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Please see the license in the file << 14 // * use. * 16 // * for the full disclaimer and the limitatio << 17 // * 15 // * * 18 // * This code implementation is the result << 16 // * This code implementation is the intellectual property of the * 19 // * technical work of the GEANT4 collaboratio << 17 // * GEANT4 collaboration. * 20 // * By using, copying, modifying or distri << 18 // * By copying, distributing or modifying the Program (or any work * 21 // * any work based on the software) you ag << 19 // * based on the Program) you indicate your acceptance of this * 22 // * use in resulting scientific publicati << 20 // * statement, and all its terms. * 23 // * acceptance of all terms of the Geant4 Sof << 24 // ******************************************* 21 // ******************************************************************** 25 // 22 // 26 // 23 // >> 24 // $Id: G4AtomicTransitionManager.hh,v 1.2 ???? >> 25 // GEANT4 tag $Name: geant4-05-00 $ 27 // 26 // 28 // Authors: Elena Guardincerri (Elena.Guardinc 27 // Authors: Elena Guardincerri (Elena.Guardincerri@ge.infn.it) 29 // Alfonso Mantero (Alfonso.Mantero@g 28 // Alfonso Mantero (Alfonso.Mantero@ge.infn.it) 30 // 29 // 31 // History: 30 // History: 32 // ----------- 31 // ----------- 33 // 32 // 34 // 16 Sept 2001 EG Modified according to a d 33 // 16 Sept 2001 EG Modified according to a design iteration in the 35 // LowEnergy category 34 // LowEnergy category 36 // 35 // 37 // ------------------------------------------- 36 // ------------------------------------------------------------------- 38 37 39 // Class description: 38 // Class description: 40 // Low Energy Electromagnetic Physics: create 39 // Low Energy Electromagnetic Physics: create or fills and manages G4AtomicShell, 41 // G4FluoTransition, G4AugerTransition objects 40 // G4FluoTransition, G4AugerTransition objects. >> 41 // Further documentation available from http://www.ge.infn.it/geant4/lowE >> 42 42 // ------------------------------------------- 43 // ------------------------------------------------------------------- 43 44 44 #ifndef G4AtomicTransitionManager_h 45 #ifndef G4AtomicTransitionManager_h 45 #define G4AtomicTransitionManager_h 1 46 #define G4AtomicTransitionManager_h 1 46 47 47 #include "G4ShellData.hh" 48 #include "G4ShellData.hh" >> 49 #include "G4FluoData.hh" >> 50 #include "G4AugerData.hh" 48 #include "G4FluoTransition.hh" 51 #include "G4FluoTransition.hh" 49 #include "G4AugerTransition.hh" << 50 #include "G4AtomicShell.hh" 52 #include "G4AtomicShell.hh" 51 #include <vector> << 53 // #include "g4std/map" >> 54 #include "g4std/vector" 52 #include "globals.hh" 55 #include "globals.hh" 53 56 54 class G4AugerData; << 55 << 56 // This class is a singleton 57 // This class is a singleton 57 class G4AtomicTransitionManager { 58 class G4AtomicTransitionManager { 58 59 59 public: 60 public: 60 /// The only way to get an instance of this << 61 /// function Instance() << 62 static G4AtomicTransitionManager* Instance() << 63 61 64 /// needs to be called once from other code << 62 // The only way to get an instance of this class is to call the 65 void Initialise(); << 63 // function Instance() >> 64 static G4AtomicTransitionManager* Instance(); 66 65 67 /// Z is the atomic number of the element, s << 66 // Z is the atomic number of the element, shellIndex is the 68 /// index (in EADL) of the shell << 67 // index (in EADL) of the shell 69 G4AtomicShell* Shell(G4int Z, size_t shellIn 68 G4AtomicShell* Shell(G4int Z, size_t shellIndex) const; 70 69 71 /// Z is the atomic number of the element, s << 70 // Z is the atomic number of the element, shellIndex is the 72 /// index (in EADL) of the final shell for t << 71 // index (in EADL) of the final shell for the transition 73 /// This function gives, upon Z and the Inde << 72 // This function gives, upon Z and the Index of the initial shell where te vacancy is, 74 /// the vacancy is, the radiative transition << 73 // the radiative transition that can happen (originating shell, energy, probability) 75 /// shell, energy, probability) << 74 const G4FluoTransition* ReachableShell(G4int Z, size_t shellIndex) const ; 76 const G4FluoTransition* ReachableShell(G4int << 75 77 << 76 // This function gives, upon Z and the Index of the initial shell where te vacancy is, 78 /// This function gives, upon Z and the Inde << 77 // the NON-radiative transition that can happen with originating shell for the transition, and the 79 /// the vacancy is, the NON-radiative transi << 78 // data for the possible auger electrons emitted (originating vacancy, energy amnd probability) 80 /// originating shell for the transition, an << 79 81 /// auger electrons emitted (originating vac << 80 const G4AugerTransition* ReachableAugerShell(G4int Z, G4int shellIndex) const ; 82 const G4AugerTransition* ReachableAugerShell << 83 81 84 /// This function returns the number of shel << 82 // This function returns the number of shells of the element 85 /// whose atomic number is Z << 83 // whose atomic number is Z 86 G4int NumberOfShells(G4int Z) const; 84 G4int NumberOfShells(G4int Z) const; 87 85 88 /// This function returns the number of thos << 86 // This function returns the number of those shells of the element 89 /// whose atomic number is Z which are reach << 87 // whose atomic number is Z which are reachable through a radiative 90 /// transition << 88 // transition 91 G4int NumberOfReachableShells(G4int Z) const << 89 92 << 90 // This function returns the number of possible radiative transitions for the atom with atomic number Z 93 /// This function returns the number of poss << 91 // i.e. the number of shell in wich a vacancy can be filled with a radiative transition 94 /// for the atom with atomic number Z i.e. t << 92 95 /// a vacancy can be filled by a NON-radiati << 93 G4int NumberOfReachableShells(G4int Z)const ; 96 G4int NumberOfReachableAugerShells(G4int Z) << 97 << 98 /// Gives the sum of the probabilities of ra << 99 /// shell whose index is shellIndex << 100 G4double << 101 TotalRadiativeTransitionProbability(G4int Z, << 102 << 103 /// Gives the sum of the probabilities of no << 104 /// shell whose index is shellIndex << 105 G4double << 106 TotalNonRadiativeTransitionProbability(G4int << 107 << 108 /// Verbosity control << 109 void SetVerboseLevel(G4int vl) {verboseLevel << 110 G4int GetVerboseLevel(){return verboseLevel; << 111 94 112 private: << 95 // This function returns the number of possible NON-radiative transitions for the atom with atomic number Z 113 explicit G4AtomicTransitionManager(); << 96 // i.e. the number of shell in wich a vacancy can be filled by a NON-radiative transition >> 97 >> 98 G4int NumberOfReachableAugerShells(G4int Z)const ; 114 99 >> 100 // Gives the sum of the probabilities of radiative transition towards the >> 101 // shell whose index is shellIndex >> 102 G4double TotalRadiativeTransitionProbability(G4int Z, size_t shellIndex); >> 103 >> 104 // Gives the sum of the probabilities of non radiative transition from the >> 105 // shell whose index is shellIndex >> 106 G4double TotalNonRadiativeTransitionProbability(G4int Z, size_t shellIndex); >> 107 >> 108 protected: >> 109 >> 110 G4AtomicTransitionManager(G4int minZ = 1, G4int maxZ = 99, >> 111 G4int limitInfTable = 6, G4int limitSupTable=100 ); 115 ~G4AtomicTransitionManager(); 112 ~G4AtomicTransitionManager(); 116 113 >> 114 private: 117 // Hide copy constructor and assignment oper 115 // Hide copy constructor and assignment operator 118 G4AtomicTransitionManager& operator=(const G 116 G4AtomicTransitionManager& operator=(const G4AtomicTransitionManager& right); 119 G4AtomicTransitionManager(const G4AtomicTran 117 G4AtomicTransitionManager(const G4AtomicTransitionManager&); 120 118 121 static G4AtomicTransitionManager* instance; 119 static G4AtomicTransitionManager* instance; 122 // since Augereffect data r stored as a tabl << 120 123 // here a pointer to an element of that clas << 124 G4AugerData* augerData; << 125 << 126 // the first element of the map is the atomi 121 // the first element of the map is the atomic number Z. 127 // the second element is a vector of G4Atomi 122 // the second element is a vector of G4AtomicShell*. 128 std::map<G4int,std::vector<G4AtomicShell*>,s << 123 G4std::map<G4int,G4std::vector<G4AtomicShell*>,G4std::less<G4int> > shellTable; 129 124 130 // the first element of the map is the atomi 125 // the first element of the map is the atomic number Z. 131 // the second element is a vector of G4Atomi 126 // the second element is a vector of G4AtomicTransition*. 132 std::map<G4int,std::vector<G4FluoTransition* << 127 G4std::map<G4int,G4std::vector<G4FluoTransition*>,G4std::less<G4int> > transitionTable; 133 128 >> 129 // since Augereffect data r stored as a table in G4AugerData, we have here a pointer to an element of that class itself. >> 130 >> 131 G4AugerData* augerData; >> 132 134 // Minimum and maximum Z in EADL table conta 133 // Minimum and maximum Z in EADL table containing identities and binding 135 // energies of shells 134 // energies of shells 136 G4int zMin = 1; << 135 G4int zMin; 137 G4int zMax = 104; << 136 G4int zMax; 138 137 139 // Minimum and maximum Z in EADL table conta 138 // Minimum and maximum Z in EADL table containing identities, transition 140 // energies and transition probabilities of 139 // energies and transition probabilities of shells 141 G4int infTableLimit = 6; << 140 G4int infTableLimit; 142 G4int supTableLimit = 104; << 141 G4int supTableLimit; 143 G4int verboseLevel; << 142 144 G4bool isInitialized; << 143 145 }; 144 }; 146 145 147 #endif 146 #endif 148 147