10.03.p03/html/_g4_polarized_compton_model_8cc_source.html

 //

 // ********************************************************************

 // * 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: G4PolarizedComptonModel.cc 96114 2016-03-16 18:51:33Z gcosmo $

 //

 // -------------------------------------------------------------------

 //

 // GEANT4 Class file

 //

 //

 // File name:     G4PolarizedComptonModel

 //

 // Author:        Andreas Schaelicke

 //

 // Creation date: 01.05.2005

 //

 // Modifications:

 // 18-07-06 use newly calculated cross sections (P. Starovoitov)

 // 21-08-05 update interface (A. Schaelicke)

 //

 // Class Description:

 //

 // -------------------------------------------------------------------

 //

 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....

 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....


 #include "G4PolarizedComptonModel.hh"

 #include "G4PhysicalConstants.hh"

 #include "G4Electron.hh"

 #include "G4Gamma.hh"

 #include "Randomize.hh"

 #include "G4DataVector.hh"

 #include "G4ParticleChangeForGamma.hh"


 #include "G4StokesVector.hh"

 #include "G4PolarizationManager.hh"

 #include "G4PolarizationHelper.hh"

 #include "G4PolarizedComptonCrossSection.hh"


 #include "G4SystemOfUnits.hh"

 #include "G4Log.hh"

 #include "G4Exp.hh"


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....


 static const G4int nlooplim = 10000;


 G4PolarizedComptonModel::G4PolarizedComptonModel(const G4ParticleDefinition*,

                          const G4String& nam)

   : G4KleinNishinaCompton(nullptr,nam),

     verboseLevel(0)

 {

   crossSectionCalculator = new G4PolarizedComptonCrossSection();

 }


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....


 G4PolarizedComptonModel::~G4PolarizedComptonModel()

 {

   delete crossSectionCalculator;

 }


 G4double G4PolarizedComptonModel::ComputeAsymmetryPerAtom

                        (G4double gammaEnergy, G4double /*Z*/)


 {

   G4double asymmetry = 0.0 ;


   G4double k0 = gammaEnergy / electron_mass_c2 ;

   G4double k1 = 1. + 2.*k0 ;


   asymmetry = -k0;

   asymmetry *= (k0 + 1.)*sqr(k1)*G4Log(k1) - 2.*k0*(5.*sqr(k0) + 4.*k0 + 1.);

   asymmetry /= ((k0 - 2.)*k0  -2.)*sqr(k1)*G4Log(k1) + 2.*k0*(k0*(k0 + 1.)*(k0 + 8.) + 2.);


   // G4cout<<"energy = "<<GammaEnergy<<"  asymmetry = "<<asymmetry<<"\t\t GAM = "<<k0<<G4endl;

   if (asymmetry>1.) G4cout<<"ERROR in G4PolarizedComptonModel::ComputeAsymmetryPerAtom"<<G4endl;


   return asymmetry;

 }


 G4double G4PolarizedComptonModel::ComputeCrossSectionPerAtom(

                                 const G4ParticleDefinition* pd,

                                       G4double kinEnergy,

                                       G4double Z,

                                       G4double A,

                                       G4double cut,

                                       G4double emax)

 {

   double xs =

     G4KleinNishinaCompton::ComputeCrossSectionPerAtom(pd,kinEnergy,

                               Z,A,cut,emax);

   G4double polzz = theBeamPolarization.p3()*theTargetPolarization.z();

   if (polzz > 0.0) {

     G4double asym = ComputeAsymmetryPerAtom(kinEnergy, Z);

     xs *= (1.+polzz*asym);

   }

   return xs;

 }


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....


 void G4PolarizedComptonModel::SampleSecondaries(

                               std::vector<G4DynamicParticle*>* fvect,

                               const G4MaterialCutsCouple*,

                   const G4DynamicParticle* aDynamicGamma,

                   G4double, G4double)

 {

   // do nothing below the threshold

   if(aDynamicGamma->GetKineticEnergy() <= LowEnergyLimit()) { return; }


   const G4Track * aTrack = fParticleChange->GetCurrentTrack();

   G4VPhysicalVolume*  aPVolume  = aTrack->GetVolume();

   G4LogicalVolume*    aLVolume  = aPVolume->GetLogicalVolume();


   if (verboseLevel >= 1) {

     G4cout<<"G4PolarizedComptonModel::SampleSecondaries in "

           <<  aLVolume->GetName() <<G4endl;

   }

   G4PolarizationManager * polarizationManager =

     G4PolarizationManager::GetInstance();


   // obtain polarization of the beam

   theBeamPolarization =  aDynamicGamma->GetPolarization();

   theBeamPolarization.SetPhoton();


   // obtain polarization of the media

   G4bool targetIsPolarized = polarizationManager->IsPolarized(aLVolume);

   theTargetPolarization =

     polarizationManager->GetVolumePolarization(aLVolume);


   // if beam is linear polarized or target is transversely polarized

   // determine the angle to x-axis

   // (assumes same PRF as in the polarization definition)


   G4ThreeVector gamDirection0 = aDynamicGamma->GetMomentumDirection();


   // transfere theTargetPolarization

   // into the gamma frame (problem electron is at rest)

   if (targetIsPolarized) {

     theTargetPolarization.rotateUz(gamDirection0);

   }

   // The scattered gamma energy is sampled according to

   // Klein - Nishina formula.

   // The random number techniques of Butcher & Messel are used

   // (Nuc Phys 20(1960),15).

   // Note : Effects due to binding of atomic electrons are negliged.


   G4double gamEnergy0 = aDynamicGamma->GetKineticEnergy();

   G4double E0_m = gamEnergy0 / electron_mass_c2 ;


   //

   // sample the energy rate of the scattered gamma

   //


   G4double epsilon, sint2;

   G4double onecost = 0.0;

   G4double Phi     = 0.0;

   G4double greject = 1.0;

   G4double cosTeta = 1.0;

   G4double sinTeta = 0.0;


   G4double eps0       = 1./(1. + 2.*E0_m);

   G4double epsilon0sq = eps0*eps0;

   G4double alpha1     = - G4Log(eps0);

   G4double alpha2     = alpha1 + 0.5*(1.- epsilon0sq);


   G4double polarization =

     theBeamPolarization.p3()*theTargetPolarization.p3();


   CLHEP::HepRandomEngine* rndmEngineMod = G4Random::getTheEngine();

   G4int nloop = 0;

   G4bool end = false;


   G4double rndm[3];


   do {

     do {

       ++nloop;

       // false interaction if too many iterations

       if(nloop > nlooplim) {

     PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,

              "too many iterations");

     return;

       }


       // 3 random numbers to sample scattering

       rndmEngineMod->flatArray(3, rndm);


       if ( alpha1 > alpha2*rndm[0]) {

     epsilon   = G4Exp(-alpha1*rndm[1]);   // epsilon0**r

       } else {

     epsilon = std::sqrt(epsilon0sq + (1.- epsilon0sq)*rndm[1]);

       }


       onecost = (1.- epsilon)/(epsilon*E0_m);

       sint2   = onecost*(2.-onecost);


       G4double gdiced = 2.*(1./epsilon+epsilon);

       G4double gdist  = 1./epsilon + epsilon - sint2

     - polarization*(1./epsilon-epsilon)*(1.-onecost);


       greject = gdist/gdiced;


       if (greject > 1.0) {

     PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,

              "theta majoranta wrong");

       }

       // Loop checking, 03-Aug-2015, Vladimir Ivanchenko

     } while (greject < rndm[2]);


     // assuming phi loop sucessful

     end = true;


     //

     // scattered gamma angles. ( Z - axis along the parent gamma)

     //

     cosTeta = 1. - onecost;

     sinTeta = std::sqrt(sint2);

     do {

       ++nloop;


       // 2 random numbers to sample scattering

       rndmEngineMod->flatArray(2, rndm);


       // false interaction if too many iterations

       Phi = twopi * rndm[0];

       if(nloop > nlooplim) {

     PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,

              "too many iterations");

     return;

       }


       G4double gdiced = 1./epsilon + epsilon - sint2

     + std::abs(theBeamPolarization.p3())*

     ( std::abs((1./epsilon-epsilon)*cosTeta*theTargetPolarization.p3())

       +(1.-epsilon)*sinTeta*(std::sqrt(sqr(theTargetPolarization.p1())

                        + sqr(theTargetPolarization.p2()))))

     +sint2*(std::sqrt(sqr(theBeamPolarization.p1()) +

               sqr(theBeamPolarization.p2())));


       G4double gdist = 1./epsilon + epsilon - sint2

     + theBeamPolarization.p3()*

     ((1./epsilon-epsilon)*cosTeta*theTargetPolarization.p3()

      +(1.-epsilon)*sinTeta*(std::cos(Phi)*theTargetPolarization.p1()+

                 std::sin(Phi)*theTargetPolarization.p2()))

     -sint2*(std::cos(2.*Phi)*theBeamPolarization.p1()

         +std::sin(2.*Phi)*theBeamPolarization.p2());

       greject = gdist/gdiced;


       if (greject > 1.0) {

     PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,

              "phi majoranta wrong");

       }


       if(greject < 1.e-3) {

     PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,

              "phi loop ineffective");

     // restart theta loop

         end = false;

         break;

       }


       // Loop checking, 03-Aug-2015, Vladimir Ivanchenko

     } while (greject < rndm[1]);

   } while(!end);

   G4double dirx = sinTeta*std::cos(Phi), diry = sinTeta*std::sin(Phi),

     dirz = cosTeta;


   //

   // update G4VParticleChange for the scattered gamma

   //


   G4ThreeVector gamDirection1 ( dirx,diry,dirz );

   gamDirection1.rotateUz(gamDirection0);

   G4double gamEnergy1 = epsilon*gamEnergy0;


   G4double edep = 0.0;

   if(gamEnergy1 > lowestSecondaryEnergy) {

     fParticleChange->ProposeMomentumDirection(gamDirection1);

     fParticleChange->SetProposedKineticEnergy(gamEnergy1);

   } else {

     fParticleChange->ProposeTrackStatus(fStopAndKill);

     fParticleChange->SetProposedKineticEnergy(0.0);

     edep = gamEnergy1;

   }


   //

   // calculate Stokesvector of final state photon and electron

   //

   G4ThreeVector  nInteractionFrame =

     G4PolarizationHelper::GetFrame(gamDirection1,gamDirection0);


   // transfere theBeamPolarization and theTargetPolarization

   // into the interaction frame (note electron is in gamma frame)

   if (verboseLevel>=1) {

     G4cout << "========================================\n";

     G4cout << " nInteractionFrame = " <<nInteractionFrame<<"\n";

     G4cout << " GammaDirection0 = " <<gamDirection0<<"\n";

     G4cout << " gammaPolarization = " <<theBeamPolarization<<"\n";

     G4cout << " electronPolarization = " <<theTargetPolarization<<"\n";

   }


   theBeamPolarization.InvRotateAz(nInteractionFrame,gamDirection0);

   theTargetPolarization.InvRotateAz(nInteractionFrame,gamDirection0);


   if (verboseLevel>=1) {

     G4cout << "----------------------------------------\n";

     G4cout << " gammaPolarization = " <<theBeamPolarization<<"\n";

     G4cout << " electronPolarization = " <<theTargetPolarization<<"\n";

     G4cout << "----------------------------------------\n";

   }


   // initialize the polarization transfer matrix

   crossSectionCalculator->Initialize(epsilon,E0_m,0.,

                      theBeamPolarization,

                      theTargetPolarization,2);


   if(gamEnergy1 > lowestSecondaryEnergy) {


     // in interaction frame

     // calculate polarization transfer to the photon (in interaction plane)

     finalGammaPolarization = crossSectionCalculator->GetPol2();

     if (verboseLevel>=1) {

       G4cout << " gammaPolarization1 = " <<finalGammaPolarization<<"\n";

     }

     finalGammaPolarization.SetPhoton();


     // translate polarization into particle reference frame

     finalGammaPolarization.RotateAz(nInteractionFrame,gamDirection1);

     if (finalGammaPolarization.mag() > 1.+1.e-8){

       G4cout<<"ERROR in Polarizaed Compton Scattering !"<<G4endl;

       G4cout<<"Polarization of final photon more than 100%"<<G4endl;

       G4cout<<finalGammaPolarization<<" mag = "

         <<finalGammaPolarization.mag()<<G4endl;

     }

     //store polarization vector

     fParticleChange->ProposePolarization(finalGammaPolarization);

     if (verboseLevel>=1) {

       G4cout << " gammaPolarization1 = " <<finalGammaPolarization<<"\n";

       G4cout << " GammaDirection1 = " <<gamDirection1<<"\n";

     }

   }


   //

   // kinematic of the scattered electron

   //

   G4double eKinEnergy = gamEnergy0 - gamEnergy1;


   if (eKinEnergy > lowestSecondaryEnergy) {


     G4ThreeVector eDirection =

       gamEnergy0*gamDirection0 - gamEnergy1*gamDirection1;

     eDirection = eDirection.unit();


     finalElectronPolarization = crossSectionCalculator->GetPol3();

     if (verboseLevel>=1) {

       G4cout << " electronPolarization1 = "

          <<finalElectronPolarization<<"\n";

     }

     // transfer into particle reference frame

     finalElectronPolarization.RotateAz(nInteractionFrame,eDirection);

     if (verboseLevel>=1) {

       G4cout << " electronPolarization1 = "

          <<finalElectronPolarization<<"\n";

       G4cout << " ElecDirection = " <<eDirection<<"\n";

     }


     // create G4DynamicParticle object for the electron.

     G4DynamicParticle* aElectron =

       new G4DynamicParticle(theElectron,eDirection,eKinEnergy);

     //store polarization vector

     if (finalElectronPolarization.mag() > 1.+1.e-8){

       G4cout<<"ERROR in Polarizaed Compton Scattering !"<<G4endl;

       G4cout<<"Polarization of final electron more than 100%"<<G4endl;

       G4cout<<finalElectronPolarization<<" mag = "

         <<finalElectronPolarization.mag()<<G4endl;

     }

     aElectron->SetPolarization(finalElectronPolarization.p1(),

                    finalElectronPolarization.p2(),

                    finalElectronPolarization.p3());

     fvect->push_back(aElectron);

   } else {

     edep += eKinEnergy;

   }

   // energy balance

   if(edep > 0.0) {

     fParticleChange->ProposeLocalEnergyDeposit(edep);

   }

 }


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......


 void

 G4PolarizedComptonModel::PrintWarning(const G4DynamicParticle* dp, G4int nloop,

                       G4double grej, G4double onecos,

                       G4double phi, const G4String sss) const

 {

   G4ExceptionDescription ed;

   ed << "Problem of scattering sampling: " << sss << "\n"

      << "Niter= " << nloop << " grej= " << grej << " cos(theta)= "

      << 1.0-onecos << " phi= " << phi << "\n"

      << "Gamma E(MeV)= " << dp->GetKineticEnergy()/MeV

      << " dir= " << dp->GetMomentumDirection()

      << " pol= " << dp->GetPolarization();

   G4Exception("G4PolarizedComptonModel::SampleSecondaries","em0044",

           JustWarning, ed, "");


 }


 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......


G4Exp.hh

CLHEP::Hep3Vector
Definition: ThreeVector.h:41

G4VEmModel::LowEnergyLimit
G4double LowEnergyLimit() const
Definition: G4VEmModel.hh:643

G4KleinNishinaCompton::fParticleChange
G4ParticleChangeForGamma * fParticleChange
Definition: G4KleinNishinaCompton.hh:92

G4PolarizedComptonModel::G4PolarizedComptonModel
G4PolarizedComptonModel(const G4ParticleDefinition *p=nullptr, const G4String &nam="Polarized-Compton")
Definition: G4PolarizedComptonModel.cc:72

G4StokesVector.hh

G4ExceptionDescription
std::ostringstream G4ExceptionDescription
Definition: globals.hh:76

G4DynamicParticle::GetKineticEnergy
G4double GetKineticEnergy() const

G4StokesVector::p2
G4double p2() const
Definition: G4StokesVector.hh:75

G4PolarizedComptonCrossSection::GetPol3
G4StokesVector GetPol3() override
Definition: G4PolarizedComptonCrossSection.cc:223

G4VPhysicalVolume
Definition: G4VPhysicalVolume.hh:82

nlooplim
static const G4int nlooplim
Definition: G4PolarizedComptonModel.cc:70

G4PolarizationManager::GetInstance
static G4PolarizationManager * GetInstance()
Definition: G4PolarizationManager.cc:52

G4DynamicParticle
Definition: G4DynamicParticle.hh:73

G4KleinNishinaCompton::ComputeCrossSectionPerAtom
virtual G4double ComputeCrossSectionPerAtom(const G4ParticleDefinition *, G4double kinEnergy, G4double Z, G4double A, G4double cut, G4double emax) override
Definition: G4KleinNishinaCompton.cc:101

G4PolarizationManager
Definition: G4PolarizationManager.hh:59

G4ParticleChangeForGamma.hh

G4ParticleDefinition
Definition: G4ParticleDefinition.hh:72

JustWarning
Definition: G4ExceptionSeverity.hh:64

G4int
int G4int
Definition: G4Types.hh:78

G4ParticleChangeForGamma::ProposeMomentumDirection
void ProposeMomentumDirection(G4double Px, G4double Py, G4double Pz)
Definition: G4ParticleChangeForGamma.hh:147

G4InuclParticleNames::k0
Definition: G4InuclParticleNames.hh:62

CLHEP::Hep3Vector::z
double z() const

G4VParticleChange::ProposeLocalEnergyDeposit
void ProposeLocalEnergyDeposit(G4double anEnergyPart)

twopi
static constexpr double twopi
Definition: G4SIunits.hh:76

G4StokesVector::p3
G4double p3() const
Definition: G4StokesVector.hh:76

G4PolarizationHelper.hh

G4MaterialCutsCouple
Definition: G4MaterialCutsCouple.hh:50

G4PolarizationManager.hh

G4cout
G4GLOB_DLL std::ostream G4cout

A
double A(double temperature)
Definition: G4DNAElectronHoleRecombination.cc:60

G4PolarizedComptonModel::SampleSecondaries
virtual void SampleSecondaries(std::vector< G4DynamicParticle * > *, const G4MaterialCutsCouple *, const G4DynamicParticle *, G4double tmin, G4double maxEnergy) override
Definition: G4PolarizedComptonModel.cc:128

G4bool
bool G4bool
Definition: G4Types.hh:79

G4KleinNishinaCompton
Definition: G4KleinNishinaCompton.hh:58

G4DynamicParticle::GetMomentumDirection
const G4ThreeVector & GetMomentumDirection() const

G4PolarizedComptonCrossSection.hh

CLHEP::Hep3Vector::rotateUz
Hep3Vector & rotateUz(const Hep3Vector &)
Definition: ThreeVector.cc:38

G4LogicalVolume
Definition: G4LogicalVolume.hh:190

G4ParticleChangeForGamma::ProposePolarization
void ProposePolarization(const G4ThreeVector &dir)
Definition: G4ParticleChangeForGamma.hh:166

G4PolarizationHelper::GetFrame
static G4ThreeVector GetFrame(const G4ThreeVector &, const G4ThreeVector &)
Definition: G4PolarizationHelper.cc:48

G4StokesVector::p1
G4double p1() const
Definition: G4StokesVector.hh:74

python.hepunit.electron_mass_c2
float electron_mass_c2
Definition: hepunit.py:274

Randomize.hh

G4KleinNishinaCompton::lowestSecondaryEnergy
G4double lowestSecondaryEnergy
Definition: G4KleinNishinaCompton.hh:93

G4DynamicParticle::SetPolarization
void SetPolarization(G4double polX, G4double polY, G4double polZ)

G4Log.hh

G4PolarizedComptonCrossSection::GetPol2
G4StokesVector GetPol2() override
Definition: G4PolarizedComptonCrossSection.cc:214

G4Exception
void G4Exception(const char *originOfException, const char *exceptionCode, G4ExceptionSeverity severity, const char *comments)
Definition: G4Exception.cc:41

G4PhysicalConstants.hh

emax
static const G4double emax
Definition: G4ChatterjeeCrossSection.hh:39

G4Log
G4double G4Log(G4double x)
Definition: G4Log.hh:230

G4Exp
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
Definition: G4Exp.hh:183

G4StokesVector::InvRotateAz
void InvRotateAz(G4ThreeVector nInteractionFrame, G4ThreeVector particleDirection)
Definition: G4StokesVector.cc:108

G4Electron.hh

G4VPhysicalVolume::GetLogicalVolume
G4LogicalVolume * GetLogicalVolume() const

sss
static const char sss[MAX_N_PAR+2]
Definition: Evaluator.cc:64

G4PolarizedComptonModel.hh

G4PolarizedComptonModel::ComputeAsymmetryPerAtom
G4double ComputeAsymmetryPerAtom(G4double gammaEnergy, G4double Z)
Definition: G4PolarizedComptonModel.cc:88

G4PolarizedComptonCrossSection
Definition: G4PolarizedComptonCrossSection.hh:57

CLHEP::Hep3Vector::unit
Hep3Vector unit() const

G4StokesVector::SetPhoton
void SetPhoton()
Definition: G4StokesVector.hh:92

G4PolarizationManager::IsPolarized
bool IsPolarized(G4LogicalVolume *lVol) const
Definition: G4PolarizationManager.hh:107

CLHEP::HepRandomEngine
Definition: RandomEngine.h:54

G4DynamicParticle::GetPolarization
const G4ThreeVector & GetPolarization() const

fStopAndKill
Definition: G4TrackStatus.hh:56

G4PolarizedComptonModel::~G4PolarizedComptonModel
virtual ~G4PolarizedComptonModel()
Definition: G4PolarizedComptonModel.cc:82

G4Track
Definition: G4Track.hh:76

G4Track::GetVolume
G4VPhysicalVolume * GetVolume() const

G4ParticleChangeForGamma::GetCurrentTrack
const G4Track * GetCurrentTrack() const
Definition: G4ParticleChangeForGamma.hh:154

G4ParticleChangeForGamma::SetProposedKineticEnergy
void SetProposedKineticEnergy(G4double proposedKinEnergy)
Definition: G4ParticleChangeForGamma.hh:129

G4endl
#define G4endl
Definition: G4ios.hh:61

MeV
static constexpr double MeV
Definition: G4SIunits.hh:214

G4PolarizedComptonCrossSection::Initialize
virtual void Initialize(G4double eps, G4double X, G4double phi, const G4StokesVector &p0, const G4StokesVector &p1, G4int flag=0) override
Definition: G4PolarizedComptonCrossSection.cc:74

G4KleinNishinaCompton::theElectron
G4ParticleDefinition * theElectron
Definition: G4KleinNishinaCompton.hh:91

sqr
T sqr(const T &x)
Definition: templates.hh:145

G4LogicalVolume::GetName
const G4String & GetName() const

G4double
double G4double
Definition: G4Types.hh:76

G4VParticleChange::ProposeTrackStatus
void ProposeTrackStatus(G4TrackStatus status)

G4SystemOfUnits.hh

G4DataVector.hh

CLHEP::HepRandomEngine::flatArray
virtual void flatArray(const int size, double *vect)=0

CLHEP::Hep3Vector::mag
double mag() const

G4PolarizationManager::GetVolumePolarization
const G4ThreeVector & GetVolumePolarization(G4LogicalVolume *lVol) const
Definition: G4PolarizationManager.hh:97

epsilon
double epsilon(double density, double temperature)
Definition: G4DNAElectronHoleRecombination.cc:96

G4StokesVector::RotateAz
void RotateAz(G4ThreeVector nInteractionFrame, G4ThreeVector particleDirection)
Definition: G4StokesVector.cc:71

Z
G4int Z
Definition: G4ParticleHPJENDLHEData.cc:262

G4Gamma.hh

G4PolarizedComptonModel::ComputeCrossSectionPerAtom
virtual G4double ComputeCrossSectionPerAtom(const G4ParticleDefinition *, G4double kinEnergy, G4double Z, G4double A, G4double cut, G4double emax) override
Definition: G4PolarizedComptonModel.cc:107

G4String
Definition: G4String.hh:45