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Desorgher << 29 // Organisation: SpaceIT GmbH << 30 // 28 // 31 // Model for the adjoint photo electric proce << 29 ///////////////////////////////////////////////////////////////////////////////// 32 // Put a higher limit on the CS to avoid a hi << 30 // Module: G4AdjointPhotoElectricModel 33 // at low energy. The very high adjoint CS of << 31 // Author: L. Desorgher 34 // reaction produce a high rate of reverse ph << 32 // Organisation: SpaceIT GmbH 35 // side of a shielding for eaxmple, the corre << 33 // Contract: ESA contract 21435/08/NL/AT 36 // correction in the StepDoIt method is not s << 34 // Customer: ESA/ESTEC 37 // energy. The problem is partially solved by << 35 ///////////////////////////////////////////////////////////////////////////////// 38 // compensating it by an extra weight correct << 36 // 39 // it with other reverse processes the revers << 37 // CHANGE HISTORY 40 // source of very occasional high weights tha << 38 // -------------- 41 // computation. A way to solve this problemn << 39 // ChangeHistory: 42 // to find as it happens in rare cases but do << 40 // -1 September 2007 creation by L. Desorgher 43 // the normal distribution. (Very Tricky!) << 41 // >> 42 // -January 2009. L. Desorgher >> 43 // Put a higher limit on the CS to avoid a high rate of Inverse Photo e- effect at low energy. The very high adjoint CS of the reverse >> 44 // photo electric reaction produce a high rate of reverse photo electric reaction in the inner side of a shielding for eaxmple, the correction of this occurence >> 45 // by weight correction in the StepDoIt method is not statistically sufficient at small energy. The problem is partially solved by setting an higher CS limit >> 46 // and compensating it by an extra weight correction factor. However when coupling it with other reverse processes the reverse photo-electric is still >> 47 // the source of very occasional high weight that decrease the efficiency of the computation. A way to solve this problemn is still needed but is difficult >> 48 // to find as it happens in rarea case but does give a weighrt that is outside the noemal distribution. (Very Tricky!) >> 49 // >> 50 // -October 2009 Correction of Element sampling. L. Desorgher >> 51 // >> 52 //------------------------------------------------------------- >> 53 // Documentation: >> 54 // Model for the adjoint photo electric process 44 // 55 // 45 ////////////////////////////////////////////// << 46 << 47 #ifndef G4AdjointPhotoElectricModel_h 56 #ifndef G4AdjointPhotoElectricModel_h 48 #define G4AdjointPhotoElectricModel_h 1 57 #define G4AdjointPhotoElectricModel_h 1 49 58 >> 59 50 #include "globals.hh" 60 #include "globals.hh" 51 #include "G4VEmAdjointModel.hh" 61 #include "G4VEmAdjointModel.hh" >> 62 #include "G4PEEffectModel.hh" >> 63 class G4AdjointPhotoElectricModel: public G4VEmAdjointModel 52 64 53 class G4AdjointPhotoElectricModel : public G4V << 54 { 65 { 55 public: << 66 public: 56 G4AdjointPhotoElectricModel(); << 57 ~G4AdjointPhotoElectricModel() override; << 58 << 59 void SampleSecondaries(const G4Track& aTrack << 60 G4ParticleChange* fPa << 61 << 62 G4double AdjointCrossSection(const G4Materia << 63 G4double primEn << 64 G4bool isScatPr << 65 67 66 G4double AdjointCrossSectionPerAtom(const G4 << 68 G4AdjointPhotoElectricModel(); 67 G4double << 69 ~G4AdjointPhotoElectricModel(); 68 << 70 69 G4AdjointPhotoElectricModel(G4AdjointPhotoEl << 71 70 G4AdjointPhotoElectricModel& operator=( << 72 71 const G4AdjointPhotoElectricModel& right) << 73 virtual void SampleSecondaries(const G4Track& aTrack, 72 << 74 G4bool IsScatProjToProjCase, 73 protected: << 75 G4ParticleChange* fParticleChange); 74 void CorrectPostStepWeight(G4ParticleChange* << 76 virtual G4double AdjointCrossSection(const G4MaterialCutsCouple* aCouple, 75 G4double old_weig << 77 G4double primEnergy, 76 G4double projecti << 78 G4bool IsScatProjToProjCase); 77 G4bool isScatProj << 79 virtual G4double GetAdjointCrossSection(const G4MaterialCutsCouple* aCouple, 78 << 80 G4double primEnergy, 79 private: << 81 G4bool IsScatProjToProjCase); 80 void DefineCurrentMaterialAndElectronEnergy( << 82 81 const G4MaterialCutsCouple* aCouple, G4dou << 83 G4double AdjointCrossSectionPerAtom(const G4Element* anElement,G4double electronEnergy); 82 << 84 83 G4double fShellProb[40][40]; << 85 84 G4double fXsec[40]; << 86 85 G4double fTotAdjointCS = 0.; << 87 inline void SetTheDirectPEEffectModel(G4PEEffectModel* aModel){theDirectPEEffectModel = aModel; 86 G4double fFactorCSBiasing = 1.; << 88 DefineDirectEMModel(aModel);} 87 G4double fPreStepAdjointCS = 0.; << 89 88 G4double fPostStepAdjointCS = 0.; << 90 virtual void CorrectPostStepWeight(G4ParticleChange* fParticleChange, 89 G4double fCurrenteEnergy = 0.; << 91 G4double old_weight, 90 << 92 G4double adjointPrimKinEnergy, 91 size_t fIndexElement = 0; << 93 G4double projectileKinEnergy, >> 94 G4bool IsScatProjToProjCase); >> 95 >> 96 >> 97 private: >> 98 G4double xsec[40]; >> 99 G4double totAdjointCS; >> 100 G4double totBiasedAdjointCS; >> 101 G4double factorCSBiasing; >> 102 G4double pre_step_AdjointCS; >> 103 G4double post_step_AdjointCS; >> 104 >> 105 >> 106 G4double shell_prob[40][40]; >> 107 >> 108 >> 109 G4PEEffectModel* theDirectPEEffectModel; >> 110 size_t index_element; >> 111 G4double current_eEnergy; >> 112 >> 113 >> 114 private: >> 115 void DefineCurrentMaterialAndElectronEnergy(const G4MaterialCutsCouple* aCouple, >> 116 G4double eEnergy); >> 117 92 }; 118 }; 93 119 94 #endif 120 #endif 95 121