// // ******************************************************************** // * License and Disclaimer * // * * // * The Geant4 software is copyright of the Copyright Holders of * // * the Geant4 Collaboration. It is provided under the terms and * // * conditions of the Geant4 Software License, included in the file * // * LICENSE and available at http://cern.ch/geant4/license . These * // * include a list of copyright holders. * // * * // * Neither the authors of this software system, nor their employing * // * institutes,nor the agencies providing financial support for this * // * work make any representation or warranty, express or implied, * // * regarding this software system or assume any liability for its * // * use. 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: G4AdjointComptonModel.cc,v 1.6 2009/12/16 17:50:03 gunter Exp $ // GEANT4 tag $Name: geant4-09-04-beta-01 $ // #include "G4AdjointComptonModel.hh" #include "G4AdjointCSManager.hh" #include "G4Integrator.hh" #include "G4TrackStatus.hh" #include "G4ParticleChange.hh" #include "G4AdjointElectron.hh" #include "G4AdjointGamma.hh" #include "G4Gamma.hh" #include "G4KleinNishinaCompton.hh" //////////////////////////////////////////////////////////////////////////////// // G4AdjointComptonModel::G4AdjointComptonModel(): G4VEmAdjointModel("AdjointCompton") { SetApplyCutInRange(false); SetUseMatrix(true); SetUseMatrixPerElement(true); SetUseOnlyOneMatrixForAllElements(true); theAdjEquivOfDirectPrimPartDef =G4AdjointGamma::AdjointGamma(); theAdjEquivOfDirectSecondPartDef=G4AdjointElectron::AdjointElectron(); theDirectPrimaryPartDef=G4Gamma::Gamma(); second_part_of_same_type=false; theDirectEMModel=new G4KleinNishinaCompton(G4Gamma::Gamma(),"ComptonDirectModel"); } //////////////////////////////////////////////////////////////////////////////// // G4AdjointComptonModel::~G4AdjointComptonModel() {;} //////////////////////////////////////////////////////////////////////////////// // void G4AdjointComptonModel::SampleSecondaries(const G4Track& aTrack, G4bool IsScatProjToProjCase, G4ParticleChange* fParticleChange) { if (!UseMatrix) return RapidSampleSecondaries(aTrack,IsScatProjToProjCase,fParticleChange); //A recall of the compton scattering law is //Egamma2=Egamma1/(1+(Egamma1/E0_electron)(1.-cos_th)) //Therefore Egamma2_max= Egamma2(cos_th=1) = Egamma1 //Therefore Egamma2_min= Egamma2(cos_th=-1) = Egamma1/(1+2.(Egamma1/E0_electron)) const G4DynamicParticle* theAdjointPrimary =aTrack.GetDynamicParticle(); G4double adjointPrimKinEnergy = theAdjointPrimary->GetKineticEnergy(); if (adjointPrimKinEnergy>HighEnergyLimit*0.999){ return; } //Sample secondary energy //----------------------- G4double gammaE1; gammaE1 = SampleAdjSecEnergyFromCSMatrix(adjointPrimKinEnergy, IsScatProjToProjCase); //gammaE2 //----------- G4double gammaE2 = adjointPrimKinEnergy; if (!IsScatProjToProjCase) gammaE2 = gammaE1 - adjointPrimKinEnergy; //Cos th //------- // G4cout<<"Compton scattering "<GetTotalMomentum(); cos_th = (gammaE1 - gammaE2*cos_th)/p_elec; } G4double sin_th = 0.; if (std::abs(cos_th)>1){ //G4cout<<"Problem in compton scattering with cos_th "<0) { cos_th=1.; } else cos_th=-1.; sin_th=0.; } else sin_th = std::sqrt(1.-cos_th*cos_th); //gamma0 momentum //-------------------- G4ThreeVector dir_parallel=theAdjointPrimary->GetMomentumDirection(); G4double phi =G4UniformRand()*2.*3.1415926; G4ThreeVector gammaMomentum1 = gammaE1*G4ThreeVector(std::cos(phi)*sin_th,std::sin(phi)*sin_th,cos_th); gammaMomentum1.rotateUz(dir_parallel); // G4cout<ProposeTrackStatus(fStopAndKill); fParticleChange->AddSecondary(new G4DynamicParticle(theAdjEquivOfDirectPrimPartDef,gammaMomentum1)); //G4cout<<"gamma0Momentum "<ProposeEnergy(gammaE1); fParticleChange->ProposeMomentumDirection(gammaMomentum1.unit()); } } //////////////////////////////////////////////////////////////////////////////// // void G4AdjointComptonModel::RapidSampleSecondaries(const G4Track& aTrack, G4bool IsScatProjToProjCase, G4ParticleChange* fParticleChange) { const G4DynamicParticle* theAdjointPrimary =aTrack.GetDynamicParticle(); DefineCurrentMaterial(aTrack.GetMaterialCutsCouple()); G4double adjointPrimKinEnergy = theAdjointPrimary->GetKineticEnergy(); if (adjointPrimKinEnergy>HighEnergyLimit*0.999){ return; } G4double diffCSUsed=currentMaterial->GetElectronDensity()*twopi_mc2_rcl2; G4double gammaE1=0.; G4double gammaE2=0.; if (!IsScatProjToProjCase){ G4double Emax = GetSecondAdjEnergyMaxForProdToProjCase(adjointPrimKinEnergy); G4double Emin= GetSecondAdjEnergyMinForProdToProjCase(adjointPrimKinEnergy);; if (Emin>=Emax) return; G4double f1=(Emin-adjointPrimKinEnergy)/Emin; G4double f2=(Emax-adjointPrimKinEnergy)/Emax/f1; gammaE1=adjointPrimKinEnergy/(1.-f1*std::pow(f2,G4UniformRand()));; gammaE2=gammaE1-adjointPrimKinEnergy; diffCSUsed= diffCSUsed*(1.+2.*std::log(1.+electron_mass_c2/adjointPrimKinEnergy))*adjointPrimKinEnergy/gammaE1/gammaE2; } else { G4double Emax = GetSecondAdjEnergyMaxForScatProjToProjCase(adjointPrimKinEnergy); G4double Emin = GetSecondAdjEnergyMinForScatProjToProjCase(adjointPrimKinEnergy,currentTcutForDirectSecond); if (Emin>=Emax) return; gammaE2 =adjointPrimKinEnergy; gammaE1=Emin*std::pow(Emax/Emin,G4UniformRand()); diffCSUsed= diffCSUsed/gammaE1; } //Weight correction //----------------------- //First w_corr is set to the ratio between adjoint total CS and fwd total CS G4double w_corr=G4AdjointCSManager::GetAdjointCSManager()->GetPostStepWeightCorrection(); //Then another correction is needed due to the fact that a biaised differential CS has been used rather than the //one consistent with the direct model G4double diffCS = DiffCrossSectionPerAtomPrimToScatPrim(gammaE1, gammaE2,1,0.); if (diffCS >0) diffCS /=G4direct_CS; // here we have the normalised diffCS diffCS*=theDirectEMProcess->GetLambda(gammaE1,currentCouple); //diffCS*=theDirectEMModel->CrossSectionPerVolume(currentMaterial,G4Gamma::Gamma(),gammaE1,0.,2.*gammaE1); //G4cout<<"diffCS/diffCSUsed "<SetParentWeightByProcess(false); fParticleChange->SetSecondaryWeightByProcess(false); fParticleChange->ProposeParentWeight(new_weight); //Cos th //------- G4double cos_th = 1.+ electron_mass_c2*(1./gammaE1 -1./gammaE2); if (!IsScatProjToProjCase) { G4double p_elec=theAdjointPrimary->GetTotalMomentum(); cos_th = (gammaE1 - gammaE2*cos_th)/p_elec; } G4double sin_th = 0.; if (std::abs(cos_th)>1){ //G4cout<<"Problem in compton scattering with cos_th "<0) { cos_th=1.; } else cos_th=-1.; sin_th=0.; } else sin_th = std::sqrt(1.-cos_th*cos_th); //gamma0 momentum //-------------------- G4ThreeVector dir_parallel=theAdjointPrimary->GetMomentumDirection(); G4double phi =G4UniformRand()*2.*3.1415926; G4ThreeVector gammaMomentum1 = gammaE1*G4ThreeVector(std::cos(phi)*sin_th,std::sin(phi)*sin_th,cos_th); gammaMomentum1.rotateUz(dir_parallel); if (!IsScatProjToProjCase){ //kill the primary and add a secondary fParticleChange->ProposeTrackStatus(fStopAndKill); fParticleChange->AddSecondary(new G4DynamicParticle(theAdjEquivOfDirectPrimPartDef,gammaMomentum1)); //G4cout<<"gamma0Momentum "<ProposeEnergy(gammaE1); fParticleChange->ProposeMomentumDirection(gammaMomentum1.unit()); } } //////////////////////////////////////////////////////////////////////////////// // //The implementation here is correct for energy loss process, for the photoelectric and compton scattering the method should be redefine G4double G4AdjointComptonModel::DiffCrossSectionPerAtomPrimToSecond( G4double gamEnergy0, G4double kinEnergyElec, G4double Z, G4double A) { G4double gamEnergy1 = gamEnergy0 - kinEnergyElec; G4double dSigmadEprod=0.; if (gamEnergy1>0.) dSigmadEprod=DiffCrossSectionPerAtomPrimToScatPrim(gamEnergy0,gamEnergy1,Z,A); return dSigmadEprod; } //////////////////////////////////////////////////////////////////////////////// // G4double G4AdjointComptonModel::DiffCrossSectionPerAtomPrimToScatPrim( G4double gamEnergy0, G4double gamEnergy1, G4double Z, G4double ) { //Based on Klein Nishina formula // In the forward case (see G4KleinNishinaModel) the cross section is parametrised while // the secondaries are sampled from the // Klein Nishida differential cross section // The used diffrential cross section here is therefore the cross section multiplied by the normalised //differential Klein Nishida cross section //Klein Nishida Cross Section //----------------------------- G4double epsilon = gamEnergy0 / electron_mass_c2 ; G4double one_plus_two_epsi =1.+2.*epsilon; G4double gamEnergy1_max = gamEnergy0; G4double gamEnergy1_min = gamEnergy0/one_plus_two_epsi; if (gamEnergy1 >gamEnergy1_max || gamEnergy1ComputeCrossSectionPerAtom(G4Gamma::Gamma(), gamEnergy0, Z, 0., 0.,0.); dCS_dE1 *= G4direct_CS/CS; /* G4cout<<"the differential CS is not null"< 0. ) e_max=std::min(1./inv_e_max,HighEnergyLimit); return e_max; } //////////////////////////////////////////////////////////////////////////////// // G4double G4AdjointComptonModel::GetSecondAdjEnergyMinForProdToProjCase(G4double PrimAdjEnergy) { G4double half_e=PrimAdjEnergy/2.; G4double term=std::sqrt(half_e*(electron_mass_c2+half_e)); G4double emin=half_e+term; return emin; } //////////////////////////////////////////////////////////////////////////////// // G4double G4AdjointComptonModel::AdjointCrossSection(const G4MaterialCutsCouple* aCouple, G4double primEnergy, G4bool IsScatProjToProjCase) { if (UseMatrix) return G4VEmAdjointModel::AdjointCrossSection(aCouple,primEnergy,IsScatProjToProjCase); DefineCurrentMaterial(aCouple); G4double Cross=0.; G4double Emax_proj =0.; G4double Emin_proj =0.; if (!IsScatProjToProjCase ){ Emax_proj = GetSecondAdjEnergyMaxForProdToProjCase(primEnergy); Emin_proj = GetSecondAdjEnergyMinForProdToProjCase(primEnergy); if (Emax_proj>Emin_proj ){ Cross= std::log((Emax_proj-primEnergy)*Emin_proj/Emax_proj/(Emin_proj-primEnergy)) *(1.+2.*std::log(1.+electron_mass_c2/primEnergy)); } } else { Emax_proj = GetSecondAdjEnergyMaxForScatProjToProjCase(primEnergy); Emin_proj = GetSecondAdjEnergyMinForScatProjToProjCase(primEnergy,0.); if (Emax_proj>Emin_proj) { Cross = std::log(Emax_proj/Emin_proj); //+0.5*primEnergy*primEnergy(1./(Emin_proj*Emin_proj) - 1./(Emax_proj*Emax_proj)); neglected at the moment } } Cross*=currentMaterial->GetElectronDensity()*twopi_mc2_rcl2; lastCS=Cross; return Cross; }