Geant4 Cross Reference

Cross-Referencing   Geant4
Geant4/processes/electromagnetic/polarisation/src/G4PolarizedComptonModel.cc

Version: [ ReleaseNotes ] [ 1.0 ] [ 1.1 ] [ 2.0 ] [ 3.0 ] [ 3.1 ] [ 3.2 ] [ 4.0 ] [ 4.0.p1 ] [ 4.0.p2 ] [ 4.1 ] [ 4.1.p1 ] [ 5.0 ] [ 5.0.p1 ] [ 5.1 ] [ 5.1.p1 ] [ 5.2 ] [ 5.2.p1 ] [ 5.2.p2 ] [ 6.0 ] [ 6.0.p1 ] [ 6.1 ] [ 6.2 ] [ 6.2.p1 ] [ 6.2.p2 ] [ 7.0 ] [ 7.0.p1 ] [ 7.1 ] [ 7.1.p1 ] [ 8.0 ] [ 8.0.p1 ] [ 8.1 ] [ 8.1.p1 ] [ 8.1.p2 ] [ 8.2 ] [ 8.2.p1 ] [ 8.3 ] [ 8.3.p1 ] [ 8.3.p2 ] [ 9.0 ] [ 9.0.p1 ] [ 9.0.p2 ] [ 9.1 ] [ 9.1.p1 ] [ 9.1.p2 ] [ 9.1.p3 ] [ 9.2 ] [ 9.2.p1 ] [ 9.2.p2 ] [ 9.2.p3 ] [ 9.2.p4 ] [ 9.3 ] [ 9.3.p1 ] [ 9.3.p2 ] [ 9.4 ] [ 9.4.p1 ] [ 9.4.p2 ] [ 9.4.p3 ] [ 9.4.p4 ] [ 9.5 ] [ 9.5.p1 ] [ 9.5.p2 ] [ 9.6 ] [ 9.6.p1 ] [ 9.6.p2 ] [ 9.6.p3 ] [ 9.6.p4 ] [ 10.0 ] [ 10.0.p1 ] [ 10.0.p2 ] [ 10.0.p3 ] [ 10.0.p4 ] [ 10.1 ] [ 10.1.p1 ] [ 10.1.p2 ] [ 10.1.p3 ] [ 10.2 ] [ 10.2.p1 ] [ 10.2.p2 ] [ 10.2.p3 ] [ 10.3 ] [ 10.3.p1 ] [ 10.3.p2 ] [ 10.3.p3 ] [ 10.4 ] [ 10.4.p1 ] [ 10.4.p2 ] [ 10.4.p3 ] [ 10.5 ] [ 10.5.p1 ] [ 10.6 ] [ 10.6.p1 ] [ 10.6.p2 ] [ 10.6.p3 ] [ 10.7 ] [ 10.7.p1 ] [ 10.7.p2 ] [ 10.7.p3 ] [ 10.7.p4 ] [ 11.0 ] [ 11.0.p1 ] [ 11.0.p2 ] [ 11.0.p3, ] [ 11.0.p4 ] [ 11.1 ] [ 11.1.1 ] [ 11.1.2 ] [ 11.1.3 ] [ 11.2 ] [ 11.2.1 ] [ 11.2.2 ] [ 11.3.0 ]

Diff markup

Differences between /processes/electromagnetic/polarisation/src/G4PolarizedComptonModel.cc (Version 11.3.0) and /processes/electromagnetic/polarisation/src/G4PolarizedComptonModel.cc (Version 11.1.1)


  1 //                                                  1 //
  2 // *******************************************      2 // ********************************************************************
  3 // * License and Disclaimer                         3 // * License and Disclaimer                                           *
  4 // *                                                4 // *                                                                  *
  5 // * The  Geant4 software  is  copyright of th      5 // * The  Geant4 software  is  copyright of the Copyright Holders  of *
  6 // * the Geant4 Collaboration.  It is provided      6 // * the Geant4 Collaboration.  It is provided  under  the terms  and *
  7 // * conditions of the Geant4 Software License      7 // * conditions of the Geant4 Software License,  included in the file *
  8 // * LICENSE and available at  http://cern.ch/      8 // * LICENSE and available at  http://cern.ch/geant4/license .  These *
  9 // * include a list of copyright holders.           9 // * include a list of copyright holders.                             *
 10 // *                                               10 // *                                                                  *
 11 // * Neither the authors of this software syst     11 // * Neither the authors of this software system, nor their employing *
 12 // * institutes,nor the agencies providing fin     12 // * institutes,nor the agencies providing financial support for this *
 13 // * work  make  any representation or  warran     13 // * work  make  any representation or  warranty, express or implied, *
 14 // * regarding  this  software system or assum     14 // * regarding  this  software system or assume any liability for its *
 15 // * use.  Please see the license in the file      15 // * use.  Please see the license in the file  LICENSE  and URL above *
 16 // * for the full disclaimer and the limitatio     16 // * for the full disclaimer and the limitation of liability.         *
 17 // *                                               17 // *                                                                  *
 18 // * This  code  implementation is the result      18 // * This  code  implementation is the result of  the  scientific and *
 19 // * technical work of the GEANT4 collaboratio     19 // * technical work of the GEANT4 collaboration.                      *
 20 // * By using,  copying,  modifying or  distri     20 // * By using,  copying,  modifying or  distributing the software (or *
 21 // * any work based  on the software)  you  ag     21 // * any work based  on the software)  you  agree  to acknowledge its *
 22 // * use  in  resulting  scientific  publicati     22 // * use  in  resulting  scientific  publications,  and indicate your *
 23 // * acceptance of all terms of the Geant4 Sof     23 // * acceptance of all terms of the Geant4 Software license.          *
 24 // *******************************************     24 // ********************************************************************
 25 //                                                 25 //
 26 // -------------------------------------------     26 // -------------------------------------------------------------------
 27 //                                                 27 //
 28 // Geant4 Class file                               28 // Geant4 Class file
 29 //                                                 29 //
 30 // File name:     G4PolarizedComptonModel          30 // File name:     G4PolarizedComptonModel
 31 //                                                 31 //
 32 // Author:        Andreas Schaelicke               32 // Author:        Andreas Schaelicke
 33                                                    33 
 34 #include "G4PolarizedComptonModel.hh"              34 #include "G4PolarizedComptonModel.hh"
 35                                                    35 
 36 #include "G4Exp.hh"                                36 #include "G4Exp.hh"
 37 #include "G4Log.hh"                                37 #include "G4Log.hh"
 38 #include "G4ParticleChangeForGamma.hh"             38 #include "G4ParticleChangeForGamma.hh"
 39 #include "G4PhysicalConstants.hh"                  39 #include "G4PhysicalConstants.hh"
 40 #include "G4PolarizationManager.hh"                40 #include "G4PolarizationManager.hh"
 41 #include "G4PolarizationHelper.hh"                 41 #include "G4PolarizationHelper.hh"
 42 #include "G4PolarizedComptonXS.hh"                 42 #include "G4PolarizedComptonXS.hh"
 43 #include "G4StokesVector.hh"                       43 #include "G4StokesVector.hh"
 44 #include "G4SystemOfUnits.hh"                      44 #include "G4SystemOfUnits.hh"
 45                                                    45 
 46 //....oooOO0OOooo........oooOO0OOooo........oo     46 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 47 G4PolarizedComptonModel::G4PolarizedComptonMod     47 G4PolarizedComptonModel::G4PolarizedComptonModel(const G4ParticleDefinition*,
 48                                                    48                                                  const G4String& nam)
 49   : G4KleinNishinaCompton(nullptr, nam)            49   : G4KleinNishinaCompton(nullptr, nam)
 50   , fVerboseLevel(0)                               50   , fVerboseLevel(0)
 51 {                                                  51 {
 52   fCrossSectionCalculator = new G4PolarizedCom     52   fCrossSectionCalculator = new G4PolarizedComptonXS();
 53   fBeamPolarization       = G4StokesVector::ZE     53   fBeamPolarization       = G4StokesVector::ZERO;
 54   fTargetPolarization     = G4StokesVector::ZE     54   fTargetPolarization     = G4StokesVector::ZERO;
 55 }                                                  55 }
 56                                                    56 
 57 //....oooOO0OOooo........oooOO0OOooo........oo     57 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 58 G4PolarizedComptonModel::~G4PolarizedComptonMo     58 G4PolarizedComptonModel::~G4PolarizedComptonModel()
 59 {                                                  59 {
 60   delete fCrossSectionCalculator;                  60   delete fCrossSectionCalculator;
 61 }                                                  61 }
 62                                                    62 
 63 //....oooOO0OOooo........oooOO0OOooo........oo     63 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 64 G4double G4PolarizedComptonModel::ComputeAsymm     64 G4double G4PolarizedComptonModel::ComputeAsymmetryPerAtom(G4double gammaEnergy,
 65                                                    65                                                           G4double /*Z*/)
 66 {                                                  66 {
 67   G4double asymmetry = 0.0;                        67   G4double asymmetry = 0.0;
 68                                                    68 
 69   G4double k0 = gammaEnergy / electron_mass_c2     69   G4double k0 = gammaEnergy / electron_mass_c2;
 70   G4double k1 = 1. + 2. * k0;                      70   G4double k1 = 1. + 2. * k0;
 71                                                    71 
 72   asymmetry = -k0;                                 72   asymmetry = -k0;
 73   asymmetry *=                                     73   asymmetry *=
 74     (k0 + 1.) * sqr(k1) * G4Log(k1) - 2. * k0      74     (k0 + 1.) * sqr(k1) * G4Log(k1) - 2. * k0 * (5. * sqr(k0) + 4. * k0 + 1.);
 75   asymmetry /= ((k0 - 2.) * k0 - 2.) * sqr(k1)     75   asymmetry /= ((k0 - 2.) * k0 - 2.) * sqr(k1) * G4Log(k1) +
 76                2. * k0 * (k0 * (k0 + 1.) * (k0     76                2. * k0 * (k0 * (k0 + 1.) * (k0 + 8.) + 2.);
 77                                                    77 
 78   if(asymmetry > 1.)                               78   if(asymmetry > 1.)
 79   {                                                79   {
 80     G4ExceptionDescription ed;                     80     G4ExceptionDescription ed;
 81     ed << "ERROR in G4PolarizedComptonModel::C     81     ed << "ERROR in G4PolarizedComptonModel::ComputeAsymmetryPerAtom.\n"
 82        << " asymmetry = " << asymmetry << "\n"     82        << " asymmetry = " << asymmetry << "\n";
 83     G4Exception("G4PolarizedComptonModel::Comp     83     G4Exception("G4PolarizedComptonModel::ComputeAsymmetryPerAtom", "pol035",
 84                 JustWarning, ed);                  84                 JustWarning, ed);
 85   }                                                85   }
 86                                                    86 
 87   return asymmetry;                                87   return asymmetry;
 88 }                                                  88 }
 89                                                    89 
 90 //....oooOO0OOooo........oooOO0OOooo........oo     90 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 91 G4double G4PolarizedComptonModel::ComputeCross     91 G4double G4PolarizedComptonModel::ComputeCrossSectionPerAtom(
 92   const G4ParticleDefinition* pd, G4double kin     92   const G4ParticleDefinition* pd, G4double kinEnergy, G4double Z, G4double A,
 93   G4double cut, G4double emax)                     93   G4double cut, G4double emax)
 94 {                                                  94 {
 95   G4double xs = G4KleinNishinaCompton::Compute     95   G4double xs = G4KleinNishinaCompton::ComputeCrossSectionPerAtom(
 96     pd, kinEnergy, Z, A, cut, emax);               96     pd, kinEnergy, Z, A, cut, emax);
 97   G4double polzz = fBeamPolarization.p3() * fT     97   G4double polzz = fBeamPolarization.p3() * fTargetPolarization.z();
 98   if(polzz > 0.0)                                  98   if(polzz > 0.0)
 99   {                                                99   {
100     G4double asym = ComputeAsymmetryPerAtom(ki    100     G4double asym = ComputeAsymmetryPerAtom(kinEnergy, Z);
101     xs *= (1. + polzz * asym);                    101     xs *= (1. + polzz * asym);
102   }                                               102   }
103   return xs;                                      103   return xs;
104 }                                                 104 }
105                                                   105 
106 //....oooOO0OOooo........oooOO0OOooo........oo    106 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
107 void G4PolarizedComptonModel::SampleSecondarie    107 void G4PolarizedComptonModel::SampleSecondaries(
108   std::vector<G4DynamicParticle*>* fvect, cons    108   std::vector<G4DynamicParticle*>* fvect, const G4MaterialCutsCouple*,
109   const G4DynamicParticle* aDynamicGamma, G4do    109   const G4DynamicParticle* aDynamicGamma, G4double, G4double)
110 {                                                 110 {
111   // do nothing below the threshold               111   // do nothing below the threshold
112   if(aDynamicGamma->GetKineticEnergy() <= LowE    112   if(aDynamicGamma->GetKineticEnergy() <= LowEnergyLimit())
113   {                                               113   {
114     return;                                       114     return;
115   }                                               115   }
116                                                   116 
117   const G4Track* aTrack       = fParticleChang    117   const G4Track* aTrack       = fParticleChange->GetCurrentTrack();
118   G4VPhysicalVolume* aPVolume = aTrack->GetVol    118   G4VPhysicalVolume* aPVolume = aTrack->GetVolume();
119   G4LogicalVolume* aLVolume   = aPVolume->GetL    119   G4LogicalVolume* aLVolume   = aPVolume->GetLogicalVolume();
120                                                   120 
121   if(fVerboseLevel >= 1)                          121   if(fVerboseLevel >= 1)
122   {                                               122   {
123     G4cout << "G4PolarizedComptonModel::Sample    123     G4cout << "G4PolarizedComptonModel::SampleSecondaries in "
124            << aLVolume->GetName() << G4endl;      124            << aLVolume->GetName() << G4endl;
125   }                                               125   }
126   G4PolarizationManager* polarizationManager =    126   G4PolarizationManager* polarizationManager =
127     G4PolarizationManager::GetInstance();         127     G4PolarizationManager::GetInstance();
128                                                   128 
129   // obtain polarization of the beam              129   // obtain polarization of the beam
130   fBeamPolarization = G4StokesVector(aDynamicG    130   fBeamPolarization = G4StokesVector(aDynamicGamma->GetPolarization());
131   fBeamPolarization.SetPhoton();                  131   fBeamPolarization.SetPhoton();
132                                                   132 
133   // obtain polarization of the media             133   // obtain polarization of the media
134   G4bool targetIsPolarized = polarizationManag    134   G4bool targetIsPolarized = polarizationManager->IsPolarized(aLVolume);
135   fTargetPolarization = polarizationManager->G    135   fTargetPolarization = polarizationManager->GetVolumePolarization(aLVolume);
136                                                   136 
137   // if beam is linear polarized or target is     137   // if beam is linear polarized or target is transversely polarized
138   // determine the angle to x-axis                138   // determine the angle to x-axis
139   // (assumes same PRF as in the polarization     139   // (assumes same PRF as in the polarization definition)
140   G4ThreeVector gamDirection0 = aDynamicGamma-    140   G4ThreeVector gamDirection0 = aDynamicGamma->GetMomentumDirection();
141                                                   141 
142   // transfer fTargetPolarization                 142   // transfer fTargetPolarization
143   // into the gamma frame (problem electron is    143   // into the gamma frame (problem electron is at rest)
144   if(targetIsPolarized)                           144   if(targetIsPolarized)
145   {                                               145   {
146     fTargetPolarization.rotateUz(gamDirection0    146     fTargetPolarization.rotateUz(gamDirection0);
147   }                                               147   }
148   // The scattered gamma energy is sampled acc    148   // The scattered gamma energy is sampled according to
149   // Klein - Nishina formula.                     149   // Klein - Nishina formula.
150   // The random number techniques of Butcher &    150   // The random number techniques of Butcher & Messel are used
151   // (Nuc Phys 20(1960),15).                      151   // (Nuc Phys 20(1960),15).
152   // Note : Effects due to binding of atomic e    152   // Note : Effects due to binding of atomic electrons are neglected.
153                                                   153 
154   G4double gamEnergy0 = aDynamicGamma->GetKine    154   G4double gamEnergy0 = aDynamicGamma->GetKineticEnergy();
155   G4double E0_m       = gamEnergy0 / electron_    155   G4double E0_m       = gamEnergy0 / electron_mass_c2;
156                                                   156 
157   // sample the energy rate of the scattered g    157   // sample the energy rate of the scattered gamma
158   G4double epsilon, sint2;                        158   G4double epsilon, sint2;
159   G4double onecost = 0.0;                         159   G4double onecost = 0.0;
160   G4double Phi     = 0.0;                         160   G4double Phi     = 0.0;
161   G4double greject = 1.0;                         161   G4double greject = 1.0;
162   G4double cosTeta = 1.0;                         162   G4double cosTeta = 1.0;
163   G4double sinTeta = 0.0;                         163   G4double sinTeta = 0.0;
164                                                   164 
165   G4double eps0       = 1. / (1. + 2. * E0_m);    165   G4double eps0       = 1. / (1. + 2. * E0_m);
166   G4double epsilon0sq = eps0 * eps0;              166   G4double epsilon0sq = eps0 * eps0;
167   G4double alpha1     = -G4Log(eps0);             167   G4double alpha1     = -G4Log(eps0);
168   G4double alpha2     = alpha1 + 0.5 * (1. - e    168   G4double alpha2     = alpha1 + 0.5 * (1. - epsilon0sq);
169                                                   169 
170   G4double polarization = fBeamPolarization.p3    170   G4double polarization = fBeamPolarization.p3() * fTargetPolarization.p3();
171                                                   171 
172   CLHEP::HepRandomEngine* rndmEngineMod = G4Ra    172   CLHEP::HepRandomEngine* rndmEngineMod = G4Random::getTheEngine();
173   G4int nloop                           = 0;      173   G4int nloop                           = 0;
174   G4bool end                            = fals    174   G4bool end                            = false;
175                                                   175 
176   G4double rndm[3];                               176   G4double rndm[3];
177                                                   177 
178   do                                              178   do
179   {                                               179   {
180     do                                            180     do
181     {                                             181     {
182       ++nloop;                                    182       ++nloop;
183       // false interaction if too many iterati    183       // false interaction if too many iterations
184       if(nloop > fLoopLim)                        184       if(nloop > fLoopLim)
185       {                                           185       {
186         PrintWarning(aDynamicGamma, nloop, gre    186         PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,
187                      "too many iterations");      187                      "too many iterations");
188         return;                                   188         return;
189       }                                           189       }
190                                                   190 
191       // 3 random numbers to sample scattering    191       // 3 random numbers to sample scattering
192       rndmEngineMod->flatArray(3, rndm);          192       rndmEngineMod->flatArray(3, rndm);
193                                                   193 
194       if(alpha1 > alpha2 * rndm[0])               194       if(alpha1 > alpha2 * rndm[0])
195       {                                           195       {
196         epsilon = G4Exp(-alpha1 * rndm[1]);       196         epsilon = G4Exp(-alpha1 * rndm[1]);
197       }                                           197       }
198       else                                        198       else
199       {                                           199       {
200         epsilon = std::sqrt(epsilon0sq + (1. -    200         epsilon = std::sqrt(epsilon0sq + (1. - epsilon0sq) * rndm[1]);
201       }                                           201       }
202                                                   202 
203       onecost = (1. - epsilon) / (epsilon * E0    203       onecost = (1. - epsilon) / (epsilon * E0_m);
204       sint2   = onecost * (2. - onecost);         204       sint2   = onecost * (2. - onecost);
205                                                   205 
206       G4double gdiced = 2. * (1. / epsilon + e    206       G4double gdiced = 2. * (1. / epsilon + epsilon);
207       G4double gdist  = 1. / epsilon + epsilon    207       G4double gdist  = 1. / epsilon + epsilon - sint2 -
208                        polarization * (1. / ep    208                        polarization * (1. / epsilon - epsilon) * (1. - onecost);
209                                                   209 
210       greject = gdist / gdiced;                   210       greject = gdist / gdiced;
211                                                   211 
212       if(greject > 1.0)                           212       if(greject > 1.0)
213       {                                           213       {
214         PrintWarning(aDynamicGamma, nloop, gre    214         PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,
215                      "theta majoranta wrong");    215                      "theta majoranta wrong");
216       }                                           216       }
217       // Loop checking, 03-Aug-2015, Vladimir     217       // Loop checking, 03-Aug-2015, Vladimir Ivanchenko
218     } while(greject < rndm[2]);                   218     } while(greject < rndm[2]);
219                                                   219 
220     // assuming phi loop successful               220     // assuming phi loop successful
221     end = true;                                   221     end = true;
222                                                   222 
223     // scattered gamma angles. ( Z - axis alon    223     // scattered gamma angles. ( Z - axis along the parent gamma)
224     cosTeta = 1. - onecost;                       224     cosTeta = 1. - onecost;
225     sinTeta = std::sqrt(sint2);                   225     sinTeta = std::sqrt(sint2);
226     do                                            226     do
227     {                                             227     {
228       ++nloop;                                    228       ++nloop;
229                                                   229 
230       // 2 random numbers to sample scattering    230       // 2 random numbers to sample scattering
231       rndmEngineMod->flatArray(2, rndm);          231       rndmEngineMod->flatArray(2, rndm);
232                                                   232 
233       // false interaction if too many iterati    233       // false interaction if too many iterations
234       Phi = twopi * rndm[0];                      234       Phi = twopi * rndm[0];
235       if(nloop > fLoopLim)                        235       if(nloop > fLoopLim)
236       {                                           236       {
237         PrintWarning(aDynamicGamma, nloop, gre    237         PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,
238                      "too many iterations");      238                      "too many iterations");
239         return;                                   239         return;
240       }                                           240       }
241                                                   241 
242       G4double gdiced = 1. / epsilon + epsilon    242       G4double gdiced = 1. / epsilon + epsilon - sint2 +
243                         std::abs(fBeamPolariza    243                         std::abs(fBeamPolarization.p3()) *
244                           (std::abs((1. / epsi    244                           (std::abs((1. / epsilon - epsilon) * cosTeta *
245                                     fTargetPol    245                                     fTargetPolarization.p3()) +
246                            (1. - epsilon) * si    246                            (1. - epsilon) * sinTeta *
247                              (std::sqrt(sqr(fT    247                              (std::sqrt(sqr(fTargetPolarization.p1()) +
248                                         sqr(fT    248                                         sqr(fTargetPolarization.p2())))) +
249                         sint2 * (std::sqrt(sqr    249                         sint2 * (std::sqrt(sqr(fBeamPolarization.p1()) +
250                                            sqr    250                                            sqr(fBeamPolarization.p2())));
251                                                   251 
252       G4double gdist =                            252       G4double gdist =
253         1. / epsilon + epsilon - sint2 +          253         1. / epsilon + epsilon - sint2 +
254         fBeamPolarization.p3() *                  254         fBeamPolarization.p3() *
255           ((1. / epsilon - epsilon) * cosTeta     255           ((1. / epsilon - epsilon) * cosTeta * fTargetPolarization.p3() +
256            (1. - epsilon) * sinTeta *             256            (1. - epsilon) * sinTeta *
257              (std::cos(Phi) * fTargetPolarizat    257              (std::cos(Phi) * fTargetPolarization.p1() +
258               std::sin(Phi) * fTargetPolarizat    258               std::sin(Phi) * fTargetPolarization.p2())) -
259         sint2 * (std::cos(2. * Phi) * fBeamPol    259         sint2 * (std::cos(2. * Phi) * fBeamPolarization.p1() +
260                  std::sin(2. * Phi) * fBeamPol    260                  std::sin(2. * Phi) * fBeamPolarization.p2());
261       greject = gdist / gdiced;                   261       greject = gdist / gdiced;
262                                                   262 
263       if(greject > 1.0)                           263       if(greject > 1.0)
264       {                                           264       {
265         PrintWarning(aDynamicGamma, nloop, gre    265         PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,
266                      "phi majoranta wrong");      266                      "phi majoranta wrong");
267       }                                           267       }
268                                                   268 
269       if(greject < 1.e-3)                         269       if(greject < 1.e-3)
270       {                                           270       {
271         PrintWarning(aDynamicGamma, nloop, gre    271         PrintWarning(aDynamicGamma, nloop, greject, onecost, Phi,
272                      "phi loop ineffective");     272                      "phi loop ineffective");
273         // restart theta loop                     273         // restart theta loop
274         end = false;                              274         end = false;
275         break;                                    275         break;
276       }                                           276       }
277                                                   277 
278       // Loop checking, 03-Aug-2015, Vladimir     278       // Loop checking, 03-Aug-2015, Vladimir Ivanchenko
279     } while(greject < rndm[1]);                   279     } while(greject < rndm[1]);
280   } while(!end);                                  280   } while(!end);
281   G4double dirx = sinTeta * std::cos(Phi);        281   G4double dirx = sinTeta * std::cos(Phi);
282   G4double diry = sinTeta * std::sin(Phi);        282   G4double diry = sinTeta * std::sin(Phi);
283   G4double dirz = cosTeta;                        283   G4double dirz = cosTeta;
284                                                   284 
285   // update G4VParticleChange for the scattere    285   // update G4VParticleChange for the scattered gamma
286   G4ThreeVector gamDirection1(dirx, diry, dirz    286   G4ThreeVector gamDirection1(dirx, diry, dirz);
287   gamDirection1.rotateUz(gamDirection0);          287   gamDirection1.rotateUz(gamDirection0);
288   G4double gamEnergy1 = epsilon * gamEnergy0;     288   G4double gamEnergy1 = epsilon * gamEnergy0;
289                                                   289 
290   G4double edep = 0.0;                            290   G4double edep = 0.0;
291   if(gamEnergy1 > lowestSecondaryEnergy)          291   if(gamEnergy1 > lowestSecondaryEnergy)
292   {                                               292   {
293     fParticleChange->ProposeMomentumDirection(    293     fParticleChange->ProposeMomentumDirection(gamDirection1);
294     fParticleChange->SetProposedKineticEnergy(    294     fParticleChange->SetProposedKineticEnergy(gamEnergy1);
295   }                                               295   }
296   else                                            296   else
297   {                                               297   {
298     fParticleChange->ProposeTrackStatus(fStopA    298     fParticleChange->ProposeTrackStatus(fStopAndKill);
299     fParticleChange->SetProposedKineticEnergy(    299     fParticleChange->SetProposedKineticEnergy(0.0);
300     edep = gamEnergy1;                            300     edep = gamEnergy1;
301   }                                               301   }
302                                                   302 
303   // calculate Stokes vector of final state ph    303   // calculate Stokes vector of final state photon and electron
304   G4ThreeVector nInteractionFrame =               304   G4ThreeVector nInteractionFrame =
305     G4PolarizationHelper::GetFrame(gamDirectio    305     G4PolarizationHelper::GetFrame(gamDirection1, gamDirection0);
306                                                   306 
307   // transfer fBeamPolarization and fTargetPol    307   // transfer fBeamPolarization and fTargetPolarization
308   // into the interaction frame (note electron    308   // into the interaction frame (note electron is in gamma frame)
309   if(fVerboseLevel >= 1)                          309   if(fVerboseLevel >= 1)
310   {                                               310   {
311     G4cout << "===============================    311     G4cout << "========================================" << G4endl;
312     G4cout << " nInteractionFrame = " << nInte    312     G4cout << " nInteractionFrame = " << nInteractionFrame << G4endl;
313     G4cout << " GammaDirection0 = " << gamDire    313     G4cout << " GammaDirection0 = " << gamDirection0 << G4endl;
314     G4cout << " gammaPolarization = " << fBeam    314     G4cout << " gammaPolarization = " << fBeamPolarization << G4endl;
315     G4cout << " electronPolarization = " << fT    315     G4cout << " electronPolarization = " << fTargetPolarization << G4endl;
316   }                                               316   }
317                                                   317 
318   fBeamPolarization.InvRotateAz(nInteractionFr    318   fBeamPolarization.InvRotateAz(nInteractionFrame, gamDirection0);
319   fTargetPolarization.InvRotateAz(nInteraction    319   fTargetPolarization.InvRotateAz(nInteractionFrame, gamDirection0);
320                                                   320 
321   if(fVerboseLevel >= 1)                          321   if(fVerboseLevel >= 1)
322   {                                               322   {
323     G4cout << "-------------------------------    323     G4cout << "----------------------------------------" << G4endl;
324     G4cout << " gammaPolarization = " << fBeam    324     G4cout << " gammaPolarization = " << fBeamPolarization << G4endl;
325     G4cout << " electronPolarization = " << fT    325     G4cout << " electronPolarization = " << fTargetPolarization << G4endl;
326     G4cout << "-------------------------------    326     G4cout << "----------------------------------------" << G4endl;
327   }                                               327   }
328                                                   328 
329   // initialize the polarization transfer matr    329   // initialize the polarization transfer matrix
330   fCrossSectionCalculator->Initialize(epsilon,    330   fCrossSectionCalculator->Initialize(epsilon, E0_m, 0., fBeamPolarization,
331                                       fTargetP    331                                       fTargetPolarization, 2);
332                                                   332 
333   if(gamEnergy1 > lowestSecondaryEnergy)          333   if(gamEnergy1 > lowestSecondaryEnergy)
334   {                                               334   {
335     // in interaction frame                       335     // in interaction frame
336     // calculate polarization transfer to the     336     // calculate polarization transfer to the photon (in interaction plane)
337     fFinalGammaPolarization = fCrossSectionCal    337     fFinalGammaPolarization = fCrossSectionCalculator->GetPol2();
338     if(fVerboseLevel >= 1)                        338     if(fVerboseLevel >= 1)
339     {                                             339     {
340       G4cout << " gammaPolarization1 = " << fF    340       G4cout << " gammaPolarization1 = " << fFinalGammaPolarization << G4endl;
341     }                                             341     }
342     fFinalGammaPolarization.SetPhoton();          342     fFinalGammaPolarization.SetPhoton();
343                                                   343 
344     // translate polarization into particle re    344     // translate polarization into particle reference frame
345     fFinalGammaPolarization.RotateAz(nInteract    345     fFinalGammaPolarization.RotateAz(nInteractionFrame, gamDirection1);
346     if(fFinalGammaPolarization.mag() > 1. + 1.    346     if(fFinalGammaPolarization.mag() > 1. + 1.e-8)
347     {                                             347     {
348       G4ExceptionDescription ed;                  348       G4ExceptionDescription ed;
349       ed << "ERROR in Polarizaed Compton Scatt    349       ed << "ERROR in Polarizaed Compton Scattering !\n";
350       ed << "Polarization of final photon more    350       ed << "Polarization of final photon more than 100%.\n";
351       ed << fFinalGammaPolarization               351       ed << fFinalGammaPolarization
352          << " mag = " << fFinalGammaPolarizati    352          << " mag = " << fFinalGammaPolarization.mag() << "\n";
353       G4Exception("G4PolarizedComptonModel::Sa    353       G4Exception("G4PolarizedComptonModel::SampleSecondaries", "pol033",
354                   FatalException, ed);            354                   FatalException, ed);
355     }                                             355     }
356     // store polarization vector                  356     // store polarization vector
357     fParticleChange->ProposePolarization(fFina    357     fParticleChange->ProposePolarization(fFinalGammaPolarization);
358     if(fVerboseLevel >= 1)                        358     if(fVerboseLevel >= 1)
359     {                                             359     {
360       G4cout << " gammaPolarization1 = " << fF    360       G4cout << " gammaPolarization1 = " << fFinalGammaPolarization << G4endl;
361       G4cout << " GammaDirection1 = " << gamDi    361       G4cout << " GammaDirection1 = " << gamDirection1 << G4endl;
362     }                                             362     }
363   }                                               363   }
364                                                   364 
365   // kinematic of the scattered electron          365   // kinematic of the scattered electron
366   G4double eKinEnergy = gamEnergy0 - gamEnergy    366   G4double eKinEnergy = gamEnergy0 - gamEnergy1;
367                                                   367 
368   if(eKinEnergy > lowestSecondaryEnergy)          368   if(eKinEnergy > lowestSecondaryEnergy)
369   {                                               369   {
370     G4ThreeVector eDirection =                    370     G4ThreeVector eDirection =
371       gamEnergy0 * gamDirection0 - gamEnergy1     371       gamEnergy0 * gamDirection0 - gamEnergy1 * gamDirection1;
372     eDirection = eDirection.unit();               372     eDirection = eDirection.unit();
373                                                   373 
374     finalElectronPolarization = fCrossSectionC    374     finalElectronPolarization = fCrossSectionCalculator->GetPol3();
375     if(fVerboseLevel >= 1)                        375     if(fVerboseLevel >= 1)
376     {                                             376     {
377       G4cout << " electronPolarization1 = " <<    377       G4cout << " electronPolarization1 = " << finalElectronPolarization
378              << G4endl;                           378              << G4endl;
379     }                                             379     }
380     // transfer into particle reference frame     380     // transfer into particle reference frame
381     finalElectronPolarization.RotateAz(nIntera    381     finalElectronPolarization.RotateAz(nInteractionFrame, eDirection);
382     if(fVerboseLevel >= 1)                        382     if(fVerboseLevel >= 1)
383     {                                             383     {
384       G4cout << " electronPolarization1 = " <<    384       G4cout << " electronPolarization1 = " << finalElectronPolarization
385              << G4endl << " ElecDirection = "     385              << G4endl << " ElecDirection = " << eDirection << G4endl;
386     }                                             386     }
387                                                   387 
388     // create G4DynamicParticle object for the    388     // create G4DynamicParticle object for the electron.
389     G4DynamicParticle* aElectron =                389     G4DynamicParticle* aElectron =
390       new G4DynamicParticle(theElectron, eDire    390       new G4DynamicParticle(theElectron, eDirection, eKinEnergy);
391     // store polarization vector                  391     // store polarization vector
392     if(finalElectronPolarization.mag() > 1. +     392     if(finalElectronPolarization.mag() > 1. + 1.e-8)
393     {                                             393     {
394       G4ExceptionDescription ed;                  394       G4ExceptionDescription ed;
395       ed << "ERROR in Polarized Compton Scatte    395       ed << "ERROR in Polarized Compton Scattering !\n";
396       ed << "Polarization of final electron mo    396       ed << "Polarization of final electron more than 100%.\n";
397       ed << finalElectronPolarization             397       ed << finalElectronPolarization
398          << " mag = " << finalElectronPolariza    398          << " mag = " << finalElectronPolarization.mag() << G4endl;
399       G4Exception("G4PolarizedComptonModel::Sa    399       G4Exception("G4PolarizedComptonModel::SampleSecondaries", "pol034",
400                   FatalException, ed);            400                   FatalException, ed);
401     }                                             401     }
402     aElectron->SetPolarization(finalElectronPo    402     aElectron->SetPolarization(finalElectronPolarization.p1(),
403                                finalElectronPo    403                                finalElectronPolarization.p2(),
404                                finalElectronPo    404                                finalElectronPolarization.p3());
405     fvect->push_back(aElectron);                  405     fvect->push_back(aElectron);
406   }                                               406   }
407   else                                            407   else
408   {                                               408   {
409     edep += eKinEnergy;                           409     edep += eKinEnergy;
410   }                                               410   }
411   // energy balance                               411   // energy balance
412   if(edep > 0.0)                                  412   if(edep > 0.0)
413   {                                               413   {
414     fParticleChange->ProposeLocalEnergyDeposit    414     fParticleChange->ProposeLocalEnergyDeposit(edep);
415   }                                               415   }
416 }                                                 416 }
417                                                   417 
418 //....oooOO0OOooo........oooOO0OOooo........oo    418 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
419 void G4PolarizedComptonModel::PrintWarning(con    419 void G4PolarizedComptonModel::PrintWarning(const G4DynamicParticle* dp,
420                                            G4i    420                                            G4int nloop, G4double grej,
421                                            G4d    421                                            G4double onecos, G4double phi,
422                                            con    422                                            const G4String sss) const
423 {                                                 423 {
424   G4ExceptionDescription ed;                      424   G4ExceptionDescription ed;
425   ed << "Problem of scattering sampling: " <<     425   ed << "Problem of scattering sampling: " << sss << "\n"
426      << "Niter= " << nloop << " grej= " << gre    426      << "Niter= " << nloop << " grej= " << grej
427      << " cos(theta)= " << 1.0 - onecos << " p    427      << " cos(theta)= " << 1.0 - onecos << " phi= " << phi << "\n"
428      << "Gamma E(MeV)= " << dp->GetKineticEner    428      << "Gamma E(MeV)= " << dp->GetKineticEnergy() / MeV
429      << " dir= " << dp->GetMomentumDirection()    429      << " dir= " << dp->GetMomentumDirection()
430      << " pol= " << dp->GetPolarization();        430      << " pol= " << dp->GetPolarization();
431   G4Exception("G4PolarizedComptonModel::Sample    431   G4Exception("G4PolarizedComptonModel::SampleSecondaries", "em0044",
432               JustWarning, ed, "");               432               JustWarning, ed, "");
433 }                                                 433 }
434                                                   434