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Please see the license in the file LICENSE and URL above * 16 // * for the full disclaimer and the limitatio 16 // * for the full disclaimer and the limitation of liability. * 17 // * 17 // * * 18 // * This code implementation is the result 18 // * This code implementation is the result of the scientific and * 19 // * technical work of the GEANT4 collaboratio 19 // * technical work of the GEANT4 collaboration. * 20 // * By using, copying, modifying or distri 20 // * By using, copying, modifying or distributing the software (or * 21 // * any work based on the software) you ag 21 // * any work based on the software) you agree to acknowledge its * 22 // * use in resulting scientific publicati 22 // * use in resulting scientific publications, and indicate your * 23 // * acceptance of all terms of the Geant4 Sof 23 // * acceptance of all terms of the Geant4 Software license. * 24 // ******************************************* 24 // ******************************************************************** 25 // 25 // >> 26 // 26 // Hadronic Process: Nuclear De-excitations 27 // Hadronic Process: Nuclear De-excitations 27 // by V. Lara (May 1998) 28 // by V. Lara (May 1998) 28 // 29 // 29 // Modifications: 30 // Modifications: 30 // 30 June 1998 by V. Lara: 31 // 30 June 1998 by V. Lara: 31 // -Using G4ParticleTable and therefore G 32 // -Using G4ParticleTable and therefore G4IonTable 32 // it can return all kind of fragments p 33 // it can return all kind of fragments produced in 33 // deexcitation 34 // deexcitation 34 // -It uses default algorithms for: 35 // -It uses default algorithms for: 35 // Evaporation: G4StatEvaporation 36 // Evaporation: G4StatEvaporation 36 // MultiFragmentation: G4DummyMF 37 // MultiFragmentation: G4DummyMF (a dummy one) 37 // Fermi Breakup model: G4StatFer 38 // Fermi Breakup model: G4StatFermiBreakUp 38 // 39 // 39 // 03 September 2008 by J. M. Quesada for exte 40 // 03 September 2008 by J. M. Quesada for external choice of inverse 40 // cross section option 41 // cross section option 41 // 06 September 2008 JMQ Also external choices 42 // 06 September 2008 JMQ Also external choices have been added for 42 // superimposed Coulomb barrier (if useSICB << 43 // superimposed Coulomb barrier (if useSICBis set true, by default is false) 43 // 23 January 2012 by V.Ivanchenko remove obso 44 // 23 January 2012 by V.Ivanchenko remove obsolete data members; added access 44 // methods to deexcitation components 45 // methods to deexcitation components 45 // 46 // 46 47 47 #ifndef G4ExcitationHandler_h 48 #ifndef G4ExcitationHandler_h 48 #define G4ExcitationHandler_h 1 49 #define G4ExcitationHandler_h 1 49 50 50 #include "globals.hh" 51 #include "globals.hh" 51 #include "G4Fragment.hh" 52 #include "G4Fragment.hh" 52 #include "G4ReactionProductVector.hh" 53 #include "G4ReactionProductVector.hh" 53 #include "G4IonTable.hh" 54 #include "G4IonTable.hh" 54 #include "G4DeexPrecoParameters.hh" 55 #include "G4DeexPrecoParameters.hh" 55 #include "G4NistManager.hh" << 56 56 57 class G4VMultiFragmentation; 57 class G4VMultiFragmentation; 58 class G4VFermiBreakUp; 58 class G4VFermiBreakUp; 59 class G4VEvaporation; 59 class G4VEvaporation; 60 class G4VEvaporationChannel; 60 class G4VEvaporationChannel; 61 class G4ParticleTable; << 61 class G4NistManager; 62 62 63 class G4ExcitationHandler 63 class G4ExcitationHandler 64 { 64 { 65 public: 65 public: 66 66 67 G4ExcitationHandler(); << 67 explicit G4ExcitationHandler(); 68 ~G4ExcitationHandler(); 68 ~G4ExcitationHandler(); 69 69 70 G4ReactionProductVector* BreakItUp(const G4F 70 G4ReactionProductVector* BreakItUp(const G4Fragment &theInitialState); 71 71 72 // short model description used for automati 72 // short model description used for automatic web documentation 73 void ModelDescription(std::ostream& outFile) 73 void ModelDescription(std::ostream& outFile) const; 74 74 75 void Initialise(); 75 void Initialise(); 76 76 77 // user defined sub-models 77 // user defined sub-models 78 // deletion is responsibility of this handle 78 // deletion is responsibility of this handler if isLocal=true 79 void SetEvaporation(G4VEvaporation* ptr, G4b 79 void SetEvaporation(G4VEvaporation* ptr, G4bool isLocal=false); 80 void SetMultiFragmentation(G4VMultiFragmenta 80 void SetMultiFragmentation(G4VMultiFragmentation* ptr); 81 void SetFermiModel(G4VFermiBreakUp* ptr); 81 void SetFermiModel(G4VFermiBreakUp* ptr); 82 void SetPhotonEvaporation(G4VEvaporationChan 82 void SetPhotonEvaporation(G4VEvaporationChannel* ptr); 83 void SetDeexChannelsType(G4DeexChannelType v 83 void SetDeexChannelsType(G4DeexChannelType val); 84 84 85 //======== Obsolete methods to be removed == 85 //======== Obsolete methods to be removed ===== 86 86 87 // parameters of sub-models 87 // parameters of sub-models 88 inline void SetMaxZForFermiBreakUp(G4int aZ) 88 inline void SetMaxZForFermiBreakUp(G4int aZ); 89 inline void SetMaxAForFermiBreakUp(G4int anA 89 inline void SetMaxAForFermiBreakUp(G4int anA); 90 inline void SetMaxAandZForFermiBreakUp(G4int 90 inline void SetMaxAandZForFermiBreakUp(G4int anA,G4int aZ); 91 inline void SetMinEForMultiFrag(G4double anE 91 inline void SetMinEForMultiFrag(G4double anE); 92 92 93 // access methods 93 // access methods 94 G4VEvaporation* GetEvaporation(); << 94 inline G4VEvaporation* GetEvaporation(); 95 G4VMultiFragmentation* GetMultiFragmentation << 95 inline G4VMultiFragmentation* GetMultiFragmentation(); 96 G4VFermiBreakUp* GetFermiModel(); << 96 inline G4VFermiBreakUp* GetFermiModel(); 97 G4VEvaporationChannel* GetPhotonEvaporation( << 97 inline G4VEvaporationChannel* GetPhotonEvaporation(); 98 98 99 // for inverse cross section choice 99 // for inverse cross section choice 100 inline void SetOPTxs(G4int opt); 100 inline void SetOPTxs(G4int opt); 101 // for superimposed Coulomb Barrier for inve << 101 // for superimposed Coulomb Barrir for inverse cross sections 102 inline void UseSICB(); 102 inline void UseSICB(); 103 103 104 //========================================== 104 //============================================== 105 105 >> 106 private: >> 107 >> 108 void SetParameters(); >> 109 106 G4ExcitationHandler(const G4ExcitationHandle 110 G4ExcitationHandler(const G4ExcitationHandler &right) = delete; 107 const G4ExcitationHandler & operator 111 const G4ExcitationHandler & operator 108 =(const G4ExcitationHandler &right) = delete 112 =(const G4ExcitationHandler &right) = delete; 109 G4bool operator==(const G4ExcitationHandler 113 G4bool operator==(const G4ExcitationHandler &right) const = delete; 110 G4bool operator!=(const G4ExcitationHandler 114 G4bool operator!=(const G4ExcitationHandler &right) const = delete; 111 << 112 private: << 113 << 114 void SetParameters(); << 115 << 116 inline void SortSecondaryFragment(G4Fragment << 117 115 118 G4VEvaporation* theEvaporation{nullptr}; << 116 G4VEvaporation* theEvaporation; 119 G4VMultiFragmentation* theMultiFragmentation 117 G4VMultiFragmentation* theMultiFragmentation; 120 G4VFermiBreakUp* theFermiModel; 118 G4VFermiBreakUp* theFermiModel; 121 G4VEvaporationChannel* thePhotonEvaporation; 119 G4VEvaporationChannel* thePhotonEvaporation; 122 G4ParticleTable* thePartTable; << 123 G4IonTable* theTableOfIons; << 124 G4NistManager* nist; << 125 120 126 const G4ParticleDefinition* theElectron; << 121 const G4ParticleDefinition* electron; 127 const G4ParticleDefinition* theNeutron; << 122 G4int icID; 128 const G4ParticleDefinition* theProton; << 129 const G4ParticleDefinition* theDeuteron; << 130 const G4ParticleDefinition* theTriton; << 131 const G4ParticleDefinition* theHe3; << 132 const G4ParticleDefinition* theAlpha; << 133 const G4ParticleDefinition* theLambda; << 134 << 135 G4int icID{0}; << 136 << 137 G4int maxZForFermiBreakUp{9}; << 138 G4int maxAForFermiBreakUp{17}; << 139 << 140 G4int fVerbose{1}; << 141 G4int fWarnings{0}; << 142 123 >> 124 G4int maxZForFermiBreakUp; >> 125 G4int maxAForFermiBreakUp; 143 G4double minEForMultiFrag; 126 G4double minEForMultiFrag; 144 G4double minExcitation; 127 G4double minExcitation; 145 G4double maxExcitation; << 146 G4double fLambdaMass; << 147 128 148 G4bool isInitialised{false}; << 129 G4IonTable* theTableOfIons; 149 G4bool isEvapLocal{true}; << 130 G4NistManager* nist; 150 G4bool isActive{true}; << 131 >> 132 G4int fVerbose; >> 133 G4bool isInitialised; >> 134 G4bool isEvapLocal; >> 135 G4bool isActive; 151 136 152 // list of fragments to store final result 137 // list of fragments to store final result 153 std::vector<G4Fragment*> theResults; 138 std::vector<G4Fragment*> theResults; 154 139 155 // list of fragments to store intermediate r 140 // list of fragments to store intermediate result 156 std::vector<G4Fragment*> results; 141 std::vector<G4Fragment*> results; 157 142 >> 143 // list of fragments to apply PhotonEvaporation >> 144 std::vector<G4Fragment*> thePhotoEvapList; >> 145 158 // list of fragments to apply Evaporation or 146 // list of fragments to apply Evaporation or Fermi Break-Up 159 std::vector<G4Fragment*> theEvapList; 147 std::vector<G4Fragment*> theEvapList; 160 }; 148 }; 161 149 162 inline void G4ExcitationHandler::SetMaxZForFer 150 inline void G4ExcitationHandler::SetMaxZForFermiBreakUp(G4int aZ) 163 { 151 { 164 maxZForFermiBreakUp = aZ; 152 maxZForFermiBreakUp = aZ; 165 } 153 } 166 154 167 inline void G4ExcitationHandler::SetMaxAForFer 155 inline void G4ExcitationHandler::SetMaxAForFermiBreakUp(G4int anA) 168 { 156 { 169 maxAForFermiBreakUp = anA; 157 maxAForFermiBreakUp = anA; 170 } 158 } 171 159 172 inline void G4ExcitationHandler::SetMaxAandZFo 160 inline void G4ExcitationHandler::SetMaxAandZForFermiBreakUp(G4int anA, G4int aZ) 173 { 161 { 174 SetMaxAForFermiBreakUp(anA); 162 SetMaxAForFermiBreakUp(anA); 175 SetMaxZForFermiBreakUp(aZ); 163 SetMaxZForFermiBreakUp(aZ); 176 } 164 } 177 165 178 inline void G4ExcitationHandler::SetMinEForMul 166 inline void G4ExcitationHandler::SetMinEForMultiFrag(G4double anE) 179 { 167 { 180 minEForMultiFrag = anE; 168 minEForMultiFrag = anE; 181 } 169 } 182 170 183 inline void G4ExcitationHandler::SortSecondary << 171 inline G4VEvaporation* G4ExcitationHandler::GetEvaporation() 184 { << 172 { 185 G4int A = frag->GetA_asInt(); << 173 return theEvaporation; 186 << 174 } 187 // gamma, e-, p, n << 175 188 if(A <= 1 || frag->IsLongLived()) { << 176 inline G4VMultiFragmentation* G4ExcitationHandler::GetMultiFragmentation() 189 theResults.push_back(frag); << 177 { 190 } else if(frag->GetExcitationEnergy() < minE << 178 return theMultiFragmentation; 191 // cold fragments << 192 G4int Z = frag->GetZ_asInt(); << 193 << 194 // is stable or d, t, He3, He4 << 195 if(nist->GetIsotopeAbundance(Z, A) > 0.0 | << 196 theResults.push_back(frag); // stable fr << 197 } else { << 198 theEvapList.push_back(frag); << 199 } << 200 // hot fragments are unstable << 201 } else { << 202 theEvapList.push_back(frag); << 203 } << 204 } 179 } >> 180 >> 181 inline G4VFermiBreakUp* G4ExcitationHandler::GetFermiModel() >> 182 { >> 183 return theFermiModel; >> 184 } >> 185 >> 186 inline G4VEvaporationChannel* G4ExcitationHandler::GetPhotonEvaporation() >> 187 { >> 188 return thePhotonEvaporation; >> 189 } >> 190 >> 191 inline void G4ExcitationHandler::SetOPTxs(G4int) >> 192 {} >> 193 >> 194 inline void G4ExcitationHandler::UseSICB() >> 195 {} 205 196 206 #endif 197 #endif 207 198