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Please see the license in the file LICENSE and URL above * // * for the full disclaimer and the limitation of liability. * // * * // * This code implementation is the result of the scientific and * // * technical work of the GEANT4 collaboration. * // * By using, copying, modifying or distributing the software (or * // * any work based on the software) you agree to acknowledge its * // * use in resulting scientific publications, and indicate your * // * acceptance of all terms of the Geant4 Software license. * // ******************************************************************** // // // $Id: G4QEnvironment.hh,v 1.38 2010-11-22 07:07:27 dennis Exp $ // GEANT4 tag $Name: not supported by cvs2svn $ // // ---------------- G4QEnvironment ---------------- // by Mikhail Kossov, August 2000. // header for Multy Quasmon Environment in the CHIPS Model // ------------------------------------------------------------ // Short description: The G4QEnvironment class corresponds to the nuclear // environment, containing excited nucleons or nuclear clusters // (G4Quasmons). In the constructer the nucleus (G4QNucleus) is clusterized // and then the projectile hadron (or hadrons) can create one (or a few) // Quasmons, which are fragmented by the Fragment member function. As a // result a vector of G4QHadrons is created, which can include the residual // nucleus in the ground state. //--------------------------------------------------------------------- #ifndef G4QEnvironment_h #define G4QEnvironment_h 1 #include "G4RandomDirection.hh" #include "G4QuasmonVector.hh" class G4QEnvironment { public: G4QEnvironment(const G4QNucleus& theEnv); // Create Env and add Quasmons // later G4QEnvironment(const G4QHadronVector& projHadrons, const G4int targPDG); G4QEnvironment(const G4QEnvironment& right); // copy QEnvironment by value G4QEnvironment(G4QEnvironment* right); // copy QEnvironment by pointer ~G4QEnvironment(); // Public Destructor // Overloaded operators const G4QEnvironment& operator=(const G4QEnvironment& right); G4bool operator==(const G4QEnvironment &right) const; G4bool operator!=(const G4QEnvironment &right) const; //Selectors G4QNucleus GetEnvironment() const; G4QuasmonVector* GetQuasmons(); // User is responsible for Destroy/Clear/Delete G4QHadronVector* GetQHadrons(); // User is responsible for Destroy/Clear/Delete G4QHadronVector* GetProjectiles(); // User is responsible for Destroy/Clear/Delete // Modifiers void AddQuasmon(G4Quasmon* Q); // Add aQuasmon to theEnvironment G4QHadronVector* Fragment(); // User must clear and destroy the G4QHadronVec // External managment void DecayBaryon(G4QHadron* dB, G4QHadronVector* HV); // Decay baryon void DecayMeson(G4QHadron* dB, G4QHadronVector* HV); // Decay meson void DecayAntistrange(G4QHadron* aS, G4QHadronVector* HV);// Decay AntiStrNuc void CheckMassShell(G4QHadronVector* HV); // All hadrons on mass shell // Static functions static void SetParameters(G4double solAn=0.4,G4bool efFlag=false,G4double piThresh=141.4, G4double mpisq=20000., G4double dinum=1880.); static void OpenElectromagneticDecays(); static void CloseElectromagneticDecays(); protected: void CleanUpQHadrons(); // Only another G4QEnvironment issue can use it (can make mess) void FillQHadrons(G4QHadronVector* input); //Only another G4QEnvironment issue can use it private: G4QHadronVector* FSInteraction(); // Final State Interaction after Hadronization G4QHadronVector HadronizeQEnvironment(); // Main HadronizationFunction used in Fragment void CopyAndDeleteHadronVector(G4QHadronVector* HV);//Copy HadrVect to Output void CreateQuasmon(const G4QContent& pQC, const G4LorentzVector& p4M, G4bool f=false); void InitClustersVector(G4int maxC, G4int maxA);//Init.NucClust's for 1st int void CleanUp(); // Makes theEnvironment=vacuum & kill Quasmons void PrepareInteractionProbabilities(const G4QContent& projQC, G4double AP); void EvaporateResidual(G4QHadron* h, G4bool f=true);// Evaporate NuclearFragm G4bool CheckGroundState(G4Quasmon* quasm,G4bool corFlag=false);//as G4Q for QHV G4bool DecayInEnvQ(G4Quasmon* quasm); // Use befor evaporation in PANIC case // Body private: // Static Parameters static G4bool WeakDecays; // Flag for opening WeakDecays (notUsed: allAreClosed) static G4bool ElMaDecays; // Flag for opening ElectroMagDecays (true by default) static G4bool EnergyFlux; // Flag for Energy Flux use instead of Multy Quasmon static G4double SolidAngle; // Part of Solid Angle to capture secondaries(@@A-dep) static G4double PiPrThresh; // Pion Production Threshold for gammas static G4double M2ShiftVir; // Shift for M2=-Q2=m_pi^2 of the virtual gamma static G4double DiNuclMass; // Double Nucleon Mass for virtual normalization // Output hadrons G4QHadronVector theQHadrons; // Vector of generated secondary hadrons // Internal working objects G4QHadronVector intQHadrons; // Vector of postponed secondary hadrons G4QCHIPSWorld* theWorld; // the CHIPS World G4int nBarClust; // Maximum BarionNumber of clusters (To optimize calc) G4double f2all; // Ratio of freeNucleons to free+denseNucleons G4QuasmonVector theQuasmons; // Intermediate vectorOfQuasmons before fragmentation G4QCandidateVector theQCandidates; // Vector of possible candidates to clusters G4QNucleus theEnvironment; // InitialNucleus (later ResidualNuclearEnvironment) G4LorentzVector tot4Mom; // Total 4-momentum in the reaction G4int totCharge; // Total charge in the reaction (for current control) G4int totBaryoN; // Total baryon number in the reaction (for cur.cont) G4QHadronVector theProjectiles; // Vector of projectiles in the interaction G4int theTargetPDG; // PDG of the target nucleus in the interaction }; //General function makes Random Unit 3D-Vector //G4ThreeVector RndmDir(); // Inline functions inline G4bool G4QEnvironment::operator==(const G4QEnvironment &rhs) const {return this == &rhs;} inline G4bool G4QEnvironment::operator!=(const G4QEnvironment &rhs) const {return this != &rhs;} inline G4QNucleus G4QEnvironment::GetEnvironment() const {return theEnvironment;} #endif