Geant4 11.2.2
Toolkit for the simulation of the passage of particles through matter
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G4ElectroVDNuclearModel Class Reference

#include <G4ElectroVDNuclearModel.hh>

+ Inheritance diagram for G4ElectroVDNuclearModel:

Public Member Functions

 G4ElectroVDNuclearModel ()
 
 ~G4ElectroVDNuclearModel ()
 
G4HadFinalStateApplyYourself (const G4HadProjectile &aTrack, G4Nucleus &aTargetNucleus)
 
virtual void ModelDescription (std::ostream &outFile) const
 
- Public Member Functions inherited from G4HadronicInteraction
 G4HadronicInteraction (const G4String &modelName="HadronicModel")
 
virtual ~G4HadronicInteraction ()
 
virtual G4double SampleInvariantT (const G4ParticleDefinition *p, G4double plab, G4int Z, G4int A)
 
virtual G4bool IsApplicable (const G4HadProjectile &aTrack, G4Nucleus &targetNucleus)
 
G4double GetMinEnergy () const
 
G4double GetMinEnergy (const G4Material *aMaterial, const G4Element *anElement) const
 
void SetMinEnergy (G4double anEnergy)
 
void SetMinEnergy (G4double anEnergy, const G4Element *anElement)
 
void SetMinEnergy (G4double anEnergy, const G4Material *aMaterial)
 
G4double GetMaxEnergy () const
 
G4double GetMaxEnergy (const G4Material *aMaterial, const G4Element *anElement) const
 
void SetMaxEnergy (const G4double anEnergy)
 
void SetMaxEnergy (G4double anEnergy, const G4Element *anElement)
 
void SetMaxEnergy (G4double anEnergy, const G4Material *aMaterial)
 
G4int GetVerboseLevel () const
 
void SetVerboseLevel (G4int value)
 
const G4StringGetModelName () const
 
void DeActivateFor (const G4Material *aMaterial)
 
void ActivateFor (const G4Material *aMaterial)
 
void DeActivateFor (const G4Element *anElement)
 
void ActivateFor (const G4Element *anElement)
 
G4bool IsBlocked (const G4Material *aMaterial) const
 
G4bool IsBlocked (const G4Element *anElement) const
 
void SetRecoilEnergyThreshold (G4double val)
 
G4double GetRecoilEnergyThreshold () const
 
virtual const std::pair< G4double, G4doubleGetFatalEnergyCheckLevels () const
 
virtual std::pair< G4double, G4doubleGetEnergyMomentumCheckLevels () const
 
void SetEnergyMomentumCheckLevels (G4double relativeLevel, G4double absoluteLevel)
 
virtual void BuildPhysicsTable (const G4ParticleDefinition &)
 
virtual void InitialiseModel ()
 
 G4HadronicInteraction (const G4HadronicInteraction &right)=delete
 
const G4HadronicInteractionoperator= (const G4HadronicInteraction &right)=delete
 
G4bool operator== (const G4HadronicInteraction &right) const =delete
 
G4bool operator!= (const G4HadronicInteraction &right) const =delete
 

Additional Inherited Members

- Protected Member Functions inherited from G4HadronicInteraction
void SetModelName (const G4String &nam)
 
G4bool IsBlocked () const
 
void Block ()
 
- Protected Attributes inherited from G4HadronicInteraction
G4HadFinalState theParticleChange
 
G4int verboseLevel
 
G4double theMinEnergy
 
G4double theMaxEnergy
 
G4bool isBlocked
 

Detailed Description

Definition at line 49 of file G4ElectroVDNuclearModel.hh.

Constructor & Destructor Documentation

◆ G4ElectroVDNuclearModel()

G4ElectroVDNuclearModel::G4ElectroVDNuclearModel ( )

Definition at line 68 of file G4ElectroVDNuclearModel.cc.

69 : G4HadronicInteraction("G4ElectroVDNuclearModel"),
70 leptonKE(0.0), photonEnergy(0.0), photonQ2(0.0), secID(-1)
71{
72 SetMinEnergy(0.0);
73 SetMaxEnergy(1*PeV);
74
75 electroXS =
77 GetCrossSectionDataSet(G4ElectroNuclearCrossSection::Default_Name());
78 if ( electroXS == nullptr ) {
79 electroXS = new G4ElectroNuclearCrossSection;
80 }
81
82 gammaXS =
84 GetCrossSectionDataSet(G4PhotoNuclearCrossSection::Default_Name());
85 if ( gammaXS == nullptr ) {
86 gammaXS =
88 GetCrossSectionDataSet(G4GammaNuclearXS::Default_Name());
89 if ( gammaXS == nullptr ) {
90 gammaXS = new G4PhotoNuclearCrossSection;
91 }
92 }
93
94 // reuse existing pre-compound model
95 G4GeneratorPrecompoundInterface* precoInterface
99 G4VPreCompoundModel* pre = static_cast<G4VPreCompoundModel*>(p);
100 if(!pre) { pre = new G4PreCompoundModel(); }
101 precoInterface->SetDeExcitation(pre);
102
103 // string model
104 ftfp = new G4TheoFSGenerator();
105 ftfp->SetTransport(precoInterface);
106 theFragmentation = new G4LundStringFragmentation();
107 theStringDecay = new G4ExcitedStringDecay(theFragmentation);
108 G4FTFModel* theStringModel = new G4FTFModel();
109 theStringModel->SetFragmentationModel(theStringDecay);
110 ftfp->SetHighEnergyGenerator(theStringModel);
111
112 // Build Bertini model
113 bert = new G4CascadeInterface();
114
115 // Creator model ID
116 secID = G4PhysicsModelCatalog::GetModelID( "model_" + GetModelName() );
117}
static G4CrossSectionDataSetRegistry * Instance()
static const char * Default_Name()
G4HadronicInteraction * FindModel(const G4String &name)
static G4HadronicInteractionRegistry * Instance()
void SetMinEnergy(G4double anEnergy)
G4HadronicInteraction(const G4String &modelName="HadronicModel")
const G4String & GetModelName() const
void SetMaxEnergy(const G4double anEnergy)
static G4int GetModelID(const G4int modelIndex)
void SetTransport(G4VIntraNuclearTransportModel *const value)
void SetHighEnergyGenerator(G4VHighEnergyGenerator *const value)
void SetDeExcitation(G4VPreCompoundModel *ptr)
void SetFragmentationModel(G4VStringFragmentation *aModel)

◆ ~G4ElectroVDNuclearModel()

G4ElectroVDNuclearModel::~G4ElectroVDNuclearModel ( )

Definition at line 119 of file G4ElectroVDNuclearModel.cc.

120{
121 delete theFragmentation;
122 delete theStringDecay;
123}

Member Function Documentation

◆ ApplyYourself()

G4HadFinalState * G4ElectroVDNuclearModel::ApplyYourself ( const G4HadProjectile & aTrack,
G4Nucleus & aTargetNucleus )
virtual

Reimplemented from G4HadronicInteraction.

Definition at line 141 of file G4ElectroVDNuclearModel.cc.

143{
144 // Set up default particle change (just returns initial state)
147 leptonKE = aTrack.GetKineticEnergy();
150
151 // Set up sanity checks for real photon production
152 G4DynamicParticle lepton(aTrack.GetDefinition(), aTrack.Get4Momentum() );
153
154 // Need to call GetElementCrossSection before calling GetEquivalentPhotonEnergy.
155 const G4Material* mat = aTrack.GetMaterial();
156 G4int targZ = targetNucleus.GetZ_asInt();
157 electroXS->GetElementCrossSection(&lepton, targZ, mat);
158
159 photonEnergy = electroXS->GetEquivalentPhotonEnergy();
160 // Photon energy cannot exceed lepton energy
161 if (photonEnergy < leptonKE) {
162 photonQ2 = electroXS->GetEquivalentPhotonQ2(photonEnergy);
164 // Photon
165 if (photonEnergy > photonQ2/dM) {
166 // Produce recoil lepton and transferred photon
167 G4DynamicParticle* transferredPhoton = CalculateEMVertex(aTrack, targetNucleus);
168 // Interact gamma with nucleus
169 if (transferredPhoton) CalculateHadronicVertex(transferredPhoton, targetNucleus);
170 }
171 }
172 return &theParticleChange;
173}
@ isAlive
double G4double
Definition G4Types.hh:83
int G4int
Definition G4Types.hh:85
Hep3Vector unit() const
Hep3Vector vect() const
virtual G4double GetElementCrossSection(const G4DynamicParticle *, G4int Z, const G4Material *mat)
void SetStatusChange(G4HadFinalStateStatus aS)
void SetEnergyChange(G4double anEnergy)
void SetMomentumChange(const G4ThreeVector &aV)
const G4Material * GetMaterial() const
const G4ParticleDefinition * GetDefinition() const
G4double GetKineticEnergy() const
const G4LorentzVector & Get4Momentum() const
static G4Neutron * Neutron()
Definition G4Neutron.cc:101
static G4Proton * Proton()
Definition G4Proton.cc:90

◆ ModelDescription()

void G4ElectroVDNuclearModel::ModelDescription ( std::ostream & outFile) const
virtual

Reimplemented from G4HadronicInteraction.

Definition at line 125 of file G4ElectroVDNuclearModel.cc.

126{
127 outFile << "G4ElectroVDNuclearModel handles the inelastic scattering\n"
128 << "of e- and e+ from nuclei using the equivalent photon\n"
129 << "approximation in which the incoming lepton generates a\n"
130 << "virtual photon at the electromagnetic vertex, and the\n"
131 << "virtual photon is converted to a real photon. At low\n"
132 << "energies, the photon interacts directly with the nucleus\n"
133 << "using the Bertini cascade. At high energies the photon\n"
134 << "is converted to a pi0 which interacts using the FTFP\n"
135 << "model. The electro- and gamma-nuclear cross sections of\n"
136 << "M. Kossov are used to generate the virtual photon spectrum\n";
137}

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