source: trunk/source/processes/electromagnetic/utils/include/G4VAtomDeexcitation.hh @ 1252

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// $Id: G4VAtomDeexcitation.hh,v 1.1 2009/07/09 11:42:52 vnivanch Exp $
// GEANT4 tag $Name: geant4-09-03 $
//
// -------------------------------------------------------------------
//
// GEANT4 Class header file
//
//
// File name:     G4VAtomDeexcitation
//
// Author:        Alfonso Mantero & Vladimir Ivanchenko
//
// Creation date: 30.06.2009
//
// Modifications:
//
// Class Description:
//
// Abstract interface to energy loss models

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

#ifndef G4VAtomDeexcitation_h
#define G4VAtomDeexcitation_h 1

#include "globals.hh"
#include <vector>

class G4AtomicShell;
class G4ParticleDefinition;
class G4DynamicParticle;

class G4VAtomDeexcitation {

  G4VAtomDeexcitation(const G4String& pname = "");

  virtual ~G4VAtomDeexcitation();

  //initialization
  virtual void PreparePhysicsTable(const G4ParticleDefinition&);
  virtual void BuildPhysicsTable(const G4ParticleDefinition&);

  // Get atomic shell by shell index, used by discrete processes 
  // (for example, photoelectric), when shell vacancy sampled by the model
  virtual const G4AtomicChell* GetAtomicShell(G4int Z, G4int ShellIndex);

  // selection of random shell for ionisation process
  virtual const G4AtomicShell* SelectRandomShell(const G4DynamicParticle*, 
                                                 G4int Z);

  // generation of deexcitation for given atom and shell vacancy
  virtual void GenerateParticles(std::vector<G4DynamicParticle*>*, 
                                 const G4AtomicChell*, G4int Z);

  // access or compute PIXE cross section 
  virtual G4double GetPIXECrossSection (const G4ParticleDefinition*, 
                                        G4int Z, G4double kinE);

  // calculate PIXE cross section from the models
  virtual G4double CalculatePIXECrossSection(const G4ParticleDefinition*,
                                             G4int Z, G4double kinE);

  // Sampling of PIXE for ionisation processes
  virtual void 
  AlongStepDeexcitation(std::vector<G4DynamicParticle*>* secVect, 
                        const G4DynamicParticle* icidentParticle, 
                        const G4MaterialCutsCouple*, 
                        G4double trueStepLenght, 
                        G4double eLoss);

  // Check if deexcitation is active for a given geometry volume
  G4bool CheckActiveRegion(G4int coupleIndex);

  // Access flags defined in the CheckActiveVolume method
  inline G4bool IsFluorescenceActive() const; 
  inline G4bool IsPIXECrossSectionActive() const; 

  // PIXE model name
  inline void SetPIXECrossSectionModel(const G4String&);
  inline const G4String& PIXECrossSectionModel() const;

  // Activation of deexcitation per detector region
  void SetFluorescenceActiveRegion(const G4Region* region = 0);
  void SetAugerActiveRegion(const G4Region* region = 0);
  void SetPIXECrossSectionActiveRegion(const G4Region* region = 0); 

  void SetFluorescenceActiveRegion(const G4String& rname = "");
  void SetAugerActiveRegion(const G4String& rname = "");
  void SetPIXECrossSectionActiveRegion(const G4String& rname = ""); 

private:

  // copy constructor and hide assignment operator
  G4VAtomDeexcitation(G4VAtomDeexcitation &);
  G4VAtomDeexcitation & operator=(const G4VAtomDeexcitation &right);

  G4String namePIXE;
  G4bool isFluoActive;
  G4bool isPIXEActive;

};

inline G4bool IsFluorescenceActive() const
{
  return isFluoActive;
}

inline G4bool IsPIXECrossSectionActive() const 
{
  return isPIXEActive;
}

inline 
void G4VAtomDeexcitation::SetPIXECrossSectionModel(const G4String& n)
{
  namePIXE = n;
}

inline 
const G4String& G4VAtomDeexcitation::PIXECrossSectionModel() const
{
  return namePIXE;
}

#endif