ dataDiffCSMap

typedef std::map<G4String, std::vector<TriDimensionMap>* > G4MicroElecInelasticModel_new::dataDiffCSMap

private

Definition at line 174 of file G4MicroElecInelasticModel_new.hh.

◆ dataProbaShellMap

typedef std::map<G4String, std::vector<VecMap>* > G4MicroElecInelasticModel_new::dataProbaShellMap

private

Definition at line 177 of file G4MicroElecInelasticModel_new.hh.

◆ incidentEnergyMap

typedef std::map<G4String, std::vector<G4double>* > G4MicroElecInelasticModel_new::incidentEnergyMap

private

Definition at line 179 of file G4MicroElecInelasticModel_new.hh.

◆ MapData

typedef std::map<G4String,G4MicroElecCrossSectionDataSet_new*,std::less<G4String> > G4MicroElecInelasticModel_new::MapData

private

Definition at line 167 of file G4MicroElecInelasticModel_new.hh.

◆ MapFile

typedef std::map<G4String,G4String,std::less<G4String> > G4MicroElecInelasticModel_new::MapFile

private

Definition at line 166 of file G4MicroElecInelasticModel_new.hh.

◆ MapStructure

typedef std::map<G4String, G4MicroElecMaterialStructure*, std::less<G4String> > G4MicroElecInelasticModel_new::MapStructure

private

Definition at line 183 of file G4MicroElecInelasticModel_new.hh.

◆ TCSMap

typedef std::map<G4String, MapData*, std::less<G4String> > G4MicroElecInelasticModel_new::TCSMap

private

Definition at line 172 of file G4MicroElecInelasticModel_new.hh.

◆ TranfEnergyMap

typedef std::map<G4String, VecMap* > G4MicroElecInelasticModel_new::TranfEnergyMap

private

Definition at line 181 of file G4MicroElecInelasticModel_new.hh.

◆ TriDimensionMap

typedef std::map<G4double, std::map<G4double, G4double> > G4MicroElecInelasticModel_new::TriDimensionMap

private

Definition at line 168 of file G4MicroElecInelasticModel_new.hh.

◆ VecMap

typedef std::map<G4double, std::vector<G4double> > G4MicroElecInelasticModel_new::VecMap

private

Definition at line 169 of file G4MicroElecInelasticModel_new.hh.

Constructor & Destructor Documentation

◆ G4MicroElecInelasticModel_new() [1/2]

G4MicroElecInelasticModel_new::G4MicroElecInelasticModel_new	(	const G4ParticleDefinition *	p = `nullptr`,
		const G4String &	nam = `"MicroElecInelasticModel"`
	)

explicit

Definition at line 97 of file G4MicroElecInelasticModel_new.cc.

  :G4VEmModel(nam),isInitialised(false)
{
  
  verboseLevel= 0;
  // Verbosity scale:
  // 0 = nothing
  // 1 = warning for energy non-conservation
  // 2 = details of energy budget
  // 3 = calculation of cross sections, file openings, sampling of atoms
  // 4 = entering in methods
  
  if( verboseLevel>0 )
  {
    G4cout << "MicroElec inelastic model is constructed " << G4endl;
  }
  
  //Mark this model as "applicable" for atomic deexcitation
  SetDeexcitationFlag(true);
  fAtomDeexcitation = nullptr;
  fParticleChangeForGamma = nullptr;
  
  // default generator
  SetAngularDistribution(new G4DeltaAngle());
 
  // Selection of computation method
  fasterCode = true;
  SEFromFermiLevel = false;
}

References fasterCode, fAtomDeexcitation, fParticleChangeForGamma, G4cout, G4endl, SEFromFermiLevel, G4VEmModel::SetAngularDistribution(), G4VEmModel::SetDeexcitationFlag(), and verboseLevel.

◆ ~G4MicroElecInelasticModel_new()

G4MicroElecInelasticModel_new::~G4MicroElecInelasticModel_new ( )

override

Definition at line 130 of file G4MicroElecInelasticModel_new.cc.

{
  // Cross section  
  // (0)
  TCSMap::iterator pos2;
  for (pos2 = tableTCS.begin(); pos2 != tableTCS.end(); ++pos2) {
    MapData* tableData = pos2->second;
    for (auto pos = tableData->begin(); pos != tableData->end(); ++pos)
      {
    G4MicroElecCrossSectionDataSet_new* table = pos->second;
    delete table;
      }
    delete tableData;
  }
  tableTCS.clear();
    
  dataDiffCSMap::iterator iterator_proba;  
  // (1)
  for (iterator_proba = eNrjTransStorage.begin(); iterator_proba != eNrjTransStorage.end(); ++iterator_proba) {
    vector<TriDimensionMap>* eNrjTransfData = iterator_proba->second;
    eNrjTransfData->clear();
    delete eNrjTransfData;
  }
  eNrjTransStorage.clear();
  
  for (iterator_proba = pNrjTransStorage.begin(); iterator_proba != pNrjTransStorage.end(); ++iterator_proba) {
    vector<TriDimensionMap>* pNrjTransfData = iterator_proba->second;
    pNrjTransfData->clear();
    delete pNrjTransfData;
  }
  pNrjTransStorage.clear();
  
  // (2)
  for (iterator_proba = eDiffDatatable.begin(); iterator_proba != eDiffDatatable.end(); ++iterator_proba) {
    vector<TriDimensionMap>* eDiffCrossSectionData = iterator_proba->second;
    eDiffCrossSectionData->clear();
    delete eDiffCrossSectionData;
  }
  eDiffDatatable.clear();
 
  for (iterator_proba = pDiffDatatable.begin(); iterator_proba != pDiffDatatable.end(); ++iterator_proba) {
    vector<TriDimensionMap>* pDiffCrossSectionData = iterator_proba->second;
    pDiffCrossSectionData->clear();
    delete pDiffCrossSectionData;
  }
  pDiffDatatable.clear();
  
  // (3)
  dataProbaShellMap::iterator iterator_probaShell;
  
  for (iterator_probaShell = eProbaShellStorage.begin(); iterator_probaShell != eProbaShellStorage.end(); ++iterator_probaShell) {
    vector<VecMap>* eProbaShellMap = iterator_probaShell->second;
    eProbaShellMap->clear();
    delete eProbaShellMap;
  }
  eProbaShellStorage.clear();
  
  for (iterator_probaShell = pProbaShellStorage.begin(); iterator_probaShell != pProbaShellStorage.end(); ++iterator_probaShell) {
    vector<VecMap>* pProbaShellMap = iterator_probaShell->second;
    pProbaShellMap->clear();
    delete pProbaShellMap;
  }
  pProbaShellStorage.clear();
  
  // (4)
  TranfEnergyMap::iterator iterator_nrjtransf;
  for (iterator_nrjtransf = eVecmStorage.begin(); iterator_nrjtransf != eVecmStorage.end(); ++iterator_nrjtransf) {
    VecMap* eVecm = iterator_nrjtransf->second;
    eVecm->clear();
    delete eVecm;
  }
  eVecmStorage.clear();
  for (iterator_nrjtransf = pVecmStorage.begin(); iterator_nrjtransf != pVecmStorage.end(); ++iterator_nrjtransf) {
    VecMap* pVecm = iterator_nrjtransf->second;
    pVecm->clear();
    delete pVecm;
  }
  pVecmStorage.clear();
  
  // (5)
  incidentEnergyMap::iterator iterator_energy;
  for (iterator_energy = eIncidentEnergyStorage.begin(); iterator_energy != eIncidentEnergyStorage.end(); ++iterator_energy) {
    std::vector<G4double>* eTdummyVec = iterator_energy->second;
    eTdummyVec->clear();
    delete eTdummyVec;
  }
  eIncidentEnergyStorage.clear();
  
  for (iterator_energy = pIncidentEnergyStorage.begin(); iterator_energy != pIncidentEnergyStorage.end(); ++iterator_energy) {
    std::vector<G4double>* pTdummyVec = iterator_energy->second;
    pTdummyVec->clear();
    delete pTdummyVec;
  }
  pIncidentEnergyStorage.clear();
  
  // (6)
  MapStructure::iterator iterator_matStructure;
  for (iterator_matStructure = tableMaterialsStructures.begin(); 
       iterator_matStructure != tableMaterialsStructures.end(); ++iterator_matStructure) {
    currentMaterialStructure = iterator_matStructure->second;
    delete currentMaterialStructure;
  }
  tableMaterialsStructures.clear();
  currentMaterialStructure = nullptr;
}

References currentMaterialStructure, eDiffDatatable, eIncidentEnergyStorage, eNrjTransStorage, eProbaShellStorage, eVecmStorage, pDiffDatatable, pIncidentEnergyStorage, pNrjTransStorage, pos, pProbaShellStorage, pVecmStorage, tableMaterialsStructures, and tableTCS.

◆ G4MicroElecInelasticModel_new() [2/2]

G4MicroElecInelasticModel_new::G4MicroElecInelasticModel_new ( const G4MicroElecInelasticModel_new & )

delete

Member Function Documentation

◆ BKZ()

G4double G4MicroElecInelasticModel_new::BKZ	(	G4double	Ep,
		G4double	mp,
		G4int	Zp,
		G4double	EF
	)

Definition at line 1417 of file G4MicroElecInelasticModel_new.cc.

{
  // need atomic unit conversion
  G4double hbar = hbar_Planck, hbar2 = hbar*hbar, me = electron_mass_c2/c_squared, Ry = me*elm_coupling*elm_coupling/(2*hbar2);
  G4double hartree = 2*Ry,  a0 = Bohr_radius,   velocity = a0*hartree/hbar;
  G4double vp = ComputeRelativistVelocity(Ep,  mp);
 
  vp /= velocity;
 
  G4double wp = Eplasmon/hartree;
  G4double a = std::pow(4./9./CLHEP::pi, 1./3.);
  G4double vF = std::pow(wp*wp/(3.*a*a*a), 1./3.);
  G4double c = 0.9;
  G4double vr = vrkreussler(vp /*in u.a*/, vF /*in u.a*/);
  G4double yr = vr/std::pow(Zp, 2./3.);
  G4double q = 0.;
  if(Zp==2) q = 1-exp(-c*vr/(Zp-5./16.));
  else q = 1.-exp(-c*(yr-0.07));
  G4double Neq = Zp*(1.-q);
  G4double l0 = 0.;
  if(Neq<=2) l0 = 3./(Zp-0.3*(Neq-1))/2.;
  else l0 = 0.48*std::pow(Neq, 2./3.)/(Zp-Neq/7.);
  if(Zp==2)  c = 1.0;
  else c = 3./2.;
  return Zp*(q + c*(1.-q)/vF/vF/2.0 * log(1.+std::pow(2.*l0*vF,2.)));   
}

References a0, source.hepunit::Bohr_radius, source.hepunit::c_squared, ComputeRelativistVelocity(), source.hepunit::electron_mass_c2, source.hepunit::elm_coupling, source.hepunit::hbar_Planck, CLHEP::pi, vrkreussler(), and G4InuclParticleNames::wp.

Referenced by CrossSectionPerVolume(), and RandomSelect().

◆ ChargeSquareRatio()

G4double G4VEmModel::ChargeSquareRatio ( const G4Track & track )

virtualinherited

Reimplemented in G4BraggIonGasModel, and G4BetheBlochIonGasModel.

Definition at line 374 of file G4VEmModel.cc.

{
  return GetChargeSquareRatio(track.GetParticleDefinition(), 
                              track.GetMaterial(), track.GetKineticEnergy());
}

References G4VEmModel::GetChargeSquareRatio(), G4Track::GetKineticEnergy(), G4Track::GetMaterial(), and G4Track::GetParticleDefinition().

Referenced by G4VEnergyLossProcess::PostStepGetPhysicalInteractionLength().

◆ ComputeCrossSectionPerAtom() [1/2]

G4double G4VEmModel::ComputeCrossSectionPerAtom	(	const G4ParticleDefinition *	part,
		const G4Element *	elm,
		G4double	kinEnergy,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

inlineinherited

Definition at line 566 of file G4VEmModel.hh.

{
  SetCurrentElement(elm);
  return ComputeCrossSectionPerAtom(part,kinEnergy,elm->GetZ(),elm->GetN(),
                                    cutEnergy,maxEnergy);
}

References G4VEmModel::ComputeCrossSectionPerAtom(), G4Element::GetN(), G4Element::GetZ(), and G4VEmModel::SetCurrentElement().

◆ ComputeCrossSectionPerAtom() [2/2]

G4double G4VEmModel::ComputeCrossSectionPerAtom	(	const G4ParticleDefinition *	,
		G4double	kinEnergy,
		G4double	Z,
		G4double	A = `0.`,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

virtualinherited

Reimplemented in G4eDPWACoulombScatteringModel, G4eBremsstrahlungRelModel, G4LivermorePhotoElectricModel, G4eSingleCoulombScatteringModel, G4IonCoulombScatteringModel, G4PolarizedComptonModel, G4eCoulombScatteringModel, G4hCoulombScatteringModel, G4KleinNishinaCompton, G4KleinNishinaModel, G4PEEffectFluoModel, G4JAEAElasticScatteringModel, G4JAEAPolarizedElasticScatteringModel, G4LivermoreComptonModel, G4LivermoreIonisationModel, G4LivermoreNuclearGammaConversionModel, G4LivermorePolarizedComptonModel, G4LivermorePolarizedGammaConversionModel, G4LivermorePolarizedRayleighModel, G4LivermoreRayleighModel, G4LowEPComptonModel, G4LowEPPolarizedComptonModel, G4PenelopeAnnihilationModel, G4PenelopeGammaConversionModel, G4PenelopePhotoElectricModel, G4PenelopeRayleighModel, G4PenelopeRayleighModelMI, G4XrayRayleighModel, G4BoldyshevTripletModel, G4BetheHeitlerModel, G4PairProductionRelModel, G4eplusTo2GammaOKVIModel, G4eplusTo3GammaOKVIModel, G4eeToTwoGammaModel, G4EmMultiModel, G4LivermoreGammaConversion5DModel, G4LivermoreGammaConversionModel, G4WentzelVIModel, G4WentzelVIRelModel, G4mplIonisationWithDeltaModel, G4MuBetheBlochModel, G4MuBremsstrahlungModel, G4MuPairProductionModel, G4AtimaEnergyLossModel, G4BetheBlochModel, G4BraggIonModel, G4BraggModel, G4ICRU73QOModel, G4LindhardSorensenIonModel, G4MollerBhabhaModel, G4eeToHadronsModel, G4eeToHadronsMultiModel, G4eBremParametrizedModel, G4IonParametrisedLossModel, G4PenelopeComptonModel, G4PenelopeIonisationModel, G4UrbanAdjointMscModel, G4UrbanMscModel, and G4PenelopeBremsstrahlungModel.

Definition at line 341 of file G4VEmModel.cc.

{
  return 0.0;
}

Referenced by G4AdjointPhotoElectricModel::AdjointCrossSectionPerAtom(), G4VEmModel::ComputeCrossSectionPerAtom(), G4EmCalculator::ComputeCrossSectionPerAtom(), G4VEmProcess::ComputeCrossSectionPerAtom(), G4EmCalculator::ComputeCrossSectionPerShell(), G4AdjointIonIonisationModel::CorrectPostStepWeight(), G4VEmModel::CrossSectionPerVolume(), G4AdjointComptonModel::DiffCrossSectionPerAtomPrimToScatPrim(), G4VEmAdjointModel::DiffCrossSectionPerAtomPrimToSecond(), G4AdjointhIonisationModel::DiffCrossSectionPerAtomPrimToSecond(), G4AdjointIonIonisationModel::DiffCrossSectionPerAtomPrimToSecond(), and G4EmElementSelector::Initialise().

◆ ComputeCrossSectionPerShell()

G4double G4VEmModel::ComputeCrossSectionPerShell	(	const G4ParticleDefinition *	,
		G4int	Z,
		G4int	shellIdx,
		G4double	kinEnergy,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

virtualinherited

Definition at line 351 of file G4VEmModel.cc.

{
  return 0.0;
}

Referenced by G4EmCalculator::ComputeCrossSectionPerShell().

◆ ComputeDEDX()

G4double G4VEmModel::ComputeDEDX	(	const G4MaterialCutsCouple *	couple,
		const G4ParticleDefinition *	part,
		G4double	kineticEnergy,
		G4double	cutEnergy = `DBL_MAX`
	)

inlineinherited

Definition at line 528 of file G4VEmModel.hh.

{
  SetCurrentCouple(couple);
  return pFactor*ComputeDEDXPerVolume(pBaseMaterial,part,kinEnergy,cutEnergy);
}

References G4VEmModel::ComputeDEDXPerVolume(), G4VEmModel::pBaseMaterial, G4VEmModel::pFactor, and G4VEmModel::SetCurrentCouple().

◆ ComputeDEDXPerVolume()

G4double G4VEmModel::ComputeDEDXPerVolume	(	const G4Material *	,
		const G4ParticleDefinition *	,
		G4double	kineticEnergy,
		G4double	cutEnergy = `DBL_MAX`
	)

virtualinherited

Reimplemented in G4eBremsstrahlungRelModel, G4PAIModel, G4PAIPhotModel, G4EmMultiModel, G4BetheBlochNoDeltaModel, G4BraggNoDeltaModel, G4ICRU73NoDeltaModel, G4mplIonisationModel, G4mplIonisationWithDeltaModel, G4LivermoreIonisationModel, G4PenelopeBremsstrahlungModel, G4PenelopeIonisationModel, G4MuBetheBlochModel, G4MuBremsstrahlungModel, G4MuPairProductionModel, G4BetheBlochModel, G4BraggIonModel, G4BraggModel, G4eBremParametrizedModel, G4LindhardSorensenIonModel, G4MollerBhabhaModel, G4ICRU49NuclearStoppingModel, G4AtimaEnergyLossModel, G4ICRU73QOModel, and G4IonParametrisedLossModel.

Definition at line 228 of file G4VEmModel.cc.

{
  return 0.0;
}

Referenced by G4NuclearStopping::AlongStepDoIt(), G4EmCorrections::BuildCorrectionVector(), G4VEmModel::ComputeDEDX(), G4EmCalculator::ComputeDEDX(), G4NIELCalculator::ComputeNIEL(), and G4EmCalculator::ComputeNuclearDEDX().

◆ ComputeElasticQmax()

G4double G4MicroElecInelasticModel_new::ComputeElasticQmax	(	G4double	T1i,
		G4double	T2i,
		G4double	m1,
		G4double	m2
	)

Definition at line 1384 of file G4MicroElecInelasticModel_new.cc.

                                                                                                               {
  G4double v1i = ComputeRelativistVelocity(T1i, M1);
  G4double v2i = ComputeRelativistVelocity(T2i, M2);
  
  G4double v2f = 2*M1/(M1+M2)*v1i + (M2-M1)/(M1+M2)*-1*v2i;
  G4double vtransfer2a = v2f*v2f-v2i*v2i;
 
  v2f = 2*M1/(M1+M2)*v1i + (M2-M1)/(M1+M2)*v2i;
  G4double vtransfer2b = v2f*v2f-v2i*v2i;
 
  G4double vtransfer2 = std::max(vtransfer2a, vtransfer2b);
  return 0.5*M2*vtransfer2;
}

References ComputeRelativistVelocity(), and G4INCL::Math::max().

Referenced by RandomizeEjectedElectronEnergy().

◆ ComputeMeanFreePath()

G4double G4VEmModel::ComputeMeanFreePath	(	const G4ParticleDefinition *	part,
		G4double	kineticEnergy,
		const G4Material *	material,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

inlineinherited

Definition at line 553 of file G4VEmModel.hh.

{
  G4double cross = CrossSectionPerVolume(material,part,ekin,emin,emax);
  return (cross > 0.0) ? 1./cross : DBL_MAX;
}

References G4VEmModel::CrossSectionPerVolume(), DBL_MAX, emax, and eplot::material.

◆ ComputeRelativistVelocity()

G4double G4MicroElecInelasticModel_new::ComputeRelativistVelocity	(	G4double	E,
		G4double	mass
	)

Definition at line 1377 of file G4MicroElecInelasticModel_new.cc.

                                                                                           {
  G4double x = E/mass;
  return c_light*std::sqrt(x*(x + 2.0))/(x + 1.0);
}

References source.hepunit::c_light.

Referenced by BKZ(), and ComputeElasticQmax().

◆ CorrectionsAlongStep()

void G4VEmModel::CorrectionsAlongStep	(	const G4MaterialCutsCouple *	,
		const G4DynamicParticle *	,
		const G4double &	length,
		G4double &	eloss
	)

virtualinherited

Reimplemented in G4IonParametrisedLossModel, G4AtimaEnergyLossModel, G4BraggIonModel, G4ICRU73QOModel, G4BetheBlochModel, and G4LindhardSorensenIonModel.

Definition at line 399 of file G4VEmModel.cc.

402{}

Referenced by G4ContinuousGainOfEnergy::AlongStepDoIt(), G4VEnergyLossProcess::AlongStepDoIt(), G4EmCalculator::ComputeDEDX(), and G4EmCalculator::GetDEDX().

◆ CrossSection()

G4double G4VEmModel::CrossSection	(	const G4MaterialCutsCouple *	couple,
		const G4ParticleDefinition *	part,
		G4double	kineticEnergy,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

inlineinherited

Definition at line 539 of file G4VEmModel.hh.

{
  SetCurrentCouple(couple);
  return pFactor*CrossSectionPerVolume(pBaseMaterial,part,kinEnergy,
                                       cutEnergy,maxEnergy);
}

References G4VEmModel::CrossSectionPerVolume(), G4VEmModel::pBaseMaterial, G4VEmModel::pFactor, and G4VEmModel::SetCurrentCouple().

Referenced by G4PolarizedAnnihilation::ComputeAsymmetry(), G4PolarizedIonisation::ComputeAsymmetry(), G4PolarizedCompton::ComputeAsymmetry(), G4EmModelManager::FillLambdaVector(), and G4EmMultiModel::SampleSecondaries().

◆ CrossSectionPerVolume()

G4double G4MicroElecInelasticModel_new::CrossSectionPerVolume	(	const G4Material *	material,
		const G4ParticleDefinition *	p,
		G4double	ekin,
		G4double	emin,
		G4double	emax
	)

overridevirtual

Reimplemented from G4VEmModel.

Definition at line 520 of file G4MicroElecInelasticModel_new.cc.

{
  if (verboseLevel > 3) G4cout << "Calling CrossSectionPerVolume() of G4MicroElecInelasticModel" << G4endl;
  
  G4double density = material->GetTotNbOfAtomsPerVolume();
  currentMaterial = material->GetName().substr(3, material->GetName().size());
  
  MapStructure::iterator structPos;
  structPos = tableMaterialsStructures.find(currentMaterial);
  
  // Calculate total cross section for model
  TCSMap::iterator tablepos;
  tablepos = tableTCS.find(currentMaterial);
  
  if (tablepos == tableTCS.end() )
    {
      G4String str = "Material ";
      str += currentMaterial + " TCS Table not found!";
      G4Exception("G4MicroElecInelasticModel_new::ComputeCrossSectionPerVolume", "em0002", FatalException, str);
      return 0;
    }
  else if(structPos == tableMaterialsStructures.end())
    {
      G4String str = "Material ";
      str += currentMaterial + " Structure not found!";
      G4Exception("G4MicroElecInelasticModel_new::ComputeCrossSectionPerVolume", "em0002", FatalException, str);
      return 0;
    }
  else {
    MapData* tableData = tablepos->second;
    currentMaterialStructure = structPos->second;
    
    G4double sigma = 0;
   
    const G4String& particleName = particleDefinition->GetParticleName();
    G4String nameLocal = particleName;
    G4int pdg = particleDefinition->GetPDGEncoding();
    G4int Z = particleDefinition->GetAtomicNumber();
    
    G4double Zeff = 1.0, Zeff2 = Zeff*Zeff;
    G4double Mion_c2 = particleDefinition->GetPDGMass();
    
    if (Mion_c2 > proton_mass_c2)
      {
    ekin *= proton_mass_c2 / Mion_c2;
        nameLocal = "proton";
      }
 
    G4double lowLim = currentMaterialStructure->GetInelasticModelLowLimit(pdg);
    G4double highLim = currentMaterialStructure->GetInelasticModelHighLimit(pdg);
    
    if (ekin >= lowLim && ekin < highLim)
      {
    std::map< G4String, G4MicroElecCrossSectionDataSet_new*, std::less<G4String> >::iterator pos;
    pos = tableData->find(nameLocal); //find particle type
    
    if (pos != tableData->end())
      {
        G4MicroElecCrossSectionDataSet_new* table = pos->second;
        if (table != 0)
          {
        sigma = table->FindValue(ekin);
                
        if (Mion_c2 > proton_mass_c2) {
          sigma = 0.;
          for (G4int i = 0; i < currentMaterialStructure->NumberOfLevels(); i++) {
            Zeff = BKZ(ekin / (proton_mass_c2 / Mion_c2), Mion_c2 / c_squared, Z, currentMaterialStructure->Energy(i)); // il faut garder le vrai ekin car le calcul à l'interieur de la methode convertie l'énergie en vitesse
            Zeff2 = Zeff*Zeff;
            sigma += Zeff2*table->FindShellValue(ekin, i); 
// il faut utiliser le ekin mis à l'echelle pour chercher la bonne 
// valeur dans les tables proton
        
          }
        }
        else {
          sigma = table->FindValue(ekin);
        }
          }
      }
    else
      {
        G4Exception("G4MicroElecInelasticModel_new::CrossSectionPerVolume", 
                        "em0002", FatalException, 
                        "Model not applicable to particle type.");
      }
      }
    else
      {
    return 1 / DBL_MAX;
      }
    
    if (verboseLevel > 3)
      {
    G4cout << "---> Kinetic energy (eV)=" << ekin / eV << G4endl;
    G4cout << " - Cross section per Si atom (cm^2)=" << sigma / cm2 << G4endl;
    G4cout << " - Cross section per Si atom (cm^-1)=" << sigma*density / (1. / cm) << G4endl;
      }
        
    return (sigma)*density;} 
 
}

References BKZ(), source.hepunit::c_squared, cm, cm2, currentMaterial, currentMaterialStructure, DBL_MAX, G4MicroElecMaterialStructure::Energy(), eV, FatalException, G4MicroElecCrossSectionDataSet_new::FindShellValue(), G4MicroElecCrossSectionDataSet_new::FindValue(), G4cout, G4endl, G4Exception(), G4ParticleDefinition::GetAtomicNumber(), G4MicroElecMaterialStructure::GetInelasticModelHighLimit(), G4MicroElecMaterialStructure::GetInelasticModelLowLimit(), G4ParticleDefinition::GetParticleName(), G4ParticleDefinition::GetPDGEncoding(), G4ParticleDefinition::GetPDGMass(), eplot::material, G4MicroElecMaterialStructure::NumberOfLevels(), pos, source.hepunit::proton_mass_c2, tableMaterialsStructures, tableTCS, verboseLevel, and Z.

◆ CurrentCouple()

const G4MaterialCutsCouple * G4VEmModel::CurrentCouple ( ) const

inlineprotectedinherited

Definition at line 490 of file G4VEmModel.hh.

{
  return fCurrentCouple;
}

References G4VEmModel::fCurrentCouple.

◆ DeexcitationFlag()

G4bool G4VEmModel::DeexcitationFlag ( ) const

inlineinherited

Definition at line 704 of file G4VEmModel.hh.

{
  return flagDeexcitation;
}

References G4VEmModel::flagDeexcitation.

Referenced by G4EmModelManager::DumpModelList().

◆ DefineForRegion()

void G4VEmModel::DefineForRegion ( const G4Region * )

virtualinherited

Reimplemented in G4PAIModel, and G4PAIPhotModel.

Definition at line 360 of file G4VEmModel.cc.

361{}

Referenced by G4EmModelManager::AddEmModel().

◆ DifferentialCrossSection()

G4double G4MicroElecInelasticModel_new::DifferentialCrossSection	(	const G4ParticleDefinition *	aParticleDefinition,
		G4double	k,
		G4double	energyTransfer,
		G4int	shell
	)

Definition at line 1118 of file G4MicroElecInelasticModel_new.cc.

{
  G4double sigma = 0.;
  
  if (energyTransfer >= currentMaterialStructure->GetLimitEnergy(LevelIndex))
    {
      G4double valueT1 = 0;
      G4double valueT2 = 0;
      G4double valueE21 = 0;
      G4double valueE22 = 0;
      G4double valueE12 = 0;
      G4double valueE11 = 0;
      
      G4double xs11 = 0;
      G4double xs12 = 0;
      G4double xs21 = 0;
      G4double xs22 = 0;
      
      if (particleDefinition == G4Electron::ElectronDefinition())
    {
      
      dataDiffCSMap::iterator iterator_Proba;
      iterator_Proba = eDiffDatatable.find(currentMaterial);
      
      incidentEnergyMap::iterator iterator_Nrj;
      iterator_Nrj = eIncidentEnergyStorage.find(currentMaterial);
      
      TranfEnergyMap::iterator iterator_TransfNrj;
      iterator_TransfNrj = eVecmStorage.find(currentMaterial);
      
      if (iterator_Proba != eDiffDatatable.end() && iterator_Nrj != eIncidentEnergyStorage.end() 
          && iterator_TransfNrj!= eVecmStorage.end())
        {   
          vector<TriDimensionMap>* eDiffCrossSectionData = (iterator_Proba->second);
          vector<G4double>* eTdummyVec = iterator_Nrj->second; //Incident energies for interpolation
          VecMap* eVecm = iterator_TransfNrj->second;
          
          // k should be in eV and energy transfer eV also
          auto t2 = std::upper_bound(eTdummyVec->begin(), eTdummyVec->end(), k);
          auto t1 = t2 - 1;
          // SI : the following condition avoids situations where energyTransfer >last vector element
          if (energyTransfer <= (*eVecm)[(*t1)].back() && energyTransfer <= (*eVecm)[(*t2)].back())
        {
          auto e12 = std::upper_bound((*eVecm)[(*t1)].begin(), (*eVecm)[(*t1)].end(), energyTransfer);
          auto e11 = e12 - 1;         
          auto e22 = std::upper_bound((*eVecm)[(*t2)].begin(), (*eVecm)[(*t2)].end(), energyTransfer);
          auto e21 = e22 - 1;
          
          valueT1 = *t1;
          valueT2 = *t2;
          valueE21 = *e21;
          valueE22 = *e22;
          valueE12 = *e12;
          valueE11 = *e11;
 
          xs11 = (*eDiffCrossSectionData)[LevelIndex][valueT1][valueE11];
          xs12 = (*eDiffCrossSectionData)[LevelIndex][valueT1][valueE12];
          xs21 = (*eDiffCrossSectionData)[LevelIndex][valueT2][valueE21];
          xs22 = (*eDiffCrossSectionData)[LevelIndex][valueT2][valueE22];
        }
        }
      else {
        G4String str = "Material ";
        str += currentMaterial + " not found!";
        G4Exception("G4MicroElecDielectricModels::DifferentialCrossSection", "em0002", FatalException, str);
      }
    }
      
      if (particleDefinition == G4Proton::ProtonDefinition())
    {     
      dataDiffCSMap::iterator iterator_Proba;
      iterator_Proba = pDiffDatatable.find(currentMaterial);
      
      incidentEnergyMap::iterator iterator_Nrj;
      iterator_Nrj = pIncidentEnergyStorage.find(currentMaterial);
      
      TranfEnergyMap::iterator iterator_TransfNrj;
      iterator_TransfNrj = pVecmStorage.find(currentMaterial);
      
      if (iterator_Proba != pDiffDatatable.end() && iterator_Nrj != pIncidentEnergyStorage.end() 
          && iterator_TransfNrj != pVecmStorage.end())
        {
          vector<TriDimensionMap>* pDiffCrossSectionData = (iterator_Proba->second);
          vector<G4double>* pTdummyVec = iterator_Nrj->second; //Incident energies for interpolation
          VecMap* pVecm = iterator_TransfNrj->second;
                  
          // k should be in eV and energy transfer eV also
          auto t2 = 
        std::upper_bound(pTdummyVec->begin(), pTdummyVec->end(), k);
          auto t1 = t2 - 1;
          if (energyTransfer <= (*pVecm)[(*t1)].back() && energyTransfer <= (*pVecm)[(*t2)].back())
        {
          auto e12 = std::upper_bound((*pVecm)[(*t1)].begin(), (*pVecm)[(*t1)].end(), energyTransfer);
          auto e11 = e12 - 1;         
          auto e22 = std::upper_bound((*pVecm)[(*t2)].begin(), (*pVecm)[(*t2)].end(), energyTransfer);
          auto e21 = e22 - 1;
          
          valueT1 = *t1;
          valueT2 = *t2;
          valueE21 = *e21;
          valueE22 = *e22;
          valueE12 = *e12;
          valueE11 = *e11;
          
          xs11 = (*pDiffCrossSectionData)[LevelIndex][valueT1][valueE11];
          xs12 = (*pDiffCrossSectionData)[LevelIndex][valueT1][valueE12];
          xs21 = (*pDiffCrossSectionData)[LevelIndex][valueT2][valueE21];
          xs22 = (*pDiffCrossSectionData)[LevelIndex][valueT2][valueE22];
        }
        }
      else {
        G4String str = "Material ";
        str += currentMaterial + " not found!";
        G4Exception("G4MicroElecDielectricModels::DifferentialCrossSection", "em0002", FatalException, str);
      }
    }
      
      G4double xsProduct = xs11 * xs12 * xs21 * xs22;
      if (xsProduct != 0.)
    {
      sigma = QuadInterpolator(     valueE11, valueE12,
                    valueE21, valueE22,
                    xs11, xs12,
                    xs21, xs22,
                    valueT1, valueT2,
                    k, energyTransfer);
    }
      
    }
  
  return sigma;
}

References currentMaterial, currentMaterialStructure, eDiffDatatable, eIncidentEnergyStorage, G4Electron::ElectronDefinition(), eVecmStorage, FatalException, G4Exception(), G4MicroElecMaterialStructure::GetLimitEnergy(), pDiffDatatable, pIncidentEnergyStorage, G4Proton::ProtonDefinition(), pVecmStorage, and QuadInterpolator().

Referenced by RandomizeEjectedElectronEnergy().

◆ FillNumberOfSecondaries()

void G4VEmModel::FillNumberOfSecondaries	(	G4int &	numberOfTriplets,
		G4int &	numberOfRecoil
	)

virtualinherited

Definition at line 365 of file G4VEmModel.cc.

{
  numberOfTriplets = 0;
  numberOfRecoil = 0;
}

Referenced by G4VEmProcess::PostStepDoIt(), and G4VEnergyLossProcess::PostStepDoIt().

◆ ForceBuildTableFlag()

G4bool G4VEmModel::ForceBuildTableFlag ( ) const

inlineinherited

Definition at line 711 of file G4VEmModel.hh.

{
  return flagForceBuildTable;
}

References G4VEmModel::flagForceBuildTable.

Referenced by G4VMscModel::GetParticleChangeForMSC().

◆ GetAngularDistribution()

G4VEmAngularDistribution * G4VEmModel::GetAngularDistribution ( )

inlineinherited

Definition at line 621 of file G4VEmModel.hh.

{
  return anglModel;
}

References G4VEmModel::anglModel.

◆ GetChargeSquareRatio()

G4double G4VEmModel::GetChargeSquareRatio	(	const G4ParticleDefinition *	p,
		const G4Material *	,
		G4double	kineticEnergy
	)

virtualinherited

Reimplemented in G4BraggIonModel, G4BraggModel, G4IonParametrisedLossModel, G4AtimaEnergyLossModel, G4BetheBlochModel, and G4LindhardSorensenIonModel.

Definition at line 382 of file G4VEmModel.cc.

{
  const G4double q = p->GetPDGCharge()*inveplus;
  return q*q;
}

References G4ParticleDefinition::GetPDGCharge(), and G4VEmModel::inveplus.

Referenced by G4ContinuousGainOfEnergy::AlongStepDoIt(), G4AdjointCSManager::BuildTotalSigmaTables(), G4VEmModel::ChargeSquareRatio(), G4EmCalculator::ComputeDEDX(), G4AdjointIonIonisationModel::CorrectPostStepWeight(), G4ContinuousGainOfEnergy::GetContinuousStepLimit(), and G4EmCalculator::GetDEDX().

◆ GetCrossSectionTable()

G4PhysicsTable * G4VEmModel::GetCrossSectionTable ( )

inlineinherited

Definition at line 870 of file G4VEmModel.hh.

{
  return xSectionTable;
}

References G4VEmModel::xSectionTable.

Referenced by G4VMultipleScattering::BuildPhysicsTable(), G4EmModelManager::DumpModelList(), G4EmCalculator::FindLambdaTable(), G4WentzelVIModel::Initialise(), and G4VMultipleScattering::StorePhysicsTable().

◆ GetCurrentElement()

const G4Element * G4VEmModel::GetCurrentElement ( ) const

inlineinherited

Definition at line 505 of file G4VEmModel.hh.

{
  return fCurrentElement;
}

References G4VEmModel::fCurrentElement.

Referenced by G4VEmProcess::GetCurrentElement(), G4VEnergyLossProcess::GetCurrentElement(), G4VEmProcess::GetTargetElement(), G4PolarizedBremsstrahlungModel::SampleSecondaries(), G4PolarizedGammaConversionModel::SampleSecondaries(), G4PolarizedPhotoElectricModel::SampleSecondaries(), G4PolarizedBremsstrahlungModel::SelectedAtom(), G4PolarizedGammaConversionModel::SelectedAtom(), and G4eBremParametrizedModel::SetCurrentElement().

◆ GetCurrentIsotope()

const G4Isotope * G4VEmModel::GetCurrentIsotope ( ) const

inlineinherited

Definition at line 512 of file G4VEmModel.hh.

{
  return fCurrentIsotope;
}

References G4VEmModel::fCurrentIsotope.

Referenced by G4VEmProcess::GetTargetIsotope().

◆ GetElementData()

G4ElementData * G4VEmModel::GetElementData ( )

inlineinherited

Definition at line 863 of file G4VEmModel.hh.

{
  return fElementData;
}

References G4VEmModel::fElementData.

Referenced by G4MuPairProductionModel::InitialiseLocal(), G4ePairProduction::StreamProcessInfo(), and G4MuPairProduction::StreamProcessInfo().

◆ GetElementSelectors()

std::vector< G4EmElementSelector * > * G4VEmModel::GetElementSelectors ( )

inlineinherited

Definition at line 844 of file G4VEmModel.hh.

{
  return elmSelectors;
}

References G4VEmModel::elmSelectors.

◆ GetModelOfFluctuations()

G4VEmFluctuationModel * G4VEmModel::GetModelOfFluctuations ( )

inlineinherited

Definition at line 614 of file G4VEmModel.hh.

{
  return flucModel;
}

References G4VEmModel::flucModel.

Referenced by G4ContinuousGainOfEnergy::AlongStepDoIt(), G4VEnergyLossProcess::AlongStepDoIt(), G4IonParametrisedLossModel::CorrectionsAlongStep(), G4AtimaEnergyLossModel::CorrectionsAlongStep(), G4BraggIonModel::CorrectionsAlongStep(), G4BetheBlochModel::CorrectionsAlongStep(), G4LindhardSorensenIonModel::CorrectionsAlongStep(), G4BraggModel::GetChargeSquareRatio(), G4VEnergyLossProcess::GetDEDXDispersion(), and G4EmMultiModel::Initialise().

◆ GetName()

const G4String & G4VEmModel::GetName ( ) const

inlineinherited

Definition at line 837 of file G4VEmModel.hh.

{
  return name;
}

References G4VEmModel::name.

Referenced by G4NIELCalculator::AddEmModel(), G4VLEPTSModel::BuildMeanFreePathTable(), G4VLEPTSModel::BuildPhysicsTable(), G4EmCalculator::ComputeDEDX(), G4MuPairProductionModel::DataCorrupted(), G4EmElementSelector::Dump(), G4EmModelManager::DumpModelList(), G4EmCalculator::FindEmModel(), G4NIELCalculator::G4NIELCalculator(), G4EmMultiModel::Initialise(), G4IonParametrisedLossModel::Initialise(), G4EmModelManager::Initialise(), G4IonParametrisedLossModel::PrintDEDXTable(), G4DNAAttachment::PrintInfo(), G4DNAChargeDecrease::PrintInfo(), G4DNAChargeIncrease::PrintInfo(), G4DNADissociation::PrintInfo(), G4DNAElastic::PrintInfo(), G4DNAExcitation::PrintInfo(), G4DNAIonisation::PrintInfo(), G4DNAPlasmonExcitation::PrintInfo(), G4DNAPositronium::PrintInfo(), G4DNARotExcitation::PrintInfo(), G4DNAVibExcitation::PrintInfo(), G4VLEPTSModel::ReadIXS(), G4LossTableManager::Register(), G4DNAModelInterface::RegisterModel(), G4IonParametrisedLossModel::RemoveDEDXTable(), G4VLEPTSModel::SampleEnergyLoss(), G4EmConfigurator::SetExtraEmModel(), G4EmConfigurator::SetModelForRegion(), and G4EmConfigurator::UpdateModelEnergyRange().

◆ GetPartialCrossSection()

G4double G4VEmModel::GetPartialCrossSection	(	const G4Material *	,
		G4int	level,
		const G4ParticleDefinition *	,
		G4double	kineticEnergy
	)

virtualinherited

Reimplemented in G4DNABornExcitationModel1, G4DNABornExcitationModel2, G4DNABornIonisationModel1, G4DNABornIonisationModel2, G4DNAMillerGreenExcitationModel, and G4DNARelativisticIonisationModel.

Definition at line 261 of file G4VEmModel.cc.

{ 
  return 0.0;
}

◆ GetParticleChangeForGamma()

G4ParticleChangeForGamma * G4VEmModel::GetParticleChangeForGamma ( )

protectedinherited

Definition at line 123 of file G4VEmModel.cc.

{
  G4ParticleChangeForGamma* p = nullptr;
  if (pParticleChange != nullptr) {
    p = static_cast<G4ParticleChangeForGamma*>(pParticleChange);
  } else {
    p = new G4ParticleChangeForGamma();
    pParticleChange = p;
  }
  if(fTripletModel != nullptr) { fTripletModel->SetParticleChange(p); }
  return p;
}

References G4VEmModel::fTripletModel, G4VEmModel::pParticleChange, and G4VEmModel::SetParticleChange().

◆ GetParticleChangeForLoss()

G4ParticleChangeForLoss * G4VEmModel::GetParticleChangeForLoss ( )

protectedinherited

Definition at line 108 of file G4VEmModel.cc.

{
  G4ParticleChangeForLoss* p = nullptr;
  if (pParticleChange != nullptr) {
    p = static_cast<G4ParticleChangeForLoss*>(pParticleChange);
  } else {
    p = new G4ParticleChangeForLoss();
    pParticleChange = p;
  }
  if(fTripletModel != nullptr) { fTripletModel->SetParticleChange(p); }
  return p;
}

References G4VEmModel::fTripletModel, G4VEmModel::pParticleChange, and G4VEmModel::SetParticleChange().

◆ GetParticleCharge()

G4double G4VEmModel::GetParticleCharge	(	const G4ParticleDefinition *	p,
		const G4Material *	,
		G4double	kineticEnergy
	)

virtualinherited

Reimplemented in G4IonParametrisedLossModel, G4BraggIonGasModel, G4BetheBlochIonGasModel, G4AtimaEnergyLossModel, G4BetheBlochModel, G4BraggIonModel, G4BraggModel, and G4LindhardSorensenIonModel.

Definition at line 391 of file G4VEmModel.cc.

{
  return p->GetPDGCharge();
}

References G4ParticleDefinition::GetPDGCharge().

Referenced by G4VEnergyLossProcess::AlongStepDoIt().

◆ GetTripletModel()

G4VEmModel * G4VEmModel::GetTripletModel ( )

inlineinherited

Definition at line 638 of file G4VEmModel.hh.

{
  return fTripletModel;
}

References G4VEmModel::fTripletModel.

Referenced by G4eBremsstrahlungRelModel::Initialise(), G4SeltzerBergerModel::Initialise(), and G4eBremsstrahlungRelModel::SampleSecondaries().

◆ HighEnergyActivationLimit()

G4double G4VEmModel::HighEnergyActivationLimit ( ) const

inlineinherited

Definition at line 669 of file G4VEmModel.hh.

{
  return eMaxActive;
}

References G4VEmModel::eMaxActive.

Referenced by G4EmModelManager::DumpModelList(), G4VMscModel::GetParticleChangeForMSC(), G4WentzelVIModel::Initialise(), and G4EmModelManager::Initialise().

◆ HighEnergyLimit()

G4double G4VEmModel::HighEnergyLimit ( ) const

inlineinherited

Definition at line 655 of file G4VEmModel.hh.

{
  return highLimit;
}

References G4VEmModel::highLimit.

◆ Initialise()

void G4MicroElecInelasticModel_new::Initialise	(	const G4ParticleDefinition *	particle,
		const G4DataVector &
	)

overridevirtual

Implements G4VEmModel.

Definition at line 238 of file G4MicroElecInelasticModel_new.cc.

{
  if (isInitialised) { return; }
 
  if (verboseLevel > 3)
    G4cout << "Calling G4MicroElecInelasticModel_new::Initialise()" << G4endl;
  
  char* path = std::getenv("G4LEDATA");
  if (!path)
    {
      G4Exception("G4MicroElecElasticModel_new::Initialise","em0006",FatalException,"G4LEDATA environment variable not set.");
      return;
    }
  
  G4String modelName = "mermin";
  G4cout << "****************************" << G4endl;
  G4cout << modelName << " model loaded !" << G4endl;
  
  // Energy limits 
  G4ParticleDefinition* electronDef = G4Electron::ElectronDefinition();
  G4ParticleDefinition* protonDef = G4Proton::ProtonDefinition();
  G4String electron = electronDef->GetParticleName();
  G4String proton = protonDef->GetParticleName();
  
  G4double scaleFactor = 1.0;
  
    // *** ELECTRON 
  lowEnergyLimit[electron] = 2 * eV;
  highEnergyLimit[electron] = 10.0 * MeV;
  
  // Cross section
  G4ProductionCutsTable* theCoupleTable = G4ProductionCutsTable::GetProductionCutsTable();
  G4int numOfCouples = theCoupleTable->GetTableSize();
  
  for (G4int i = 0; i < numOfCouples; ++i) {
    const G4Material* material = theCoupleTable->GetMaterialCutsCouple(i)->GetMaterial();
    G4cout << "Material " << i + 1 << " / " << numOfCouples << " : " << material->GetName() << G4endl;
    if (material->GetName() == "Vacuum") continue;
    G4String mat = material->GetName().substr(3, material->GetName().size());   
    MapData* tableData = new MapData;
    currentMaterialStructure = new G4MicroElecMaterialStructure(mat);
    
    tableMaterialsStructures[mat] = currentMaterialStructure;
    if (particle == electronDef) {
      //TCS
      G4String fileElectron("Inelastic/" + modelName + "_sigma_inelastic_e-_" + mat);
      G4cout << fileElectron << G4endl;
      G4MicroElecCrossSectionDataSet_new* tableE = new G4MicroElecCrossSectionDataSet_new(new G4LogLogInterpolation, MeV, scaleFactor);
      tableE->LoadData(fileElectron);
      tableData->insert(make_pair(electron, tableE));
      
      // DCS
      std::ostringstream eFullFileName;
      if (fasterCode) {
    eFullFileName << path << "/microelec/Inelastic/cumulated_" + modelName + "_sigmadiff_inelastic_e-_" + mat + ".dat";
    G4cout << "Faster code = true" << G4endl;
    G4cout << "Inelastic/cumulated_" + modelName + "_sigmadiff_inelastic_e-_" + mat + ".dat" << G4endl;
      }
      else {
    eFullFileName << path << "/microelec/Inelastic/" + modelName + "_sigmadiff_inelastic_e-_" + mat + ".dat";
    G4cout << "Faster code = false" << G4endl;
    G4cout << "Inelastic/" + modelName + "_sigmadiff_inelastic_e-_" + mat + ".dat" << G4endl;
      }
      
      std::ifstream eDiffCrossSection(eFullFileName.str().c_str());
      if (!eDiffCrossSection)
    {
      std::stringstream ss;
      ss << "Missing data " << eFullFileName.str().c_str();
      std::string sortieString = ss.str();
          
      if (fasterCode) G4Exception("G4MicroElecInelasticModel_new::Initialise", "em0003",
                      FatalException, sortieString.c_str());
                                          
      else {
        G4Exception("G4MicroElecInelasticModel_new::Initialise", "em0003",
            FatalException, "Missing data file:/microelec/sigmadiff_inelastic_e_Si.dat");
      }   
    }
      
      // Clear the arrays for re-initialization case (MT mode)
      // Octobre 22nd, 2014 - Melanie Raine      
      //Creating vectors of maps for DCS and Cumulated DCS for the current material.
      //Each vector is storing one map for each shell.      
      vector<TriDimensionMap>* eDiffCrossSectionData = 
    new vector<TriDimensionMap>; //Storage of [IncidentEnergy, TransfEnergy, DCS values], used in slower code
      vector<TriDimensionMap>* eNrjTransfData = 
    new vector<TriDimensionMap>; //Storage of possible transfer energies by shell
      vector<VecMap>* eProbaShellMap = new vector<VecMap>; //Storage of the vectors containing all cumulated DCS values for an initial energy, by shell
      vector<G4double>* eTdummyVec = new vector<G4double>; //Storage of incident energies for interpolation
      VecMap* eVecm = new VecMap; //Transfered energy map for slower code
      
      for (int j = 0; j < currentMaterialStructure->NumberOfLevels(); j++) //Filling the map vectors with an empty map for each shell
    {
      eDiffCrossSectionData->push_back(TriDimensionMap());
      eNrjTransfData->push_back(TriDimensionMap());
      eProbaShellMap->push_back(VecMap());
    }
      
      eTdummyVec->push_back(0.);
      while (!eDiffCrossSection.eof())
    {
      G4double tDummy; //incident energy
      G4double eDummy; //transfered energy
      eDiffCrossSection >> tDummy >> eDummy;
      if (tDummy != eTdummyVec->back()) eTdummyVec->push_back(tDummy);
      
      G4double tmp; //probability
      for (int j = 0; j < currentMaterialStructure->NumberOfLevels(); j++)
        {
          eDiffCrossSection >> tmp;       
          (*eDiffCrossSectionData)[j][tDummy][eDummy] = tmp;
          
          if (fasterCode)
        {
          (*eNrjTransfData)[j][tDummy][(*eDiffCrossSectionData)[j][tDummy][eDummy]] = eDummy;
          (*eProbaShellMap)[j][tDummy].push_back((*eDiffCrossSectionData)[j][tDummy][eDummy]);
        }
          else {  // SI - only if eof is not reached !
        if (!eDiffCrossSection.eof()) (*eDiffCrossSectionData)[j][tDummy][eDummy] *= scaleFactor;
        (*eVecm)[tDummy].push_back(eDummy);
          }
        }
    }
      //
      G4cout << "add to material vector" << G4endl;
      
      //Filing maps for the current material into the master maps
      if (fasterCode) {
    eNrjTransStorage[mat] = eNrjTransfData;
    eProbaShellStorage[mat] = eProbaShellMap;
      }
      else {
    eDiffDatatable[mat] = eDiffCrossSectionData;
    eVecmStorage[mat] = eVecm;
      }
      eIncidentEnergyStorage[mat] = eTdummyVec;
 
      //Cleanup support vectors
      // delete eProbaShellMap;
      // delete eDiffCrossSectionData;
      // delete eNrjTransfData;
    }
    
    // *** PROTON
    if (particle == protonDef)
      {
    // Cross section
    G4String fileProton("Inelastic/" + modelName + "_sigma_inelastic_p_" + mat); G4cout << fileProton << G4endl;
    G4MicroElecCrossSectionDataSet_new* tableP = new G4MicroElecCrossSectionDataSet_new(new G4LogLogInterpolation, MeV, scaleFactor);
    tableP->LoadData(fileProton);
    tableData->insert(make_pair(proton, tableP));
 
    // DCS
    std::ostringstream pFullFileName;   
    if (fasterCode) {
      pFullFileName << path << "/microelec/Inelastic/cumulated_" + modelName + "_sigmadiff_inelastic_p_" + mat + ".dat";
      G4cout << "Faster code = true" << G4endl;
      G4cout << "Inelastic/cumulated_" + modelName + "_sigmadiff_inelastic_p_" + mat + ".dat" << G4endl;
    }
    else {
      pFullFileName << path << "/microelec/Inelastic/" + modelName + "_sigmadiff_inelastic_p_" + mat + ".dat";
      G4cout << "Faster code = false" << G4endl;
      G4cout << "Inelastic/" + modelName + "_sigmadiff_inelastic_e-_" + mat + ".dat" << G4endl;
    }
    
    std::ifstream pDiffCrossSection(pFullFileName.str().c_str());
    if (!pDiffCrossSection)
      {
        if (fasterCode) G4Exception("G4MicroElecInelasticModel_new::Initialise", "em0003",
                    FatalException, "Missing data file:/microelec/sigmadiff_cumulated_inelastic_p_Si.dat");
        else {        
          G4Exception("G4MicroElecInelasticModel_new::Initialise", "em0003",
              FatalException, "Missing data file:/microelec/sigmadiff_inelastic_p_Si.dat");
        }
      }
    
    //
    // Clear the arrays for re-initialization case (MT mode)
    // Octobre 22nd, 2014 - Melanie Raine
    //Creating vectors of maps for DCS and Cumulated DCS for the current material.
    //Each vector is storing one map for each shell.
    
    vector<TriDimensionMap>* pDiffCrossSectionData = 
      new vector<TriDimensionMap>; //Storage of [IncidentEnergy, TransfEnergy, DCS values], used in slower code
    vector<TriDimensionMap>* pNrjTransfData = 
      new vector<TriDimensionMap>; //Storage of possible transfer energies by shell
    vector<VecMap>* pProbaShellMap = 
      new vector<VecMap>; //Storage of the vectors containing all cumulated DCS values for an initial energy, by shell
    vector<G4double>* pTdummyVec = 
      new vector<G4double>; //Storage of incident energies for interpolation
    VecMap* eVecm = new VecMap; //Transfered energy map for slower code
 
    for (int j = 0; j < currentMaterialStructure->NumberOfLevels(); ++j) 
      //Filling the map vectors with an empty map for each shell
      {
        pDiffCrossSectionData->push_back(TriDimensionMap());
        pNrjTransfData->push_back(TriDimensionMap());
        pProbaShellMap->push_back(VecMap());
      }
    
    pTdummyVec->push_back(0.);
    while (!pDiffCrossSection.eof())
      {
        G4double tDummy; //incident energy
        G4double eDummy; //transfered energy
        pDiffCrossSection >> tDummy >> eDummy;
        if (tDummy != pTdummyVec->back()) pTdummyVec->push_back(tDummy);
        
        G4double tmp; //probability
        for (int j = 0; j < currentMaterialStructure->NumberOfLevels(); j++)
          {
        pDiffCrossSection >> tmp;   
        (*pDiffCrossSectionData)[j][tDummy][eDummy] = tmp; 
        // ArrayofMaps[j] -> fill with 3DMap(incidentEnergy, 
        // 2Dmap (transferedEnergy,proba=tmp) ) -> fill map for shell j 
        // with proba for transfered energy eDummy
        
        if (fasterCode)
          {
            (*pNrjTransfData)[j][tDummy][(*pDiffCrossSectionData)[j][tDummy][eDummy]] = eDummy;
            (*pProbaShellMap)[j][tDummy].push_back((*pDiffCrossSectionData)[j][tDummy][eDummy]);
          }
        else {  // SI - only if eof is not reached !
          if (!pDiffCrossSection.eof()) (*pDiffCrossSectionData)[j][tDummy][eDummy] *= scaleFactor;
          (*eVecm)[tDummy].push_back(eDummy);
        }
          }
      }
    
    //Filing maps for the current material into the master maps
    if (fasterCode) {
      pNrjTransStorage[mat] = pNrjTransfData;
      pProbaShellStorage[mat] = pProbaShellMap;
    }
    else {
      pDiffDatatable[mat] = pDiffCrossSectionData;
      pVecmStorage[mat] = eVecm;
    }
    pIncidentEnergyStorage[mat] = pTdummyVec;
         
    //Cleanup support vectors
    // delete pNrjTransfData;
    // delete eVecm;
    // delete pDiffCrossSectionData;
    // delete pProbaShellMap;
      }
    tableTCS[mat] = tableData;
} 
  if (particle==electronDef)
    {
      SetLowEnergyLimit(lowEnergyLimit[electron]);
      SetHighEnergyLimit(highEnergyLimit[electron]);
    }
  
  if (particle==protonDef)
    {
      SetLowEnergyLimit(100*eV);
      SetHighEnergyLimit(10*MeV);
    }
  
  if( verboseLevel>1 )
    {
      G4cout << "MicroElec Inelastic model is initialized " << G4endl
         << "Energy range: "
         << LowEnergyLimit() / keV << " keV - "
         << HighEnergyLimit() / MeV << " MeV for "
         << particle->GetParticleName()
         << " with mass (amu) " << particle->GetPDGMass()/proton_mass_c2
         << " and charge " << particle->GetPDGCharge()
         << G4endl << G4endl ;
    }
  
  fAtomDeexcitation  = G4LossTableManager::Instance()->AtomDeexcitation();
  
  fParticleChangeForGamma = GetParticleChangeForGamma();
  isInitialised = true;
}

References G4LossTableManager::AtomDeexcitation(), currentMaterialStructure, eDiffDatatable, eIncidentEnergyStorage, G4InuclParticleNames::electron, G4Electron::ElectronDefinition(), eNrjTransStorage, eProbaShellStorage, eV, eVecmStorage, fasterCode, FatalException, fAtomDeexcitation, fParticleChangeForGamma, G4cout, G4endl, G4Exception(), G4MaterialCutsCouple::GetMaterial(), G4ProductionCutsTable::GetMaterialCutsCouple(), G4VEmModel::GetParticleChangeForGamma(), G4ParticleDefinition::GetParticleName(), G4ParticleDefinition::GetPDGCharge(), G4ParticleDefinition::GetPDGMass(), G4ProductionCutsTable::GetProductionCutsTable(), G4ProductionCutsTable::GetTableSize(), highEnergyLimit, G4VEmModel::HighEnergyLimit(), G4LossTableManager::Instance(), isInitialised, keV, G4MicroElecCrossSectionDataSet_new::LoadData(), lowEnergyLimit, G4VEmModel::LowEnergyLimit(), eplot::material, MeV, G4MicroElecMaterialStructure::NumberOfLevels(), pDiffDatatable, pIncidentEnergyStorage, pNrjTransStorage, pProbaShellStorage, G4InuclParticleNames::proton, source.hepunit::proton_mass_c2, G4Proton::ProtonDefinition(), pVecmStorage, G4VEmModel::SetHighEnergyLimit(), G4VEmModel::SetLowEnergyLimit(), tableMaterialsStructures, tableTCS, and verboseLevel.

◆ InitialiseElementSelectors()

void G4VEmModel::InitialiseElementSelectors	(	const G4ParticleDefinition *	part,
		const G4DataVector &	cuts
	)

inherited

Definition at line 138 of file G4VEmModel.cc.

{
  // using spline for element selectors should be investigated in details
  // because small number of points may provide biased results
  // large number of points requires significant increase of memory
  G4bool spline = false;
  
  //G4cout << "IES: for " << GetName() << " Emin(MeV)= " << lowLimit/MeV 
  //         << " Emax(MeV)= " << highLimit/MeV << G4endl;
  
  // two times less bins because probability functon is normalized 
  // so correspondingly is more smooth
  if(highLimit <= lowLimit) { return; }
 
  G4int nbinsPerDec = G4EmParameters::Instance()->NumberOfBinsPerDecade();
 
  G4ProductionCutsTable* theCoupleTable=
    G4ProductionCutsTable::GetProductionCutsTable();
  G4int numOfCouples = theCoupleTable->GetTableSize();
 
  // prepare vector
  if(!elmSelectors) {
    elmSelectors = new std::vector<G4EmElementSelector*>;
  }
  if(numOfCouples > nSelectors) { 
    for(G4int i=nSelectors; i<numOfCouples; ++i) { 
      elmSelectors->push_back(nullptr); 
    }
    nSelectors = numOfCouples;
  }
 
  // initialise vector
  for(G4int i=0; i<numOfCouples; ++i) {
 
    // no need in element selectors for infinite cuts
    if(cuts[i] == DBL_MAX) { continue; }
   
    auto couple = theCoupleTable->GetMaterialCutsCouple(i); 
    auto material = couple->GetMaterial();
    SetCurrentCouple(couple);
 
    // selector already exist then delete
    delete (*elmSelectors)[i];
 
    G4double emin = std::max(lowLimit, MinPrimaryEnergy(material, part, cuts[i]));
    G4double emax = std::max(highLimit, 10*emin);
    static const G4double invlog106 = 1.0/(6*G4Log(10.));
    G4int nbins = (G4int)(nbinsPerDec*G4Log(emax/emin)*invlog106);
    nbins = std::max(nbins, 3);
 
    (*elmSelectors)[i] = new G4EmElementSelector(this,material,nbins,
                         emin,emax,spline);
    ((*elmSelectors)[i])->Initialise(part, cuts[i]);
    /*      
      G4cout << "G4VEmModel::InitialiseElmSelectors i= " << i 
             << "  "  << part->GetParticleName() 
             << " for " << GetName() << "  cut= " << cuts[i] 
             << "  " << (*elmSelectors)[i] << G4endl;      
      ((*elmSelectors)[i])->Dump(part);
    */
  } 
}

References DBL_MAX, G4VEmModel::elmSelectors, emax, G4Log(), G4ProductionCutsTable::GetMaterialCutsCouple(), G4ProductionCutsTable::GetProductionCutsTable(), G4ProductionCutsTable::GetTableSize(), G4VEmModel::highLimit, G4VEmModel::Initialise(), G4EmParameters::Instance(), G4VEmModel::lowLimit, eplot::material, G4INCL::Math::max(), G4VEmModel::MinPrimaryEnergy(), G4VEmModel::nSelectors, G4EmParameters::NumberOfBinsPerDecade(), and G4VEmModel::SetCurrentCouple().

◆ InitialiseForElement()

void G4VEmModel::InitialiseForElement	(	const G4ParticleDefinition *	,
		G4int	Z
	)

virtualinherited

◆ InitialiseForMaterial()

void G4VEmModel::InitialiseForMaterial	(	const G4ParticleDefinition *	part,
		const G4Material *	material
	)

virtualinherited

Definition at line 209 of file G4VEmModel.cc.

{
  if(material != nullptr) {
    size_t n = material->GetNumberOfElements();
    for(size_t i=0; i<n; ++i) {
      G4int Z = material->GetElement(i)->GetZasInt();
      InitialiseForElement(part, Z);
    }
  }
}

References G4VEmModel::InitialiseForElement(), eplot::material, CLHEP::detail::n, and Z.

Referenced by G4EmCalculator::FindEmModel().

◆ InitialiseLocal()

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

virtualinherited

Reimplemented in G4PenelopeAnnihilationModel, G4PenelopeBremsstrahlungModel, G4PenelopeGammaConversionModel, G4PenelopeIonisationModel, G4eDPWACoulombScatteringModel, G4eSingleCoulombScatteringModel, G4PAIModel, G4PAIPhotModel, G4JAEAElasticScatteringModel, G4JAEAPolarizedElasticScatteringModel, G4LivermoreComptonModel, G4LivermoreNuclearGammaConversionModel, G4LivermorePolarizedComptonModel, G4LivermorePolarizedGammaConversionModel, G4LivermorePolarizedRayleighModel, G4LivermoreRayleighModel, G4LowEPComptonModel, G4LowEPPolarizedComptonModel, G4PenelopeComptonModel, G4PenelopePhotoElectricModel, G4PenelopeRayleighModel, G4PenelopeRayleighModelMI, G4MuBremsstrahlungModel, G4MuPairProductionModel, G4BetheHeitlerModel, G4eBremParametrizedModel, G4eBremsstrahlungRelModel, G4eCoulombScatteringModel, G4hCoulombScatteringModel, G4KleinNishinaCompton, G4KleinNishinaModel, G4PairProductionRelModel, G4WentzelVIModel, and G4GoudsmitSaundersonMscModel.

Definition at line 204 of file G4VEmModel.cc.

205{}

Referenced by G4VEmProcess::BuildPhysicsTable(), G4VEnergyLossProcess::BuildPhysicsTable(), and G4VMultipleScattering::BuildPhysicsTable().

◆ Interpolate()

G4double G4MicroElecInelasticModel_new::Interpolate	(	G4double	e1,
		G4double	e2,
		G4double	e,
		G4double	xs1,
		G4double	xs2
	)

private

Definition at line 1258 of file G4MicroElecInelasticModel_new.cc.

{
  G4double value = 0.;
 
  // Log-log interpolation by default
  if (e1 != 0 && e2 != 0 && (e2-e1) != 0 && !fasterCode)
    {
      G4double a = std::log(xs2/xs1)/ std::log(e2/e1);
      G4double b = std::log(xs2) - a * std::log(e2);
      G4double sigma = a * std::log(e) + b;
      value = (std::exp(sigma));
    }
 
  // Switch to log-lin interpolation for faster code
  if ((e2 - e1) != 0 && xs1 != 0 && xs2 != 0 && fasterCode)
    {
      G4double d1 = std::log(xs1);
      G4double d2 = std::log(xs2);
      value = std::exp((d1 + (d2 - d1) * (e - e1) / (e2 - e1)));
    }
 
  // Switch to lin-lin interpolation for faster code
  // in case one of xs1 or xs2 (=cum proba) value is zero
  if ((e2 - e1) != 0 && (xs1 == 0 || xs2 == 0) && fasterCode)
    {
      G4double d1 = xs1;
      G4double d2 = xs2;
      value = (d1 + (d2 - d1) * (e - e1) / (e2 - e1));
    }
 
  return value;
}

References d1, d2, e1, e2, and fasterCode.

Referenced by QuadInterpolator(), and TransferedEnergy().

◆ IsActive()

G4bool G4VEmModel::IsActive ( G4double kinEnergy ) const

inlineinherited

Definition at line 795 of file G4VEmModel.hh.

{
  return (kinEnergy >= eMinActive && kinEnergy <= eMaxActive);
}

References G4VEmModel::eMaxActive, and G4VEmModel::eMinActive.

Referenced by G4VEnergyLossProcess::AlongStepDoIt(), G4NuclearStopping::AlongStepDoIt(), G4VMultipleScattering::AlongStepGetPhysicalInteractionLength(), G4VEnergyLossProcess::AlongStepGetPhysicalInteractionLength(), G4VEmProcess::PostStepDoIt(), G4VEnergyLossProcess::PostStepDoIt(), G4VEmProcess::PostStepGetPhysicalInteractionLength(), and G4VEnergyLossProcess::PostStepGetPhysicalInteractionLength().

◆ IsLocked()

G4bool G4VEmModel::IsLocked ( ) const

inlineinherited

Definition at line 877 of file G4VEmModel.hh.

{
  return isLocked;
}

References G4VEmModel::isLocked.

Referenced by G4VMscModel::InitialiseParameters(), G4VMscModel::SetGeomFactor(), G4VMscModel::SetLambdaLimit(), G4VMscModel::SetLateralDisplasmentFlag(), G4VMscModel::SetRangeFactor(), G4VMscModel::SetSafetyFactor(), G4VMscModel::SetSampleZ(), G4VMscModel::SetSkin(), and G4VMscModel::SetStepLimitType().

◆ IsMaster()

G4bool G4VEmModel::IsMaster ( ) const

inlineinherited

Definition at line 746 of file G4VEmModel.hh.

{
  return isMaster;
}

References G4VEmModel::isMaster.

◆ LowEnergyActivationLimit()

G4double G4VEmModel::LowEnergyActivationLimit ( ) const

inlineinherited

Definition at line 676 of file G4VEmModel.hh.

{
  return eMinActive;
}

References G4VEmModel::eMinActive.

Referenced by G4EmModelManager::DumpModelList(), G4VMscModel::GetParticleChangeForMSC(), G4WentzelVIModel::Initialise(), and G4EmModelManager::Initialise().

◆ LowEnergyLimit()

G4double G4VEmModel::LowEnergyLimit ( ) const

inlineinherited

Definition at line 662 of file G4VEmModel.hh.

{
  return lowLimit;
}

References G4VEmModel::lowLimit.

◆ LPMFlag()

G4bool G4VEmModel::LPMFlag ( ) const

inlineinherited

Definition at line 697 of file G4VEmModel.hh.

{
  return theLPMflag;
}

References G4VEmModel::theLPMflag.

Referenced by G4eBremsstrahlungRelModel::Initialise(), G4eBremsstrahlungRelModel::SetupForMaterial(), G4SeltzerBergerModel::SetupForMaterial(), and G4eBremsstrahlungRelModel::~G4eBremsstrahlungRelModel().

◆ MaxSecondaryEnergy()

G4double G4VEmModel::MaxSecondaryEnergy	(	const G4ParticleDefinition *	,
		G4double	kineticEnergy
	)

protectedvirtualinherited

Reimplemented in G4BraggIonModel, G4BraggModel, G4ICRU73QOModel, G4MollerBhabhaModel, G4PAIModel, G4PAIPhotModel, G4mplIonisationWithDeltaModel, G4MuBetheBlochModel, G4AtimaEnergyLossModel, G4BetheBlochModel, G4LindhardSorensenIonModel, and G4IonParametrisedLossModel.

Definition at line 432 of file G4VEmModel.cc.

{
  return kineticEnergy;
}

Referenced by G4VEmModel::MaxSecondaryKinEnergy().

◆ MaxSecondaryKinEnergy()

G4double G4VEmModel::MaxSecondaryKinEnergy ( const G4DynamicParticle * dynParticle )

inlineinherited

Definition at line 520 of file G4VEmModel.hh.

{
  return MaxSecondaryEnergy(dynPart->GetParticleDefinition(),
                            dynPart->GetKineticEnergy());
}

References G4DynamicParticle::GetKineticEnergy(), G4DynamicParticle::GetParticleDefinition(), and G4VEmModel::MaxSecondaryEnergy().

Referenced by G4ContinuousGainOfEnergy::AlongStepDoIt(), G4VEnergyLossProcess::AlongStepDoIt(), G4VEnergyLossProcess::GetDEDXDispersion(), G4MuBetheBlochModel::SampleSecondaries(), G4PolarizedIonisationModel::SampleSecondaries(), G4BraggIonModel::SampleSecondaries(), G4BraggModel::SampleSecondaries(), G4ICRU73QOModel::SampleSecondaries(), and G4IonParametrisedLossModel::SampleSecondaries().

◆ MinEnergyCut()

G4double G4VEmModel::MinEnergyCut	(	const G4ParticleDefinition *	,
		const G4MaterialCutsCouple *
	)

virtualinherited

Reimplemented in G4IonParametrisedLossModel, G4PenelopeBremsstrahlungModel, G4PenelopeIonisationModel, G4MuBetheBlochModel, G4MuBremsstrahlungModel, G4eBremParametrizedModel, G4PAIModel, G4PAIPhotModel, G4mplIonisationWithDeltaModel, G4AtimaEnergyLossModel, G4BetheBlochModel, G4BraggIonModel, G4BraggModel, and G4LindhardSorensenIonModel.

Definition at line 424 of file G4VEmModel.cc.

{
  return 0.0;
}

Referenced by G4EmModelManager::Initialise().

◆ MinPrimaryEnergy()

G4double G4VEmModel::MinPrimaryEnergy	(	const G4Material *	,
		const G4ParticleDefinition *	,
		G4double	cut = `0.0`
	)

virtualinherited

Reimplemented in G4eBremsstrahlungRelModel, G4BoldyshevTripletModel, G4eCoulombScatteringModel, G4hCoulombScatteringModel, G4LivermoreNuclearGammaConversionModel, G4LivermorePolarizedGammaConversionModel, G4MuBremsstrahlungModel, G4MuPairProductionModel, and G4eDPWACoulombScatteringModel.

Definition at line 415 of file G4VEmModel.cc.

{
  return 0.0;
}

Referenced by G4LossTableBuilder::BuildTableForModel(), and G4VEmModel::InitialiseElementSelectors().

◆ ModelDescription()

void G4VEmModel::ModelDescription ( std::ostream & outFile ) const

virtualinherited

Reimplemented in G4eeToHadronsMultiModel.

Definition at line 469 of file G4VEmModel.cc.

{
  outFile << "The description for this model has not been written yet.\n";
}

◆ operator=()

G4MicroElecInelasticModel_new & G4MicroElecInelasticModel_new::operator= ( const G4MicroElecInelasticModel_new & right )

delete

◆ PolarAngleLimit()

G4double G4VEmModel::PolarAngleLimit ( ) const

inlineinherited

Definition at line 683 of file G4VEmModel.hh.

{
  return polarAngleLimit;
}

References G4VEmModel::polarAngleLimit.

Referenced by G4eCoulombScatteringModel::Initialise(), G4eDPWACoulombScatteringModel::Initialise(), G4hCoulombScatteringModel::Initialise(), and G4WentzelVIModel::Initialise().

◆ QuadInterpolator()

G4double G4MicroElecInelasticModel_new::QuadInterpolator	(	G4double	e11,
		G4double	e12,
		G4double	e21,
		G4double	e22,
		G4double	x11,
		G4double	x12,
		G4double	x21,
		G4double	x22,
		G4double	t1,
		G4double	t2,
		G4double	t,
		G4double	e
	)

private

Definition at line 1297 of file G4MicroElecInelasticModel_new.cc.

{
  G4double interpolatedvalue1 = Interpolate(e11, e12, e, xs11, xs12);
  G4double interpolatedvalue2 = Interpolate(e21, e22, e, xs21, xs22);
  G4double value = Interpolate(t1, t2, t, interpolatedvalue1, interpolatedvalue2);
  return value;
}

References Interpolate().

Referenced by DifferentialCrossSection(), and TransferedEnergy().

◆ RandomizeCreatedElectronEnergy()

G4double G4MicroElecInelasticModel_new::RandomizeCreatedElectronEnergy ( G4double secondaryKinetic )

private

◆ RandomizeEjectedElectronEnergy()

G4double G4MicroElecInelasticModel_new::RandomizeEjectedElectronEnergy	(	const G4ParticleDefinition *	aParticleDefinition,
		G4double	incomingParticleEnergy,
		G4int	shell,
		G4double	originalMass,
		G4int	originalZ
	)

private

Definition at line 762 of file G4MicroElecInelasticModel_new.cc.

{
  G4double secondaryElectronKineticEnergy=0.;
  if (particleDefinition == G4Electron::ElectronDefinition())
    {
      G4double maximumEnergyTransfer=k;      
      G4double crossSectionMaximum = 0.;
      G4double minEnergy = currentMaterialStructure->GetLimitEnergy(shell);
      G4double maxEnergy = maximumEnergyTransfer;
      G4int nEnergySteps = 100;
      
      G4double value(minEnergy);
      G4double stpEnergy(std::pow(maxEnergy/value, 1./static_cast<G4double>(nEnergySteps-1)));
      G4int step(nEnergySteps);
      while (step>0)
    {
      --step;
      G4double differentialCrossSection = 
        DifferentialCrossSection(particleDefinition, k, value, shell);
      crossSectionMaximum = std::max(crossSectionMaximum, differentialCrossSection);
      value*=stpEnergy;
    }
      
      do
    {
      secondaryElectronKineticEnergy = G4UniformRand() * 
        (maximumEnergyTransfer-currentMaterialStructure->GetLimitEnergy(shell));
    } while(G4UniformRand()*crossSectionMaximum > 
        DifferentialCrossSection(particleDefinition, k,
          (secondaryElectronKineticEnergy+currentMaterialStructure->GetLimitEnergy(shell)),shell));
    }
  else if (particleDefinition == G4Proton::ProtonDefinition())
    {      
      G4double maximumEnergyTransfer =
    ComputeElasticQmax(k/(proton_mass_c2/originalMass), 
               currentMaterialStructure->Energy(shell), 
               originalMass/c_squared, electron_mass_c2/c_squared);
      
      G4double crossSectionMaximum = 0.;
      
      G4double minEnergy = currentMaterialStructure->GetLimitEnergy(shell);
      G4double maxEnergy = maximumEnergyTransfer;
      G4int nEnergySteps = 100;
      
      G4double value(minEnergy);
      G4double stpEnergy(std::pow(maxEnergy/value, 1./static_cast<G4double>(nEnergySteps-1)));
      G4int step(nEnergySteps);
      
      while (step>0)
    {
      --step;
      G4double differentialCrossSection = 
        DifferentialCrossSection(particleDefinition, k, value, shell);
      crossSectionMaximum = std::max(crossSectionMaximum, differentialCrossSection);
      value*=stpEnergy;
    }
      
      G4double energyTransfer = 0.;      
      do
    {
      energyTransfer = G4UniformRand() * maximumEnergyTransfer;
    } while(G4UniformRand()*crossSectionMaximum > 
        DifferentialCrossSection(particleDefinition, k,energyTransfer,shell));
      
      secondaryElectronKineticEnergy = 
    energyTransfer-currentMaterialStructure->GetLimitEnergy(shell);
      
    }
  return std::max(secondaryElectronKineticEnergy, 0.0);
}

References source.hepunit::c_squared, ComputeElasticQmax(), currentMaterialStructure, DifferentialCrossSection(), source.hepunit::electron_mass_c2, G4Electron::ElectronDefinition(), G4MicroElecMaterialStructure::Energy(), G4UniformRand, G4MicroElecMaterialStructure::GetLimitEnergy(), G4INCL::Math::max(), source.hepunit::proton_mass_c2, and G4Proton::ProtonDefinition().

Referenced by SampleSecondaries().

◆ RandomizeEjectedElectronEnergyFromCumulatedDcs()

G4double G4MicroElecInelasticModel_new::RandomizeEjectedElectronEnergyFromCumulatedDcs	(	const G4ParticleDefinition *	particleDefinition,
		G4double	k,
		G4int	shell
	)

private

Definition at line 837 of file G4MicroElecInelasticModel_new.cc.

{
  G4double secondaryElectronKineticEnergy = 0.;
  G4double random = G4UniformRand();
 
  secondaryElectronKineticEnergy = TransferedEnergy(particleDefinition, k, shell, random)
    - currentMaterialStructure->GetLimitEnergy(shell) ;
 
  if (isnan(secondaryElectronKineticEnergy)) { secondaryElectronKineticEnergy = k - currentMaterialStructure->GetLimitEnergy(shell); }
 
  if (secondaryElectronKineticEnergy < 0.) {
    secondaryElectronKineticEnergy = k - currentMaterialStructure->GetEnergyGap();
    SEFromFermiLevel = true;
  }
  return secondaryElectronKineticEnergy;
}

References currentMaterialStructure, G4UniformRand, G4MicroElecMaterialStructure::GetEnergyGap(), G4MicroElecMaterialStructure::GetLimitEnergy(), SEFromFermiLevel, and TransferedEnergy().

Referenced by SampleSecondaries().

◆ RandomSelect()

G4int G4MicroElecInelasticModel_new::RandomSelect	(	G4double	energy,
		const G4String &	particle,
		G4double	originalMass,
		G4int	originalZ
	)

private

Definition at line 1312 of file G4MicroElecInelasticModel_new.cc.

{
  G4int level = 0;
  
  TCSMap::iterator tablepos;
  tablepos = tableTCS.find(currentMaterial);
  MapData* tableData = tablepos->second;
  
  std::map< G4String,G4MicroElecCrossSectionDataSet_new*,std::less<G4String> >::iterator pos;
  pos = tableData->find(particle);
  
  std::vector<G4double> Zeff(currentMaterialStructure->NumberOfLevels(), 1.0);
  if(originalMass>proton_mass_c2) {
    for(G4int nl=0;nl<currentMaterialStructure->NumberOfLevels();nl++) {
      Zeff[nl] = BKZ(k/(proton_mass_c2/originalMass), originalMass/c_squared, originalZ, currentMaterialStructure->Energy(nl));
    }
  }
  
  if (pos != tableData->end())
    {
      G4MicroElecCrossSectionDataSet_new* table = pos->second;
      
      if (table != 0)
    {
      G4double* valuesBuffer = new G4double[table->NumberOfComponents()];
      const size_t n(table->NumberOfComponents());
      size_t i(n);
      G4double value = 0.;
      
      while (i>0)
        {
          i--;
          valuesBuffer[i] = table->GetComponent(i)->FindValue(k)*Zeff[i]*Zeff[i];
          value += valuesBuffer[i];
        }     
      value *= G4UniformRand();
      
      i = n;
      
      while (i > 0)
        {
          i--;
          
          if (valuesBuffer[i] > value)
        {
          delete[] valuesBuffer;
          return i;
        }
          value -= valuesBuffer[i];
        }
      
      if (valuesBuffer) delete[] valuesBuffer;
      
    }
    }
  else
    {
      G4Exception("G4MicroElecInelasticModel_new::RandomSelect","em0002",FatalException,"Model not applicable to particle type.");
    }
  
  return level;
}

References BKZ(), source.hepunit::c_squared, currentMaterial, currentMaterialStructure, G4MicroElecMaterialStructure::Energy(), FatalException, G4VEMDataSet::FindValue(), G4Exception(), G4UniformRand, G4MicroElecCrossSectionDataSet_new::GetComponent(), CLHEP::detail::n, G4MicroElecCrossSectionDataSet_new::NumberOfComponents(), G4MicroElecMaterialStructure::NumberOfLevels(), pos, source.hepunit::proton_mass_c2, and tableTCS.

Referenced by SampleSecondaries().

◆ SampleSecondaries()

void G4MicroElecInelasticModel_new::SampleSecondaries	(	std::vector< G4DynamicParticle * > *	fvect,
		const G4MaterialCutsCouple *	couple,
		const G4DynamicParticle *	particle,
		G4double	tmin,
		G4double	maxEnergy
	)

overridevirtual

Implements G4VEmModel.

Definition at line 628 of file G4MicroElecInelasticModel_new.cc.

{
  
  if (verboseLevel > 3)
    G4cout << "Calling SampleSecondaries() of G4MicroElecInelasticModel" << G4endl;
  
  G4int pdg = particle->GetParticleDefinition()->GetPDGEncoding();
  G4double lowLim = currentMaterialStructure->GetInelasticModelLowLimit(pdg);
  G4double highLim = currentMaterialStructure->GetInelasticModelHighLimit(pdg);
  
  G4double ekin = particle->GetKineticEnergy();
  G4double k = ekin ;
  
  G4ParticleDefinition* PartDef = particle->GetDefinition();
  const G4String& particleName = PartDef->GetParticleName();
  G4String nameLocal2 = particleName ;
  G4double particleMass = particle->GetDefinition()->GetPDGMass();
  G4double originalMass = particleMass; // a passer en argument dans samplesecondaryenergy pour évaluer correctement Qmax
  G4int originalZ = particle->GetDefinition()->GetAtomicNumber();
  
  if (particleMass > proton_mass_c2)
    {
      k *= proton_mass_c2/particleMass ;
      PartDef = G4Proton::ProtonDefinition();
      nameLocal2 = "proton" ;
    }
   
  if (k >= lowLim && k < highLim)
    {
      G4ParticleMomentum primaryDirection = particle->GetMomentumDirection();
      G4double totalEnergy = ekin + particleMass;
      G4double pSquare = ekin * (totalEnergy + particleMass);
      G4double totalMomentum = std::sqrt(pSquare);
      
      G4int Shell = 1;
      
      Shell = RandomSelect(k,nameLocal2,originalMass, originalZ);
            
      G4double bindingEnergy = currentMaterialStructure->Energy(Shell);
      G4double limitEnergy = currentMaterialStructure->GetLimitEnergy(Shell);
      
      if (verboseLevel > 3)
    {
      G4cout << "---> Kinetic energy (eV)=" << k/eV << G4endl ;
      G4cout << "Shell: " << Shell << ", energy: " << bindingEnergy/eV << G4endl;
    }
      
      // sample deexcitation
      
      G4int secNumberInit = 0;  // need to know at a certain point the energy of secondaries
      G4int secNumberFinal = 0; // So I'll make the difference and then sum the energies
      
      //SI: additional protection if tcs interpolation method is modified
      //if (k<bindingEnergy) return;
      if (k<limitEnergy) return;
      //    G4cout << currentMaterial << G4endl;
      G4int Z = currentMaterialStructure->GetZ(Shell);     
      G4int shellEnum = currentMaterialStructure->GetEADL_Enumerator(Shell);
      if (currentMaterialStructure->IsShellWeaklyBound(Shell)) { shellEnum = -1; }
      
      if(fAtomDeexcitation && shellEnum >=0) 
    {
      //        G4cout << "enter if deex and shell 0" << G4endl;
      G4AtomicShellEnumerator as = G4AtomicShellEnumerator(shellEnum);
      const G4AtomicShell* shell = fAtomDeexcitation->GetAtomicShell(Z, as);
      secNumberInit = fvect->size();
      fAtomDeexcitation->GenerateParticles(fvect, shell, Z, 0, 0);
      secNumberFinal = fvect->size();
    }
            
      G4double secondaryKinetic=-1000*eV;
      SEFromFermiLevel = false;
      if (!fasterCode)
    {
      secondaryKinetic = RandomizeEjectedElectronEnergy(PartDef, k, Shell, originalMass, originalZ);      
    }
      else 
    {
      secondaryKinetic = RandomizeEjectedElectronEnergyFromCumulatedDcs(PartDef, k, Shell) ;
    }
 
      if (verboseLevel > 3)
    {
      G4cout << "Ionisation process" << G4endl;
      G4cout << "Shell: " << Shell << " Kin. energy (eV)=" << k/eV
         << " Sec. energy (eV)=" << secondaryKinetic/eV << G4endl;
    }
      G4ThreeVector deltaDirection =
    GetAngularDistribution()->SampleDirectionForShell(particle, secondaryKinetic,
                              Z, Shell,
                              couple->GetMaterial());
      
      if (particle->GetDefinition() == G4Electron::ElectronDefinition())
    {
      G4double deltaTotalMomentum = std::sqrt(secondaryKinetic*(secondaryKinetic + 2.*electron_mass_c2 ));    
      
      G4double finalPx = totalMomentum*primaryDirection.x() - deltaTotalMomentum*deltaDirection.x();
      G4double finalPy = totalMomentum*primaryDirection.y() - deltaTotalMomentum*deltaDirection.y();
      G4double finalPz = totalMomentum*primaryDirection.z() - deltaTotalMomentum*deltaDirection.z();
      G4double finalMomentum = std::sqrt(finalPx*finalPx + finalPy*finalPy + finalPz*finalPz);
      finalPx /= finalMomentum;
      finalPy /= finalMomentum;
      finalPz /= finalMomentum;
      
      G4ThreeVector direction;
      direction.set(finalPx,finalPy,finalPz);
      
      fParticleChangeForGamma->ProposeMomentumDirection(direction.unit());
    }
      else fParticleChangeForGamma->ProposeMomentumDirection(primaryDirection);
      
      // note that secondaryKinetic is the energy of the delta ray, not of all secondaries.
      G4double deexSecEnergy = 0;
      for (G4int j=secNumberInit; j < secNumberFinal; ++j) {
    deexSecEnergy = deexSecEnergy + (*fvect)[j]->GetKineticEnergy();
      }      
      if (SEFromFermiLevel) limitEnergy = currentMaterialStructure->GetEnergyGap();
      fParticleChangeForGamma->SetProposedKineticEnergy(ekin - secondaryKinetic - limitEnergy); //Ef = Ei-(Q-El)-El = Ei-Q
      fParticleChangeForGamma->ProposeLocalEnergyDeposit(limitEnergy - deexSecEnergy);
           
      if (secondaryKinetic>0)
    {  
      G4DynamicParticle* dp = new G4DynamicParticle(G4Electron::Electron(), deltaDirection, secondaryKinetic); //Esec = Q-El
      fvect->push_back(dp);
    }      
    }
}

◆ SecondaryThreshold()

G4double G4VEmModel::SecondaryThreshold ( ) const

inlineinherited

Definition at line 690 of file G4VEmModel.hh.

{
  return secondaryThreshold;
}

References G4VEmModel::secondaryThreshold.

Referenced by G4LivermoreBremsstrahlungModel::SampleSecondaries(), G4eBremParametrizedModel::SampleSecondaries(), G4eBremsstrahlungRelModel::SampleSecondaries(), G4SeltzerBergerModel::SampleSecondaries(), G4MuBremsstrahlungModel::SampleSecondaries(), and G4MuPairProductionModel::SampleSecondaries().

◆ SelectIsotopeNumber()

G4int G4VEmModel::SelectIsotopeNumber ( const G4Element * elm )

inherited

Definition at line 319 of file G4VEmModel.cc.

{
  SetCurrentElement(elm);
  const size_t ni = elm->GetNumberOfIsotopes();
  fCurrentIsotope = elm->GetIsotope(0);
  size_t idx = 0;
  if(ni > 1) {
    const G4double* ab = elm->GetRelativeAbundanceVector();
    G4double x = G4UniformRand();
    for(; idx<ni; ++idx) {
      x -= ab[idx];
      if (x <= 0.0) { 
    fCurrentIsotope = elm->GetIsotope(idx);
    break; 
      }
    }
  }
  return fCurrentIsotope->GetN();
}

References ab, G4VEmModel::fCurrentIsotope, G4UniformRand, G4Element::GetIsotope(), G4Isotope::GetN(), G4Element::GetNumberOfIsotopes(), G4Element::GetRelativeAbundanceVector(), and G4VEmModel::SetCurrentElement().

Referenced by G4eSingleCoulombScatteringModel::SampleSecondaries(), G4IonCoulombScatteringModel::SampleSecondaries(), G4eCoulombScatteringModel::SampleSecondaries(), G4hCoulombScatteringModel::SampleSecondaries(), and G4BetheHeitler5DModel::SampleSecondaries().

◆ SelectRandomAtom() [1/2]

const G4Element * G4VEmModel::SelectRandomAtom	(	const G4Material *	mat,
		const G4ParticleDefinition *	pd,
		G4double	kineticEnergy,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

inherited

Definition at line 275 of file G4VEmModel.cc.

{
  size_t n = mat->GetNumberOfElements();
  fCurrentElement = mat->GetElement(0);
  if (n > 1) {
    const G4double x = G4UniformRand()*
      G4VEmModel::CrossSectionPerVolume(mat,pd,kinEnergy,tcut,tmax);
    for(size_t i=0; i<n; ++i) {
      if (x <= xsec[i]) {
        fCurrentElement = mat->GetElement(i);
        break;
      }
    }
  }
  return fCurrentElement;
}

References G4VEmModel::CrossSectionPerVolume(), G4VEmModel::fCurrentElement, G4UniformRand, G4Material::GetElement(), G4Material::GetNumberOfElements(), CLHEP::detail::n, and G4VEmModel::xsec.

◆ SelectRandomAtom() [2/2]

const G4Element * G4VEmModel::SelectRandomAtom	(	const G4MaterialCutsCouple *	couple,
		const G4ParticleDefinition *	part,
		G4double	kineticEnergy,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

inlineinherited

Definition at line 580 of file G4VEmModel.hh.

{
  SetCurrentCouple(couple);
  fCurrentElement = (nSelectors > 0) ?
    ((*elmSelectors)[couple->GetIndex()])->SelectRandomAtom(kinEnergy) :
    SelectRandomAtom(pBaseMaterial,part,kinEnergy,cutEnergy,maxEnergy);
  fCurrentIsotope = nullptr;
  return fCurrentElement;
}

References G4VEmModel::elmSelectors, G4VEmModel::fCurrentElement, G4VEmModel::fCurrentIsotope, G4MaterialCutsCouple::GetIndex(), G4VEmModel::nSelectors, G4VEmModel::pBaseMaterial, G4VEmModel::SelectRandomAtom(), and G4VEmModel::SetCurrentCouple().

◆ SelectRandomAtomNumber()

G4int G4VEmModel::SelectRandomAtomNumber ( const G4Material * mat )

inherited

Definition at line 297 of file G4VEmModel.cc.

{
  // this algorith assumes that cross section is proportional to
  // number electrons multiplied by number of atoms
  const size_t nn = mat->GetNumberOfElements();
  fCurrentElement = mat->GetElement(0);
  if(1 < nn) {
    const G4double* at = mat->GetVecNbOfAtomsPerVolume();
    G4double tot = mat->GetTotNbOfAtomsPerVolume()*G4UniformRand();
    for(size_t i=0; i<nn; ++i) {
      tot -= at[i];
      if(tot <= 0.0) { 
    fCurrentElement = mat->GetElement(i);
    break; 
      }
    }
  }
  return fCurrentElement->GetZasInt();
}

References G4VEmModel::fCurrentElement, G4UniformRand, G4Material::GetElement(), G4Material::GetNumberOfElements(), G4Material::GetTotNbOfAtomsPerVolume(), G4Material::GetVecNbOfAtomsPerVolume(), G4Element::GetZasInt(), and G4InuclParticleNames::nn.

Referenced by G4AtimaEnergyLossModel::SampleSecondaries(), G4BetheBlochModel::SampleSecondaries(), G4BraggIonModel::SampleSecondaries(), G4BraggModel::SampleSecondaries(), G4ICRU73QOModel::SampleSecondaries(), G4LindhardSorensenIonModel::SampleSecondaries(), G4MollerBhabhaModel::SampleSecondaries(), and G4IonParametrisedLossModel::SampleSecondaries().

◆ SelectTargetAtom()

const G4Element * G4VEmModel::SelectTargetAtom	(	const G4MaterialCutsCouple *	couple,
		const G4ParticleDefinition *	part,
		G4double	kineticEnergy,
		G4double	logKineticEnergy,
		G4double	cutEnergy = `0.0`,
		G4double	maxEnergy = `DBL_MAX`
	)

inlineinherited

Definition at line 597 of file G4VEmModel.hh.

{
  SetCurrentCouple(couple);
  fCurrentElement = (nSelectors > 0)
   ? ((*elmSelectors)[couple->GetIndex()])->SelectRandomAtom(kinEnergy,logKinE)
   : SelectRandomAtom(pBaseMaterial,part,kinEnergy,cutEnergy,maxEnergy);
  fCurrentIsotope = nullptr;
  return fCurrentElement;
}

References G4VEmModel::elmSelectors, G4VEmModel::fCurrentElement, G4VEmModel::fCurrentIsotope, G4MaterialCutsCouple::GetIndex(), G4VEmModel::nSelectors, G4VEmModel::pBaseMaterial, G4VEmModel::SelectRandomAtom(), and G4VEmModel::SetCurrentCouple().

◆ SetActivationHighEnergyLimit()

void G4VEmModel::SetActivationHighEnergyLimit ( G4double val )

inlineinherited

Definition at line 781 of file G4VEmModel.hh.

{
  eMaxActive = val;
}

References G4VEmModel::eMaxActive.

Referenced by G4EmModelActivator::ActivateMicroElec(), G4EmDNAPhysics_option7::ConstructProcess(), G4EmDNAPhysics_option8::ConstructProcess(), G4NuclearStopping::InitialiseProcess(), and G4EmConfigurator::SetExtraEmModel().

◆ SetActivationLowEnergyLimit()

void G4VEmModel::SetActivationLowEnergyLimit ( G4double val )

inlineinherited

Definition at line 788 of file G4VEmModel.hh.

{
  eMinActive = val;
}

References G4VEmModel::eMinActive.

◆ SetAngularDistribution()

void G4VEmModel::SetAngularDistribution ( G4VEmAngularDistribution * p )

inlineinherited

Definition at line 628 of file G4VEmModel.hh.

{
  if(p != anglModel) {
    delete anglModel;
    anglModel = p;
  }
}

References G4VEmModel::anglModel.

Referenced by G4EmLivermorePhysics::ConstructProcess(), G4EmLowEPPhysics::ConstructProcess(), G4EmStandardPhysics::ConstructProcess(), G4EmStandardPhysics_option3::ConstructProcess(), G4EmStandardPhysics_option4::ConstructProcess(), G4EmStandardPhysicsSS::ConstructProcess(), G4BetheHeitlerModel::G4BetheHeitlerModel(), G4DNABornIonisationModel1::G4DNABornIonisationModel1(), G4DNABornIonisationModel2::G4DNABornIonisationModel2(), G4DNAEmfietzoglouIonisationModel::G4DNAEmfietzoglouIonisationModel(), G4DNARuddIonisationExtendedModel::G4DNARuddIonisationExtendedModel(), G4DNARuddIonisationModel::G4DNARuddIonisationModel(), G4eBremParametrizedModel::G4eBremParametrizedModel(), G4eBremsstrahlungRelModel::G4eBremsstrahlungRelModel(), G4IonParametrisedLossModel::G4IonParametrisedLossModel(), G4LivermoreBremsstrahlungModel::G4LivermoreBremsstrahlungModel(), G4LivermoreIonisationModel::G4LivermoreIonisationModel(), G4LivermorePhotoElectricModel::G4LivermorePhotoElectricModel(), G4LivermoreRayleighModel::G4LivermoreRayleighModel(), G4MicroElecInelasticModel::G4MicroElecInelasticModel(), G4MicroElecInelasticModel_new(), G4MuBremsstrahlungModel::G4MuBremsstrahlungModel(), G4MuPairProductionModel::G4MuPairProductionModel(), G4PAIModel::G4PAIModel(), G4PAIPhotModel::G4PAIPhotModel(), G4PairProductionRelModel::G4PairProductionRelModel(), G4PEEffectFluoModel::G4PEEffectFluoModel(), G4SeltzerBergerModel::G4SeltzerBergerModel(), G4AtimaEnergyLossModel::Initialise(), G4BetheBlochModel::Initialise(), G4BraggIonModel::Initialise(), G4BraggModel::Initialise(), G4ICRU73QOModel::Initialise(), G4LindhardSorensenIonModel::Initialise(), and G4MollerBhabhaModel::Initialise().

◆ SetAngularGeneratorFlag()

void G4VEmModel::SetAngularGeneratorFlag ( G4bool val )

inlineinherited

Definition at line 725 of file G4VEmModel.hh.

{
  useAngularGenerator = val;
}

References G4VEmModel::useAngularGenerator.

Referenced by G4VEnergyLossProcess::PreparePhysicsTable().

◆ SetCrossSectionTable()

void G4VEmModel::SetCrossSectionTable	(	G4PhysicsTable *	p,
		G4bool	isLocal
	)

inherited

Definition at line 455 of file G4VEmModel.cc.

{
  if(p != xSectionTable) {
    if(xSectionTable != nullptr && localTable) { 
      xSectionTable->clearAndDestroy(); 
      delete xSectionTable;
    }
    xSectionTable = p;
  }
  localTable = isLocal;
}

References G4PhysicsTable::clearAndDestroy(), G4VEmModel::localTable, and G4VEmModel::xSectionTable.

Referenced by G4VMultipleScattering::BuildPhysicsTable().

◆ SetCurrentCouple()

void G4VEmModel::SetCurrentCouple ( const G4MaterialCutsCouple * ptr )

inlineinherited

Definition at line 472 of file G4VEmModel.hh.

{
  if(fCurrentCouple != ptr) {
    fCurrentCouple = ptr;
    basedCoupleIndex = currentCoupleIndex = ptr->GetIndex();
    pBaseMaterial = ptr->GetMaterial();
    pFactor = 1.0;
    if(useBaseMaterials) {
      basedCoupleIndex = (*theDensityIdx)[currentCoupleIndex];
      if(nullptr != pBaseMaterial->GetBaseMaterial()) 
    pBaseMaterial = pBaseMaterial->GetBaseMaterial();
      pFactor = (*theDensityFactor)[currentCoupleIndex];
    }
  }
}

References G4VEmModel::basedCoupleIndex, G4VEmModel::currentCoupleIndex, G4VEmModel::fCurrentCouple, G4Material::GetBaseMaterial(), G4MaterialCutsCouple::GetIndex(), G4MaterialCutsCouple::GetMaterial(), G4VEmModel::pBaseMaterial, G4VEmModel::pFactor, and G4VEmModel::useBaseMaterials.

Referenced by G4VMultipleScattering::AlongStepGetPhysicalInteractionLength(), G4EmMultiModel::ComputeCrossSectionPerAtom(), G4VEmModel::ComputeDEDX(), G4TablesForExtrapolator::ComputeTrasportXS(), G4UrbanAdjointMscModel::ComputeTruePathLengthLimit(), G4GoudsmitSaundersonMscModel::ComputeTruePathLengthLimit(), G4UrbanMscModel::ComputeTruePathLengthLimit(), G4VEmModel::CrossSection(), G4AdjointPhotoElectricModel::DefineCurrentMaterialAndElectronEnergy(), G4WentzelVIModel::DefineMaterial(), G4WentzelVIRelModel::DefineMaterial(), G4EmCalculator::GetCrossSectionPerVolume(), G4LivermoreGammaConversion5DModel::Initialise(), G4VEmModel::InitialiseElementSelectors(), G4PEEffectFluoModel::SampleSecondaries(), G4EmMultiModel::SampleSecondaries(), G4VEnergyLossProcess::SelectModel(), G4VEmProcess::SelectModel(), G4VEmModel::SelectRandomAtom(), G4VEmModel::SelectTargetAtom(), and G4VEmModel::Value().

◆ SetCurrentElement()

void G4VEmModel::SetCurrentElement ( const G4Element * elm )

inlineprotectedinherited

Definition at line 497 of file G4VEmModel.hh.

{
  fCurrentElement = elm;
  fCurrentIsotope = nullptr;
}

References G4VEmModel::fCurrentElement, and G4VEmModel::fCurrentIsotope.

Referenced by G4VEmModel::ComputeCrossSectionPerAtom(), G4eBremsstrahlungRelModel::ComputeDEDXPerVolume(), G4eBremParametrizedModel::ComputeDEDXPerVolume(), and G4VEmModel::SelectIsotopeNumber().

◆ SetDeexcitationFlag()

void G4VEmModel::SetDeexcitationFlag ( G4bool val )

inlineinherited

Definition at line 823 of file G4VEmModel.hh.

{
  flagDeexcitation = val;
}

References G4VEmModel::flagDeexcitation.

Referenced by G4DNABornIonisationModel1::G4DNABornIonisationModel1(), G4DNABornIonisationModel2::G4DNABornIonisationModel2(), G4DNACPA100IonisationModel::G4DNACPA100IonisationModel(), G4DNAEmfietzoglouIonisationModel::G4DNAEmfietzoglouIonisationModel(), G4DNARelativisticIonisationModel::G4DNARelativisticIonisationModel(), G4DNARuddIonisationExtendedModel::G4DNARuddIonisationExtendedModel(), G4DNARuddIonisationModel::G4DNARuddIonisationModel(), G4KleinNishinaModel::G4KleinNishinaModel(), G4LEPTSIonisationModel::G4LEPTSIonisationModel(), G4LivermoreComptonModel::G4LivermoreComptonModel(), G4LivermorePhotoElectricModel::G4LivermorePhotoElectricModel(), G4LivermorePolarizedComptonModel::G4LivermorePolarizedComptonModel(), G4LowEPComptonModel::G4LowEPComptonModel(), G4LowEPPolarizedComptonModel::G4LowEPPolarizedComptonModel(), G4MicroElecInelasticModel::G4MicroElecInelasticModel(), G4MicroElecInelasticModel_new(), G4PEEffectFluoModel::G4PEEffectFluoModel(), G4PenelopeBremsstrahlungModel::G4PenelopeBremsstrahlungModel(), G4PenelopeComptonModel::G4PenelopeComptonModel(), G4PenelopeIonisationModel::G4PenelopeIonisationModel(), G4PenelopePhotoElectricModel::G4PenelopePhotoElectricModel(), G4AtimaEnergyLossModel::Initialise(), G4BetheBlochModel::Initialise(), G4BraggIonModel::Initialise(), G4BraggModel::Initialise(), G4ICRU73QOModel::Initialise(), and G4LindhardSorensenIonModel::Initialise().

◆ SetElementSelectors()

void G4VEmModel::SetElementSelectors ( std::vector< G4EmElementSelector * > * p )

inlineinherited

Definition at line 852 of file G4VEmModel.hh.

{
  if(p != elmSelectors) {
    elmSelectors = p;
    nSelectors = (nullptr != elmSelectors) ? G4int(elmSelectors->size()) : 0;
    localElmSelectors = false;
  }
}

References G4VEmModel::elmSelectors, G4VEmModel::localElmSelectors, and G4VEmModel::nSelectors.

◆ SetFluctuationFlag()

void G4VEmModel::SetFluctuationFlag ( G4bool val )

inlineinherited

Definition at line 732 of file G4VEmModel.hh.

{
  lossFlucFlag = val;
}

References G4VEmModel::lossFlucFlag.

Referenced by G4EmCalculator::ComputeNuclearDEDX().

◆ SetForceBuildTable()

void G4VEmModel::SetForceBuildTable ( G4bool val )

inlineinherited

Definition at line 830 of file G4VEmModel.hh.

{
  flagForceBuildTable = val;
}

References G4VEmModel::flagForceBuildTable.

◆ SetHighEnergyLimit()

void G4VEmModel::SetHighEnergyLimit ( G4double val )

inlineinherited

Definition at line 767 of file G4VEmModel.hh.

{
  highLimit = val;
}

References G4VEmModel::highLimit.

◆ SetLocked()

void G4VEmModel::SetLocked ( G4bool val )

inlineinherited

Definition at line 884 of file G4VEmModel.hh.

{
  isLocked = val;
}

References G4VEmModel::isLocked.

Referenced by G4EmModelActivator::ActivateEmOptions(), G4EmModelActivator::AddStandardScattering(), and G4EmModelActivator::SetMscParameters().

◆ SetLowEnergyLimit()

void G4VEmModel::SetLowEnergyLimit ( G4double val )

inlineinherited

Definition at line 774 of file G4VEmModel.hh.

{
  lowLimit = val;
}

References G4VEmModel::lowLimit.

◆ SetLPMFlag()

void G4VEmModel::SetLPMFlag ( G4bool val )

inlineinherited

Definition at line 816 of file G4VEmModel.hh.

{
  theLPMflag = val;
}

References G4VEmModel::theLPMflag.

Referenced by G4eBremsstrahlungRelModel::G4eBremsstrahlungRelModel(), G4LivermoreBremsstrahlungModel::G4LivermoreBremsstrahlungModel(), G4SeltzerBergerModel::G4SeltzerBergerModel(), and G4eBremsstrahlung::InitialiseEnergyLossProcess().

◆ SetMasterThread()

void G4VEmModel::SetMasterThread ( G4bool val )

inlineinherited

Definition at line 739 of file G4VEmModel.hh.

{
  isMaster = val;
}

References G4VEmModel::isMaster.

Referenced by G4VEmProcess::PreparePhysicsTable(), G4VEnergyLossProcess::PreparePhysicsTable(), and G4VMultipleScattering::PreparePhysicsTable().

◆ SetParticleChange()

void G4VEmModel::SetParticleChange	(	G4VParticleChange *	p,
		G4VEmFluctuationModel *	f = `nullptr`
	)

inherited

Definition at line 447 of file G4VEmModel.cc.

{
  if(p != nullptr && pParticleChange != p) { pParticleChange = p; }
  if(flucModel != f) { flucModel = f; }
}

References G4VEmModel::flucModel, and G4VEmModel::pParticleChange.

Referenced by G4VMultipleScattering::AddEmModel(), G4VEmProcess::AddEmModel(), G4VEnergyLossProcess::AddEmModel(), G4VEmModel::GetParticleChangeForGamma(), G4VEmModel::GetParticleChangeForLoss(), G4EmMultiModel::Initialise(), G4IonParametrisedLossModel::Initialise(), G4DNADummyModel::Initialise(), and G4NuclearStopping::InitialiseProcess().

◆ SetPolarAngleLimit()

void G4VEmModel::SetPolarAngleLimit ( G4double val )

inlineinherited

Definition at line 802 of file G4VEmModel.hh.

{
  if(!isLocked) { polarAngleLimit = val; }
}

References G4VEmModel::isLocked, and G4VEmModel::polarAngleLimit.

Referenced by G4EmModelActivator::ActivateEmOptions(), G4TablesForExtrapolator::ComputeTrasportXS(), G4CoulombScattering::InitialiseProcess(), G4VEmProcess::PreparePhysicsTable(), and G4VMultipleScattering::PreparePhysicsTable().

◆ SetSecondaryThreshold()

void G4VEmModel::SetSecondaryThreshold ( G4double val )

inlineinherited

Definition at line 809 of file G4VEmModel.hh.

{
  secondaryThreshold = val;
}

References G4VEmModel::secondaryThreshold.

Referenced by G4MuBremsstrahlung::InitialiseEnergyLossProcess(), G4MuPairProduction::InitialiseEnergyLossProcess(), and G4eBremsstrahlung::InitialiseEnergyLossProcess().

◆ SetTripletModel()

void G4VEmModel::SetTripletModel ( G4VEmModel * p )

inlineinherited

Definition at line 645 of file G4VEmModel.hh.

{
  if(p != fTripletModel) {
    delete fTripletModel;
    fTripletModel = p;
  }
}

References G4VEmModel::fTripletModel.

Referenced by G4eplusTo2GammaOKVIModel::G4eplusTo2GammaOKVIModel().

◆ SetupForMaterial()

void G4VEmModel::SetupForMaterial	(	const G4ParticleDefinition *	,
		const G4Material *	,
		G4double	kineticEnergy
	)

virtualinherited

Reimplemented in G4eBremParametrizedModel, G4eBremsstrahlungRelModel, G4PairProductionRelModel, and G4SeltzerBergerModel.

Definition at line 440 of file G4VEmModel.cc.

442{}

Referenced by G4VEmModel::CrossSectionPerVolume(), G4PenelopeComptonModel::CrossSectionPerVolume(), G4PenelopeBremsstrahlungModel::CrossSectionPerVolume(), G4PenelopeIonisationModel::CrossSectionPerVolume(), G4EmCalculator::FindEmModel(), and G4EmElementSelector::Initialise().

◆ SetUseBaseMaterials()

void G4VEmModel::SetUseBaseMaterials ( G4bool val )

inlineinherited

Definition at line 753 of file G4VEmModel.hh.

{
  useBaseMaterials = val;
}

References G4VEmModel::useBaseMaterials.

Referenced by G4VEmProcess::BuildPhysicsTable(), G4VEnergyLossProcess::BuildPhysicsTable(), G4VMultipleScattering::BuildPhysicsTable(), G4TablesForExtrapolator::ComputeElectronDEDX(), G4TablesForExtrapolator::ComputeMuonDEDX(), G4TablesForExtrapolator::ComputeProtonDEDX(), G4TablesForExtrapolator::ComputeTrasportXS(), G4VEmProcess::PreparePhysicsTable(), G4VEnergyLossProcess::PreparePhysicsTable(), and G4VMultipleScattering::PreparePhysicsTable().

◆ StartTracking()

void G4VEmModel::StartTracking ( G4Track * )

virtualinherited

Reimplemented in G4UrbanAdjointMscModel, G4GoudsmitSaundersonMscModel, G4UrbanMscModel, and G4WentzelVIModel.

Definition at line 270 of file G4VEmModel.cc.

271{}

Referenced by G4VMultipleScattering::StartTracking().

◆ stepFunc()

G4double G4MicroElecInelasticModel_new::stepFunc ( G4double x )

Definition at line 1400 of file G4MicroElecInelasticModel_new.cc.

                                                           {
  return (x < 0.) ? 1.0 : 0.0;
}

Referenced by vrkreussler().

◆ TransferedEnergy()

G4double G4MicroElecInelasticModel_new::TransferedEnergy	(	const G4ParticleDefinition *	particleDefinition,
		G4double	k,
		G4int	ionizationLevelIndex,
		G4double	random
	)

private

Definition at line 857 of file G4MicroElecInelasticModel_new.cc.

{
  G4double nrj = 0.;
  G4double valueK1 = 0;
  G4double valueK2 = 0;
  G4double valuePROB21 = 0;
  G4double valuePROB22 = 0;
  G4double valuePROB12 = 0;
  G4double valuePROB11 = 0;
  G4double nrjTransf11 = 0;
  G4double nrjTransf12 = 0;
  G4double nrjTransf21 = 0;
  G4double nrjTransf22 = 0;
  
  G4double maximumEnergyTransfer1 = 0;
  G4double maximumEnergyTransfer2 = 0;
  G4double maximumEnergyTransferP = 4.* (electron_mass_c2 / proton_mass_c2) * k;
  G4double bindingEnergy = currentMaterialStructure->GetLimitEnergy(ionizationLevelIndex);
  
  if (particleDefinition == G4Electron::ElectronDefinition())
    {      
      dataDiffCSMap::iterator iterator_Nrj;
      iterator_Nrj = eNrjTransStorage.find(currentMaterial);
      
      dataProbaShellMap::iterator iterator_Proba;
      iterator_Proba = eProbaShellStorage.find(currentMaterial);
      
      incidentEnergyMap::iterator iterator_Tdummy;
      iterator_Tdummy = eIncidentEnergyStorage.find(currentMaterial);
      
      if(iterator_Nrj == eNrjTransStorage.end() || iterator_Proba == eProbaShellStorage.end() || 
     iterator_Tdummy == eIncidentEnergyStorage.end())
    {
      G4String str = "Material ";
      str += currentMaterial + " not found!";
      G4Exception("G4MicroElecInelasticModel_new::TransferedEnergy", "em0002", 
              FatalException, str);
    }
      else {
    vector<TriDimensionMap>* eNrjTransfData = iterator_Nrj->second; //Storage of possible transfer energies
    vector<VecMap>* eProbaShellMap = iterator_Proba->second; //Storage of probabilities for energy transfer
    vector<G4double>* eTdummyVec = iterator_Tdummy->second; //Incident energies for interpolation
    
    // k should be in eV
    auto k2 = std::upper_bound(eTdummyVec->begin(),
                                eTdummyVec->end(),
                                k);
    auto k1 = k2 - 1;
 
    // SI : the following condition avoids situations where random >last vector element
    if (random <= (*eProbaShellMap)[ionizationLevelIndex][(*k1)].back()
        && random <= (*eProbaShellMap)[ionizationLevelIndex][(*k2)].back())
      {
        auto prob12 =
          std::upper_bound((*eProbaShellMap)[ionizationLevelIndex][(*k1)].begin(),
                   (*eProbaShellMap)[ionizationLevelIndex][(*k1)].end(),
                   random);
        
        auto prob11 = prob12 - 1;
        
        auto prob22 =
          std::upper_bound((*eProbaShellMap)[ionizationLevelIndex][(*k2)].begin(),
                   (*eProbaShellMap)[ionizationLevelIndex][(*k2)].end(),
                   random);
        
        auto prob21 = prob22 - 1;
        
        valueK1 = *k1;
        valueK2 = *k2;
        valuePROB21 = *prob21;
        valuePROB22 = *prob22;
        valuePROB12 = *prob12;
        valuePROB11 = *prob11;
        
        // The following condition avoid getting transfered energy < binding energy and forces cumxs = 1 for maximum energy transfer.
        if (valuePROB11 == 0) nrjTransf11 = bindingEnergy;
        else nrjTransf11 = (*eNrjTransfData)[ionizationLevelIndex][valueK1][valuePROB11];
        if (valuePROB12 == 1)
          {
        if ((valueK1 + bindingEnergy) / 2. > valueK1) 
          maximumEnergyTransfer1 = valueK1;
        else 
          maximumEnergyTransfer1 = (valueK1 + bindingEnergy) / 2.;
        
        nrjTransf12 = maximumEnergyTransfer1;
          }
        else 
          nrjTransf12 = (*eNrjTransfData)[ionizationLevelIndex][valueK1][valuePROB12];
        
        if (valuePROB21 == 0) nrjTransf21 = bindingEnergy;
        else nrjTransf21 = (*eNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB21];
        if (valuePROB22 == 1)
          {
        if ((valueK2 + bindingEnergy) / 2. > valueK2) maximumEnergyTransfer2 = valueK2;
        else maximumEnergyTransfer2 = (valueK2 + bindingEnergy) / 2.;
                
        nrjTransf22 = maximumEnergyTransfer2;
          }
        else nrjTransf22 = (*eNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB22];
        
      }
    // Avoids cases where cum xs is zero for k1 and is not for k2 (with always k1<k2)
    if (random > (*eProbaShellMap)[ionizationLevelIndex][(*k1)].back())
      {
        auto prob22 =
          std::upper_bound((*eProbaShellMap)[ionizationLevelIndex][(*k2)].begin(),
                   (*eProbaShellMap)[ionizationLevelIndex][(*k2)].end(),
                   random);     
        auto prob21 = prob22 - 1;
        
        valueK1 = *k1;
        valueK2 = *k2;
        valuePROB21 = *prob21;
        valuePROB22 = *prob22;
                
        nrjTransf21 = (*eNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB21];
        nrjTransf22 = (*eNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB22];
        
        G4double interpolatedvalue2 = Interpolate(valuePROB21,
                              valuePROB22,
                              random,
                              nrjTransf21,
                              nrjTransf22);
        
        // zeros are explicitly set
        G4double value = Interpolate(valueK1, valueK2, k, 0., interpolatedvalue2);
        
        return value;
      }
      }
    }
  else if (particleDefinition == G4Proton::ProtonDefinition())
    {
      // k should be in eV      
      dataDiffCSMap::iterator iterator_Nrj;
      iterator_Nrj = pNrjTransStorage.find(currentMaterial);
      
      dataProbaShellMap::iterator iterator_Proba;
      iterator_Proba = pProbaShellStorage.find(currentMaterial);
      
      incidentEnergyMap::iterator iterator_Tdummy;
      iterator_Tdummy = pIncidentEnergyStorage.find(currentMaterial);
      
      if (iterator_Nrj == pNrjTransStorage.end() || iterator_Proba == pProbaShellStorage.end() || 
      iterator_Tdummy == pIncidentEnergyStorage.end())
    {
      G4String str = "Material ";
      str += currentMaterial + " not found!";
      G4Exception("G4MicroElecInelasticModel_new::TransferedEnergy", "em0002", 
              FatalException, str);
    }
      else 
    {
      vector<TriDimensionMap>* pNrjTransfData = iterator_Nrj->second; //Storage of possible transfer energies
      vector<VecMap>* pProbaShellMap = iterator_Proba->second; //Storage of probabilities for energy transfer
      vector<G4double>* pTdummyVec = iterator_Tdummy->second; //Incident energies for interpolation
      
      auto k2 = std::upper_bound(pTdummyVec->begin(),
                                  pTdummyVec->end(),
                                  k);
      
      auto k1 = k2 - 1;
      
      // SI : the following condition avoids situations where random > last vector element,
      //      for eg. when the last element is zero
      if (random <= (*pProbaShellMap)[ionizationLevelIndex][(*k1)].back()
          && random <= (*pProbaShellMap)[ionizationLevelIndex][(*k2)].back())
        {
          auto prob12 =
        std::upper_bound((*pProbaShellMap)[ionizationLevelIndex][(*k1)].begin(),
                 (*pProbaShellMap)[ionizationLevelIndex][(*k1)].end(),
                 random);
          auto prob11 = prob12 - 1;       
          auto prob22 =
        std::upper_bound((*pProbaShellMap)[ionizationLevelIndex][(*k2)].begin(),
                 (*pProbaShellMap)[ionizationLevelIndex][(*k2)].end(),
                 random);
          auto prob21 = prob22 - 1;
          
          valueK1 = *k1;
          valueK2 = *k2;
          valuePROB21 = *prob21;
          valuePROB22 = *prob22;
          valuePROB12 = *prob12;
          valuePROB11 = *prob11;
          
          // The following condition avoid getting transfered energy < binding energy 
          // and forces cumxs = 1 for maximum energy transfer.
          if (valuePROB11 == 0) nrjTransf11 = bindingEnergy;
          else nrjTransf11 = (*pNrjTransfData)[ionizationLevelIndex][valueK1][valuePROB11];
          
          if (valuePROB12 == 1) nrjTransf12 = maximumEnergyTransferP;
          else nrjTransf12 = (*pNrjTransfData)[ionizationLevelIndex][valueK1][valuePROB12];
          
          if (valuePROB21 == 0) nrjTransf21 = bindingEnergy;
          else nrjTransf21 = (*pNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB21];
          
          if (valuePROB22 == 1) nrjTransf22 = maximumEnergyTransferP;
          else nrjTransf22 = (*pNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB22];
          
        }
      
      // Avoids cases where cum xs is zero for k1 and is not for k2 (with always k1<k2)   
      if (random > (*pProbaShellMap)[ionizationLevelIndex][(*k1)].back())
        {
          auto prob22 =
        std::upper_bound((*pProbaShellMap)[ionizationLevelIndex][(*k2)].begin(),
                 (*pProbaShellMap)[ionizationLevelIndex][(*k2)].end(),
                 random);
          
          auto prob21 = prob22 - 1;
          
          valueK1 = *k1;
          valueK2 = *k2;
          valuePROB21 = *prob21;
          valuePROB22 = *prob22;
          
          nrjTransf21 = (*pNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB21];
          nrjTransf22 = (*pNrjTransfData)[ionizationLevelIndex][valueK2][valuePROB22];
          
          G4double interpolatedvalue2 = Interpolate(valuePROB21,
                            valuePROB22,
                            random,
                            nrjTransf21,
                            nrjTransf22);
          
          // zeros are explicitly set         
          G4double value = Interpolate(valueK1, valueK2, k, 0., interpolatedvalue2);          
          return value;
        }
    }
    }
  // End electron and proton cases
  
  G4double nrjTransfProduct = nrjTransf11 * nrjTransf12 * nrjTransf21 * nrjTransf22;
  
  if (nrjTransfProduct != 0.)
    {
      nrj = QuadInterpolator(valuePROB11,
                 valuePROB12,
                 valuePROB21,
                 valuePROB22,
                 nrjTransf11,
                 nrjTransf12,
                 nrjTransf21,
                 nrjTransf22,
                 valueK1,
                 valueK2,
                 k,
                 random);
    }
  
  return nrj;
}

References G4InuclSpecialFunctions::bindingEnergy(), currentMaterial, currentMaterialStructure, eIncidentEnergyStorage, source.hepunit::electron_mass_c2, G4Electron::ElectronDefinition(), eNrjTransStorage, eProbaShellStorage, FatalException, G4Exception(), G4MicroElecMaterialStructure::GetLimitEnergy(), Interpolate(), pIncidentEnergyStorage, pNrjTransStorage, pProbaShellStorage, source.hepunit::proton_mass_c2, G4Proton::ProtonDefinition(), and QuadInterpolator().

Referenced by RandomizeEjectedElectronEnergyFromCumulatedDcs().

◆ UseAngularGeneratorFlag()

G4bool G4VEmModel::UseAngularGeneratorFlag ( ) const

inlineinherited

Definition at line 718 of file G4VEmModel.hh.

{
  return useAngularGenerator;
}

References G4VEmModel::useAngularGenerator.

Referenced by G4AtimaEnergyLossModel::Initialise(), G4BetheBlochModel::Initialise(), G4BraggIonModel::Initialise(), G4BraggModel::Initialise(), G4ICRU73QOModel::Initialise(), G4LindhardSorensenIonModel::Initialise(), G4MollerBhabhaModel::Initialise(), G4AtimaEnergyLossModel::SampleSecondaries(), G4BetheBlochModel::SampleSecondaries(), G4BraggIonModel::SampleSecondaries(), G4BraggModel::SampleSecondaries(), G4ICRU73QOModel::SampleSecondaries(), G4LindhardSorensenIonModel::SampleSecondaries(), and G4MollerBhabhaModel::SampleSecondaries().

◆ UseBaseMaterials()

G4bool G4VEmModel::UseBaseMaterials ( ) const

inlineinherited

Definition at line 760 of file G4VEmModel.hh.

{
  return useBaseMaterials;
}

References G4VEmModel::useBaseMaterials.

◆ Value()

G4double G4VEmModel::Value	(	const G4MaterialCutsCouple *	couple,
		const G4ParticleDefinition *	p,
		G4double	kineticEnergy
	)

virtualinherited

Definition at line 406 of file G4VEmModel.cc.

{
  SetCurrentCouple(couple);
  return pFactor*e*e*CrossSectionPerVolume(pBaseMaterial,p,e,0.0,DBL_MAX);
}

References G4VEmModel::CrossSectionPerVolume(), DBL_MAX, G4VEmModel::pBaseMaterial, G4VEmModel::pFactor, and G4VEmModel::SetCurrentCouple().

Referenced by G4IonParametrisedLossModel::BuildRangeVector(), G4LossTableBuilder::BuildTableForModel(), G4LivermorePhotoElectricModel::ComputeCrossSectionPerAtom(), G4IonParametrisedLossModel::ComputeLossForStep(), G4VLEPTSModel::GetMeanFreePath(), G4DNABornExcitationModel2::GetPartialCrossSection(), G4DNABornExcitationModel2::Initialise(), G4DNABornExcitationModel2::RandomSelect(), G4SeltzerBergerModel::SampleEnergyTransfer(), G4LivermoreBremsstrahlungModel::SampleSecondaries(), and G4LivermorePhotoElectricModel::SampleSecondaries().

◆ vrkreussler()

G4double G4MicroElecInelasticModel_new::vrkreussler	(	G4double	v,
		G4double	vF
	)

Definition at line 1406 of file G4MicroElecInelasticModel_new.cc.

{
  G4double r = vF*( std::pow(v/vF+1., 3.) - fabs(std::pow(v/vF-1., 3.)) 
            + 4.*(v/vF)*(v/vF) ) + stepFunc(v/vF-1.) * (3./2.*v/vF - 
                                4.*(v/vF)*(v/vF) + 3.*std::pow(v/vF, 3.) 
                                - 0.5*std::pow(v/vF, 5.));
  return r/(10.*v/vF);
}

References stepFunc().

Referenced by BKZ().

Field Documentation

◆ anglModel

G4VEmAngularDistribution* G4VEmModel::anglModel = nullptr

privateinherited

Definition at line 414 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetAngularDistribution(), G4VEmModel::SetAngularDistribution(), and G4VEmModel::~G4VEmModel().

◆ basedCoupleIndex

size_t G4VEmModel::basedCoupleIndex = 0

protectedinherited

Definition at line 449 of file G4VEmModel.hh.

Referenced by G4VMscModel::GetTransportMeanFreePath(), and G4VEmModel::SetCurrentCouple().

◆ currentCoupleIndex

size_t G4VEmModel::currentCoupleIndex = 0

protectedinherited

Definition at line 448 of file G4VEmModel.hh.

Referenced by G4VEmModel::SetCurrentCouple().

◆ currentMaterial

G4String G4MicroElecInelasticModel_new::currentMaterial = ""

private

Definition at line 186 of file G4MicroElecInelasticModel_new.hh.

Referenced by CrossSectionPerVolume(), DifferentialCrossSection(), RandomSelect(), and TransferedEnergy().

◆ currentMaterialStructure

G4MicroElecMaterialStructure* G4MicroElecInelasticModel_new::currentMaterialStructure = nullptr

private

Definition at line 164 of file G4MicroElecInelasticModel_new.hh.

Referenced by CrossSectionPerVolume(), DifferentialCrossSection(), Initialise(), RandomizeEjectedElectronEnergy(), RandomizeEjectedElectronEnergyFromCumulatedDcs(), RandomSelect(), SampleSecondaries(), TransferedEnergy(), and ~G4MicroElecInelasticModel_new().

◆ eDiffDatatable

dataDiffCSMap G4MicroElecInelasticModel_new::eDiffDatatable

private

Definition at line 175 of file G4MicroElecInelasticModel_new.hh.

Referenced by DifferentialCrossSection(), Initialise(), and ~G4MicroElecInelasticModel_new().

◆ eIncidentEnergyStorage

incidentEnergyMap G4MicroElecInelasticModel_new::eIncidentEnergyStorage

private

Definition at line 180 of file G4MicroElecInelasticModel_new.hh.

Referenced by DifferentialCrossSection(), Initialise(), TransferedEnergy(), and ~G4MicroElecInelasticModel_new().

◆ elmSelectors

std::vector<G4EmElementSelector*>* G4VEmModel::elmSelectors = nullptr

privateinherited

Definition at line 419 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetElementSelectors(), G4VEmModel::InitialiseElementSelectors(), G4VEmModel::SelectRandomAtom(), G4VEmModel::SelectTargetAtom(), G4VEmModel::SetElementSelectors(), and G4VEmModel::~G4VEmModel().

◆ eMaxActive

G4double G4VEmModel::eMaxActive = DBL_MAX

privateinherited

Definition at line 439 of file G4VEmModel.hh.

Referenced by G4VEmModel::HighEnergyActivationLimit(), G4VEmModel::IsActive(), and G4VEmModel::SetActivationHighEnergyLimit().

◆ eMinActive

G4double G4VEmModel::eMinActive = 0.0

privateinherited

Definition at line 438 of file G4VEmModel.hh.

Referenced by G4VEmModel::IsActive(), G4VEmModel::LowEnergyActivationLimit(), and G4VEmModel::SetActivationLowEnergyLimit().

◆ eNrjTransStorage

dataDiffCSMap G4MicroElecInelasticModel_new::eNrjTransStorage

private

Definition at line 176 of file G4MicroElecInelasticModel_new.hh.

Referenced by Initialise(), TransferedEnergy(), and ~G4MicroElecInelasticModel_new().

◆ eProbaShellStorage

dataProbaShellMap G4MicroElecInelasticModel_new::eProbaShellStorage

private

Definition at line 178 of file G4MicroElecInelasticModel_new.hh.

Referenced by Initialise(), TransferedEnergy(), and ~G4MicroElecInelasticModel_new().

◆ eVecmStorage

TranfEnergyMap G4MicroElecInelasticModel_new::eVecmStorage

private

Definition at line 182 of file G4MicroElecInelasticModel_new.hh.

Referenced by DifferentialCrossSection(), Initialise(), and ~G4MicroElecInelasticModel_new().

◆ fasterCode

G4bool G4MicroElecInelasticModel_new::fasterCode

private

Definition at line 192 of file G4MicroElecInelasticModel_new.hh.

Referenced by G4MicroElecInelasticModel_new(), Initialise(), Interpolate(), and SampleSecondaries().

◆ fAtomDeexcitation

G4VAtomDeexcitation* G4MicroElecInelasticModel_new::fAtomDeexcitation = nullptr

private

Definition at line 162 of file G4MicroElecInelasticModel_new.hh.

Referenced by G4MicroElecInelasticModel_new(), Initialise(), and SampleSecondaries().

◆ fCurrentCouple

const G4MaterialCutsCouple* G4VEmModel::fCurrentCouple = nullptr

privateinherited

Definition at line 416 of file G4VEmModel.hh.

Referenced by G4VEmModel::CurrentCouple(), and G4VEmModel::SetCurrentCouple().

◆ fCurrentElement

const G4Element* G4VEmModel::fCurrentElement = nullptr

privateinherited

Definition at line 417 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetCurrentElement(), G4VEmModel::SelectRandomAtom(), G4VEmModel::SelectRandomAtomNumber(), G4VEmModel::SelectTargetAtom(), and G4VEmModel::SetCurrentElement().

◆ fCurrentIsotope

const G4Isotope* G4VEmModel::fCurrentIsotope = nullptr

privateinherited

Definition at line 418 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetCurrentIsotope(), G4VEmModel::SelectIsotopeNumber(), G4VEmModel::SelectRandomAtom(), G4VEmModel::SelectTargetAtom(), and G4VEmModel::SetCurrentElement().

◆ fElementData

G4ElementData* G4VEmModel::fElementData = nullptr

protectedinherited

Definition at line 424 of file G4VEmModel.hh.

Referenced by G4MuPairProductionModel::FindScaledEnergy(), G4VEmModel::GetElementData(), G4MuPairProductionModel::Initialise(), G4MuPairProductionModel::InitialiseLocal(), G4MuPairProductionModel::MakeSamplingTables(), G4MuPairProductionModel::RetrieveTables(), G4MuPairProductionModel::StoreTables(), and G4VEmModel::~G4VEmModel().

◆ fEmManager

G4LossTableManager* G4VEmModel::fEmManager

privateinherited

Definition at line 420 of file G4VEmModel.hh.

Referenced by G4VEmModel::G4VEmModel(), and G4VEmModel::~G4VEmModel().

◆ flagDeexcitation

G4bool G4VEmModel::flagDeexcitation = false

privateinherited

Definition at line 455 of file G4VEmModel.hh.

Referenced by G4VEmModel::DeexcitationFlag(), and G4VEmModel::SetDeexcitationFlag().

◆ flagForceBuildTable

G4bool G4VEmModel::flagForceBuildTable = false

privateinherited

Definition at line 456 of file G4VEmModel.hh.

Referenced by G4VEmModel::ForceBuildTableFlag(), and G4VEmModel::SetForceBuildTable().

◆ flucModel

G4VEmFluctuationModel* G4VEmModel::flucModel = nullptr

privateinherited

Definition at line 413 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetModelOfFluctuations(), and G4VEmModel::SetParticleChange().

◆ fParticleChangeForGamma

G4ParticleChangeForGamma* G4MicroElecInelasticModel_new::fParticleChangeForGamma = nullptr

protected

Definition at line 133 of file G4MicroElecInelasticModel_new.hh.

Referenced by G4MicroElecInelasticModel_new(), Initialise(), and SampleSecondaries().

◆ fTripletModel

G4VEmModel* G4VEmModel::fTripletModel = nullptr

privateinherited

Definition at line 415 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetParticleChangeForGamma(), G4VEmModel::GetParticleChangeForLoss(), G4VEmModel::GetTripletModel(), and G4VEmModel::SetTripletModel().

◆ highEnergyLimit

std::map<G4String,G4double,std::less<G4String> > G4MicroElecInelasticModel_new::highEnergyLimit

private

Definition at line 188 of file G4MicroElecInelasticModel_new.hh.

Referenced by Initialise().

◆ highLimit

G4double G4VEmModel::highLimit

privateinherited

Definition at line 437 of file G4VEmModel.hh.

Referenced by G4VEmModel::HighEnergyLimit(), G4VEmModel::InitialiseElementSelectors(), and G4VEmModel::SetHighEnergyLimit().

◆ inveplus

G4double G4VEmModel::inveplus

protectedinherited

Definition at line 431 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetChargeSquareRatio(), G4VMscModel::GetDEDX(), G4VMscModel::GetEnergy(), G4VMscModel::GetRange(), G4LindhardSorensenIonModel::SetupParameters(), and G4BetheBlochModel::SetupParameters().

◆ isInitialised

G4bool G4MicroElecInelasticModel_new::isInitialised

private

Definition at line 191 of file G4MicroElecInelasticModel_new.hh.

Referenced by Initialise().

◆ isLocked

G4bool G4VEmModel::isLocked = false

privateinherited

Definition at line 463 of file G4VEmModel.hh.

Referenced by G4VEmModel::IsLocked(), G4VEmModel::SetLocked(), and G4VEmModel::SetPolarAngleLimit().

◆ isMaster

G4bool G4VEmModel::isMaster = true

privateinherited

Definition at line 457 of file G4VEmModel.hh.

Referenced by G4VEmModel::IsMaster(), G4VEmModel::SetMasterThread(), and G4VEmModel::~G4VEmModel().

◆ localElmSelectors

G4bool G4VEmModel::localElmSelectors = true

privateinherited

Definition at line 460 of file G4VEmModel.hh.

Referenced by G4VEmModel::SetElementSelectors(), and G4VEmModel::~G4VEmModel().

◆ localTable

G4bool G4VEmModel::localTable = true

privateinherited

Definition at line 459 of file G4VEmModel.hh.

Referenced by G4VEmModel::SetCrossSectionTable(), and G4VEmModel::~G4VEmModel().

◆ lossFlucFlag

G4bool G4VEmModel::lossFlucFlag = true

protectedinherited

Definition at line 450 of file G4VEmModel.hh.

Referenced by G4ICRU49NuclearStoppingModel::NuclearStoppingPower(), and G4VEmModel::SetFluctuationFlag().

◆ lowEnergyLimit

std::map<G4String,G4double,std::less<G4String> > G4MicroElecInelasticModel_new::lowEnergyLimit

private

Definition at line 187 of file G4MicroElecInelasticModel_new.hh.

Referenced by Initialise().

◆ lowLimit

G4double G4VEmModel::lowLimit

privateinherited

Definition at line 436 of file G4VEmModel.hh.

Referenced by G4VEmModel::InitialiseElementSelectors(), G4VEmModel::LowEnergyLimit(), and G4VEmModel::SetLowEnergyLimit().

◆ name

const G4String G4VEmModel::name

privateinherited

Definition at line 465 of file G4VEmModel.hh.

Referenced by source.g4viscp.G4Scene::create_scene(), G4VEmModel::GetName(), mcscore.MCParticle::printout(), and source.g4viscp.G4Scene::update_scene().

◆ nistSi

G4Material* G4MicroElecInelasticModel_new::nistSi = nullptr

private

Definition at line 163 of file G4MicroElecInelasticModel_new.hh.

◆ nsec

G4int G4VEmModel::nsec = 5

privateinherited

Definition at line 444 of file G4VEmModel.hh.

Referenced by G4VEmModel::CrossSectionPerVolume(), and G4VEmModel::G4VEmModel().

◆ nSelectors

G4int G4VEmModel::nSelectors = 0

privateinherited

Definition at line 443 of file G4VEmModel.hh.

Referenced by G4VEmModel::InitialiseElementSelectors(), G4VEmModel::SelectRandomAtom(), G4VEmModel::SelectTargetAtom(), G4VEmModel::SetElementSelectors(), and G4VEmModel::~G4VEmModel().

◆ pBaseMaterial

const G4Material* G4VEmModel::pBaseMaterial = nullptr

protectedinherited

Definition at line 427 of file G4VEmModel.hh.

Referenced by G4VEmModel::ComputeDEDX(), G4VEmModel::CrossSection(), G4VMscModel::GetTransportMeanFreePath(), G4VEmModel::SelectRandomAtom(), G4VEmModel::SelectTargetAtom(), G4VEmModel::SetCurrentCouple(), and G4VEmModel::Value().

◆ pDiffDatatable

dataDiffCSMap G4MicroElecInelasticModel_new::pDiffDatatable

private

Definition at line 175 of file G4MicroElecInelasticModel_new.hh.

Referenced by DifferentialCrossSection(), Initialise(), and ~G4MicroElecInelasticModel_new().

◆ pFactor

G4double G4VEmModel::pFactor = 1.0

protectedinherited

Definition at line 432 of file G4VEmModel.hh.

Referenced by G4VEmModel::ComputeDEDX(), G4VEmModel::CrossSection(), G4VMscModel::GetTransportMeanFreePath(), G4VEmModel::SetCurrentCouple(), and G4VEmModel::Value().

◆ pIncidentEnergyStorage

incidentEnergyMap G4MicroElecInelasticModel_new::pIncidentEnergyStorage

private

Definition at line 180 of file G4MicroElecInelasticModel_new.hh.

Referenced by DifferentialCrossSection(), Initialise(), TransferedEnergy(), and ~G4MicroElecInelasticModel_new().

◆ pNrjTransStorage

dataDiffCSMap G4MicroElecInelasticModel_new::pNrjTransStorage

private

Definition at line 176 of file G4MicroElecInelasticModel_new.hh.

Referenced by Initialise(), TransferedEnergy(), and ~G4MicroElecInelasticModel_new().

◆ polarAngleLimit

G4double G4VEmModel::polarAngleLimit

privateinherited

Definition at line 441 of file G4VEmModel.hh.

Referenced by G4VEmModel::PolarAngleLimit(), and G4VEmModel::SetPolarAngleLimit().

◆ pParticleChange

G4VParticleChange* G4VEmModel::pParticleChange = nullptr

protectedinherited

Definition at line 425 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetParticleChangeForGamma(), G4VEmModel::GetParticleChangeForLoss(), G4VMscModel::GetParticleChangeForMSC(), G4EmMultiModel::Initialise(), and G4VEmModel::SetParticleChange().

◆ pProbaShellStorage

dataProbaShellMap G4MicroElecInelasticModel_new::pProbaShellStorage

private

Definition at line 178 of file G4MicroElecInelasticModel_new.hh.

Referenced by Initialise(), TransferedEnergy(), and ~G4MicroElecInelasticModel_new().

◆ pVecmStorage

TranfEnergyMap G4MicroElecInelasticModel_new::pVecmStorage

private

Definition at line 182 of file G4MicroElecInelasticModel_new.hh.

Referenced by DifferentialCrossSection(), Initialise(), and ~G4MicroElecInelasticModel_new().

◆ secondaryThreshold

G4double G4VEmModel::secondaryThreshold = DBL_MAX

privateinherited

Definition at line 440 of file G4VEmModel.hh.

Referenced by G4VEmModel::SecondaryThreshold(), and G4VEmModel::SetSecondaryThreshold().

◆ SEFromFermiLevel

G4bool G4MicroElecInelasticModel_new::SEFromFermiLevel

private

Definition at line 193 of file G4MicroElecInelasticModel_new.hh.

Referenced by G4MicroElecInelasticModel_new(), RandomizeEjectedElectronEnergyFromCumulatedDcs(), and SampleSecondaries().

◆ tableMaterialsStructures

MapStructure G4MicroElecInelasticModel_new::tableMaterialsStructures

private

Definition at line 184 of file G4MicroElecInelasticModel_new.hh.

Referenced by CrossSectionPerVolume(), Initialise(), and ~G4MicroElecInelasticModel_new().

◆ tableTCS

TCSMap G4MicroElecInelasticModel_new::tableTCS

private

Definition at line 173 of file G4MicroElecInelasticModel_new.hh.

Referenced by CrossSectionPerVolume(), Initialise(), RandomSelect(), and ~G4MicroElecInelasticModel_new().

◆ theDensityFactor

const std::vector<G4double>* G4VEmModel::theDensityFactor = nullptr

protectedinherited

Definition at line 428 of file G4VEmModel.hh.

Referenced by G4VEmModel::G4VEmModel().

◆ theDensityIdx

const std::vector<G4int>* G4VEmModel::theDensityIdx = nullptr

protectedinherited

Definition at line 429 of file G4VEmModel.hh.

Referenced by G4VEmModel::G4VEmModel().

◆ theLPMflag

G4bool G4VEmModel::theLPMflag = false

privateinherited

Definition at line 454 of file G4VEmModel.hh.

Referenced by G4VEmModel::LPMFlag(), and G4VEmModel::SetLPMFlag().

◆ useAngularGenerator

G4bool G4VEmModel::useAngularGenerator = false

privateinherited

Definition at line 461 of file G4VEmModel.hh.

Referenced by G4VEmModel::SetAngularGeneratorFlag(), and G4VEmModel::UseAngularGeneratorFlag().

◆ useBaseMaterials

G4bool G4VEmModel::useBaseMaterials = false

privateinherited

Definition at line 462 of file G4VEmModel.hh.

Referenced by G4VEmModel::SetCurrentCouple(), G4VEmModel::SetUseBaseMaterials(), and G4VEmModel::UseBaseMaterials().

◆ verboseLevel

G4int G4MicroElecInelasticModel_new::verboseLevel

private

Definition at line 190 of file G4MicroElecInelasticModel_new.hh.

Referenced by CrossSectionPerVolume(), G4MicroElecInelasticModel_new(), Initialise(), and SampleSecondaries().

◆ xsec

std::vector<G4double> G4VEmModel::xsec

privateinherited

Definition at line 466 of file G4VEmModel.hh.

Referenced by G4VEmModel::CrossSectionPerVolume(), G4VEmModel::G4VEmModel(), and G4VEmModel::SelectRandomAtom().

◆ xSectionTable

G4PhysicsTable* G4VEmModel::xSectionTable = nullptr

protectedinherited

Definition at line 426 of file G4VEmModel.hh.

Referenced by G4VEmModel::GetCrossSectionTable(), G4VMscModel::GetParticleChangeForMSC(), G4VMscModel::GetTransportMeanFreePath(), G4VEmModel::SetCrossSectionTable(), and G4VEmModel::~G4VEmModel().

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

source/processes/electromagnetic/lowenergy/include/G4MicroElecInelasticModel_new.hh
source/processes/electromagnetic/lowenergy/src/G4MicroElecInelasticModel_new.cc

Public Member Functions

Protected Member Functions

Protected Attributes

Private Types

Private Member Functions

Private Attributes

Detailed Description

Member Typedef Documentation

◆ dataDiffCSMap

◆ dataProbaShellMap

◆ incidentEnergyMap

◆ MapData

◆ MapFile

◆ MapStructure

◆ TCSMap

◆ TranfEnergyMap

◆ TriDimensionMap

◆ VecMap

Constructor & Destructor Documentation

◆ G4MicroElecInelasticModel_new() [1/2]

◆ ~G4MicroElecInelasticModel_new()

◆ G4MicroElecInelasticModel_new() [2/2]

Member Function Documentation

◆ BKZ()

◆ ChargeSquareRatio()

◆ ComputeCrossSectionPerAtom() [1/2]

◆ ComputeCrossSectionPerAtom() [2/2]

◆ ComputeCrossSectionPerShell()

◆ ComputeDEDX()

◆ ComputeDEDXPerVolume()

◆ ComputeElasticQmax()

◆ ComputeMeanFreePath()

◆ ComputeRelativistVelocity()

◆ CorrectionsAlongStep()

◆ CrossSection()

◆ CrossSectionPerVolume()

◆ CurrentCouple()

◆ DeexcitationFlag()

◆ DefineForRegion()

◆ DifferentialCrossSection()

◆ FillNumberOfSecondaries()

◆ ForceBuildTableFlag()

◆ GetAngularDistribution()

◆ GetChargeSquareRatio()

◆ GetCrossSectionTable()

◆ GetCurrentElement()

◆ GetCurrentIsotope()

◆ GetElementData()

◆ GetElementSelectors()

◆ GetModelOfFluctuations()

◆ GetName()

◆ GetPartialCrossSection()

◆ GetParticleChangeForGamma()

◆ GetParticleChangeForLoss()

◆ GetParticleCharge()

◆ GetTripletModel()

◆ HighEnergyActivationLimit()

◆ HighEnergyLimit()

◆ Initialise()

◆ InitialiseElementSelectors()

◆ InitialiseForElement()

◆ InitialiseForMaterial()

◆ InitialiseLocal()

◆ Interpolate()

◆ IsActive()

◆ IsLocked()

◆ IsMaster()

◆ LowEnergyActivationLimit()

◆ LowEnergyLimit()

◆ LPMFlag()

◆ MaxSecondaryEnergy()

◆ MaxSecondaryKinEnergy()

◆ MinEnergyCut()

◆ MinPrimaryEnergy()

◆ ModelDescription()

◆ operator=()

◆ PolarAngleLimit()

◆ QuadInterpolator()

◆ RandomizeCreatedElectronEnergy()

◆ RandomizeEjectedElectronEnergy()