g4doxy4.10/html/_g4_evaporation_channel_8hh_source.html

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 // $Id: G4EvaporationChannel.hh 67983 2013-03-13 10:42:03Z gcosmo $

 //

 //

 //J.M. Quesada (August2008). Based on:

 //

 // Hadronic Process: Nuclear De-excitations

 // by V. Lara (Oct 1998)

 //

 // 17-11-2010 V.Ivanchenko in constructor replace G4VEmissionProbability by

 //            G4EvaporationProbability and do not new and delete probability

 //            object at each call; use G4Pow


 #ifndef G4EvaporationChannel_h

 #define G4EvaporationChannel_h 1


 #include "G4VEvaporationChannel.hh"

 #include "G4EvaporationProbability.hh"

 #include "G4VCoulombBarrier.hh"


 class G4EvaporationLevelDensityParameter;


 class G4EvaporationChannel : public G4VEvaporationChannel

 {

 public:

   // constructor

   G4EvaporationChannel(G4int theA, G4int theZ, const G4String & aName,

                G4EvaporationProbability * aEmissionStrategy,

                    G4VCoulombBarrier * aCoulombBarrier);


   // destructor

   virtual ~G4EvaporationChannel();


   inline void SetEmissionStrategy(G4EvaporationProbability * aEmissionStrategy)

   {theEvaporationProbabilityPtr = aEmissionStrategy;}


   inline void SetCoulombBarrierStrategy(G4VCoulombBarrier * aCoulombBarrier)

   {theCoulombBarrierPtr = aCoulombBarrier;}


 protected:

   // default constructor

   G4EvaporationChannel();


 public:


   //  virtual void Initialize(const G4Fragment & fragment);


   virtual G4double GetEmissionProbability(G4Fragment* fragment);


   G4FragmentVector * BreakUp(const G4Fragment & theNucleus);


   inline G4double GetMaximalKineticEnergy(void) const

   { return MaximalKineticEnergy; }


 private:


   // Calculate Binding Energy for separate fragment from nucleus

   G4double CalcBindingEnergy(G4int anA, G4int aZ);


   // Calculate maximal kinetic energy that can be carried by fragment (in MeV)

   G4double CalcMaximalKineticEnergy(G4double U);


   // Samples fragment kinetic energy.

   G4double  GetKineticEnergy(const G4Fragment & aFragment);


   // This has to be removed and put in Random Generator

   G4ThreeVector IsotropicVector(G4double Magnitude  = 1.0);


   G4EvaporationChannel(const G4EvaporationChannel & right);

   const G4EvaporationChannel & operator=(const G4EvaporationChannel & right);

   G4bool operator==(const G4EvaporationChannel & right) const;

   G4bool operator!=(const G4EvaporationChannel & right) const;


     // Data Members

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

 private:


   // This data member define the channel.

   // They are intializated at object creation (constructor) time.


   // Atomic Number of ejectile

   G4int theA;


   // Charge of ejectile

   G4int theZ;


   G4double EvaporatedMass;

   G4double ResidualMass;


   // For evaporation probability calcualation

   G4EvaporationProbability * theEvaporationProbabilityPtr;


   // For Level Density calculation

   // G4bool MyOwnLevelDensity;

   G4VLevelDensityParameter * theLevelDensityPtr;


   // For Coulomb Barrier calculation

   G4VCoulombBarrier * theCoulombBarrierPtr;

   G4double CoulombBarrier;


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


   // These values depend on the nucleus that is being evaporated.

   // They are calculated through the Initialize method which takes as parameters

   // the atomic number, charge and excitation energy of nucleus.


   // Residual Mass Number

   G4int ResidualA;


   // Residual Charge

   G4int ResidualZ;


   // Emission Probability

   G4double EmissionProbability;


   // Maximal Kinetic Energy that can be carried by fragment

   G4double MaximalKineticEnergy;


 };


 #endif

CLHEP::Hep3Vector
Definition: ThreeVector.h:41

right
Definition: F04UserTrackInformation.hh:37

G4EvaporationChannel::G4EvaporationChannel
G4EvaporationChannel()
Definition: G4EvaporationChannel.cc:72

G4EvaporationProbability
Definition: G4EvaporationProbability.hh:44

G4EvaporationChannel::GetEmissionProbability
virtual G4double GetEmissionProbability(G4Fragment *fragment)
Definition: G4EvaporationChannel.cc:95

G4EvaporationChannel
Definition: G4EvaporationChannel.hh:47

G4Fragment
Definition: G4Fragment.hh:68

G4int
int G4int
Definition: G4Types.hh:78

G4EvaporationChannel::GetMaximalKineticEnergy
G4double GetMaximalKineticEnergy(void) const
Definition: G4EvaporationChannel.hh:76

G4EvaporationChannel::SetCoulombBarrierStrategy
void SetCoulombBarrierStrategy(G4VCoulombBarrier *aCoulombBarrier)
Definition: G4EvaporationChannel.hh:61

G4EvaporationProbability.hh

G4bool
bool G4bool
Definition: G4Types.hh:79

G4FragmentVector
std::vector< G4Fragment * > G4FragmentVector
Definition: G4Fragment.hh:65

G4VCoulombBarrier
Definition: G4VCoulombBarrier.hh:37

G4EvaporationChannel::~G4EvaporationChannel
virtual ~G4EvaporationChannel()
Definition: G4EvaporationChannel.cc:87

G4VEvaporationChannel.hh

G4VCoulombBarrier.hh

G4EvaporationChannel::BreakUp
G4FragmentVector * BreakUp(const G4Fragment &theNucleus)
Definition: G4EvaporationChannel.cc:154

G4EvaporationLevelDensityParameter
Definition: G4EvaporationLevelDensityParameter.hh:40

G4double
double G4double
Definition: G4Types.hh:76

G4EvaporationChannel::SetEmissionStrategy
void SetEmissionStrategy(G4EvaporationProbability *aEmissionStrategy)
Definition: G4EvaporationChannel.hh:58

G4VLevelDensityParameter
Definition: G4VLevelDensityParameter.hh:37

G4String
Definition: examples/extended/parallel/TopC/ParN02/AnnotatedFiles/G4String.hh:45

G4VEvaporationChannel
Definition: G4VEvaporationChannel.hh:56