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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: G4PolarizedMollerBhabhaModel.cc,v 1.4 2007/05/23 08:52:20 vnivanch Exp $ // GEANT4 tag $Name: geant4-09-04-beta-01 $ // ------------------------------------------------------------------- // // GEANT4 Class file // // File name: G4PolarizedMollerBhabhaModel // // Author: A.Schaelicke on base of Vladimir Ivanchenko code // // Creation date: 10.11.2005 // // Modifications: // // 20-08-05, modified interface (A.Schaelicke) // // Class Description: // // Implementation of energy loss and delta-electron production by e+/e- // (including polarization effects) // // ------------------------------------------------------------------- // //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo...... #include "G4PolarizedMollerBhabhaModel.hh" #include "G4Electron.hh" #include "G4Positron.hh" #include "G4ParticleChangeForLoss.hh" #include "Randomize.hh" #include "G4PolarizationManager.hh" #include "G4PolarizationHelper.hh" #include "G4PolarizedBhabhaCrossSection.hh" #include "G4PolarizedMollerCrossSection.hh" //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... G4PolarizedMollerBhabhaModel::G4PolarizedMollerBhabhaModel(const G4ParticleDefinition* p, const G4String& nam) : G4MollerBhabhaModel(p,nam) { // G4cout<<" particle==electron "<<(p==theElectron)< TotalXSection(xmin,xmax,gam, theBeamPolarization, theTargetPolarization); G4double crossUnpol=crossSectionCalculator-> TotalXSection(xmin,xmax,gam, G4StokesVector::ZERO, G4StokesVector::ZERO); if (crossUnpol>0.) factor=crossPol/crossUnpol; // G4cout<<" factor="<* vdp, const G4MaterialCutsCouple* , const G4DynamicParticle* dp, G4double tmin, G4double maxEnergy) { // *** obtain and save target and beam polarization *** G4PolarizationManager * polarizationManger = G4PolarizationManager::GetInstance(); const G4Track * aTrack = fParticleChange->GetCurrentTrack(); // obtain polarization of the beam theBeamPolarization = dp->GetPolarization(); // obtain polarization of the media G4VPhysicalVolume* aPVolume = aTrack->GetVolume(); G4LogicalVolume* aLVolume = aPVolume->GetLogicalVolume(); const G4bool targetIsPolarized = polarizationManger->IsPolarized(aLVolume); theTargetPolarization = polarizationManger->GetVolumePolarization(aLVolume); // transfer target polarization in interaction frame if (targetIsPolarized) theTargetPolarization.rotateUz(dp->GetMomentumDirection()); G4double tmax = std::min(maxEnergy, MaxSecondaryKinEnergy(dp)); if(tmin >= tmax) return; // if(tmin > tmax) tmin = tmax; G4double polL = theBeamPolarization.z()*theTargetPolarization.z(); polL=std::fabs(polL); G4double polT = theBeamPolarization.x()*theTargetPolarization.x() + theBeamPolarization.y()*theTargetPolarization.y(); polT=std::fabs(polT); G4double kineticEnergy = dp->GetKineticEnergy(); G4double energy = kineticEnergy + electron_mass_c2; G4double totalMomentum = std::sqrt(kineticEnergy*(energy + electron_mass_c2)); G4double xmin = tmin/kineticEnergy; G4double xmax = tmax/kineticEnergy; G4double gam = energy/electron_mass_c2; G4double gamma2 = gam*gam; G4double gmo = gam - 1.; G4double gmo2 = gmo*gmo; G4double gmo3 = gmo2*gmo; G4double gpo = gam + 1.; G4double gpo2 = gpo*gpo; G4double gpo3 = gpo2*gpo; G4double x, y, q, grej, grej2; G4double z = 0.; G4double xs = 0., phi =0.; G4ThreeVector direction = dp->GetMomentumDirection(); //(Polarized) Moller (e-e-) scattering if (isElectron) { // *** dice according to polarized cross section G4double G = ((2.0*gam - 1.0)/gamma2)*(1. - polT - polL*gam); G4double H = (sqr(gam - 1.0)/gamma2)*(1. + polT + polL*((gam + 3.)/(gam - 1.))); y = 1.0 - xmax; grej = 1.0 - G*xmax + xmax*xmax*(H + (1.0 - G*y)/(y*y)); grej2 = 1.0 - G*xmin + xmin*xmin*(H + (1.0 - G*y)/(y*y)); if (grej2 > grej) grej = grej2; G4double prefM = gamma2*classic_electr_radius*classic_electr_radius/(gmo2*(gam + 1.0)); grej *= prefM; do { q = G4UniformRand(); x = xmin*xmax/(xmin*(1.0 - q) + xmax*q); if (crossSectionCalculator) { crossSectionCalculator->Initialize(x,gam,phi,theBeamPolarization, theTargetPolarization,1); xs=crossSectionCalculator->XSection(G4StokesVector::ZERO, G4StokesVector::ZERO); z=xs*sqr(x)*4.; if (grej < z) { G4cout<<"WARNING : error in Moller rejection routine! \n" <<" z = "< z); //Bhabha (e+e-) scattering } else { // *** dice according to polarized cross section y = xmax*xmax; grej = 0.; grej += y*y*gmo3*(1. + (polL + polT)*(gam + 3.)/gmo); grej += -2.*xmin*xmin*xmin*gam*gmo2*(1. - (polL + polT)*(gam + 3.)/gmo); grej += y*y*gmo*(3.*gamma2 + 6.*gam + 4.)*(1. + (polL*(3.*gam + 1.)*(gamma2 + gam + 1.) + polT*((gam + 2.)*gamma2 + 1.))/(gmo*(3.*gam*(gam + 2.) + 4.))); grej /= gpo3; grej += -xmin*(2.*gamma2 + 4.*gam + 1.)*(1. - gam*(polL*(2.*gam + 1.) + polT)/(2.*gam*(gam + 2.) + 1.))/gpo2; grej += gamma2/(gamma2 - 1.); G4double prefB = classic_electr_radius*classic_electr_radius/(gam - 1.0); grej *= prefB; do { q = G4UniformRand(); x = xmin*xmax/(xmin*(1.0 - q) + xmax*q); if (crossSectionCalculator) { crossSectionCalculator->Initialize(x,gam,phi,theBeamPolarization, theTargetPolarization,1); xs=crossSectionCalculator->XSection(G4StokesVector::ZERO, G4StokesVector::ZERO); z=xs*sqr(x)*4.; } else { G4cout<<"No calculator in Bhabha scattering"< grej) { G4cout<<"&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&"< z); } // // // polar asymmetries (due to transverse polarizations) // // if (crossSectionCalculator) { // grej*=1./(sqr(x)*sqr(gamma2-1))*sqr(gam*(1+gam)); grej=xs*2.; do { phi = twopi * G4UniformRand() ; crossSectionCalculator->Initialize(x,gam,phi,theBeamPolarization, theTargetPolarization,1); xs=crossSectionCalculator->XSection(G4StokesVector::ZERO, G4StokesVector::ZERO); if(xs > grej) { if (isElectron){ G4cout << "G4PolarizedMollerBhabhaModel::SampleSecondaries Warning! "< xs); } // fix kinematics of delta electron G4double deltaKinEnergy = x * kineticEnergy; G4double deltaMomentum = std::sqrt(deltaKinEnergy * (deltaKinEnergy + 2.0*electron_mass_c2)); G4double cost = deltaKinEnergy * (energy + electron_mass_c2) / (deltaMomentum * totalMomentum); G4double sint = 1.0 - cost*cost; if(sint > 0.0) sint = std::sqrt(sint); G4ThreeVector deltaDirection(-sint*std::cos(phi),-sint*std::sin(phi), cost) ; deltaDirection.rotateUz(direction); // primary change kineticEnergy -= deltaKinEnergy; fParticleChange->SetProposedKineticEnergy(kineticEnergy); if(kineticEnergy > DBL_MIN) { G4ThreeVector dir = totalMomentum*direction - deltaMomentum*deltaDirection; direction = dir.unit(); fParticleChange->SetProposedMomentumDirection(direction); } // create G4DynamicParticle object for delta ray G4DynamicParticle* delta = new G4DynamicParticle(theElectron,deltaDirection,deltaKinEnergy); vdp->push_back(delta); // get interaction frame G4ThreeVector nInteractionFrame = G4PolarizationHelper::GetFrame(direction,deltaDirection); if (crossSectionCalculator) { // calculate mean final state polarizations theBeamPolarization.InvRotateAz(nInteractionFrame,direction); theTargetPolarization.InvRotateAz(nInteractionFrame,direction); crossSectionCalculator->Initialize(x,gam,phi,theBeamPolarization, theTargetPolarization,2); // electron/positron fPositronPolarization=crossSectionCalculator->GetPol2(); fPositronPolarization.RotateAz(nInteractionFrame,direction); fParticleChange->ProposePolarization(fPositronPolarization); // electron fElectronPolarization=crossSectionCalculator->GetPol3(); fElectronPolarization.RotateAz(nInteractionFrame,deltaDirection); delta->SetPolarization(fElectronPolarization.x(), fElectronPolarization.y(), fElectronPolarization.z()); } else { fPositronPolarization=G4ThreeVector(); fElectronPolarization=G4ThreeVector(); } } //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......