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Geant4/processes/electromagnetic/xrays/src/G4ForwardXrayTR.cc

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Differences between /processes/electromagnetic/xrays/src/G4ForwardXrayTR.cc (Version 11.3.0) and /processes/electromagnetic/xrays/src/G4ForwardXrayTR.cc (Version 9.6)


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 25 //                                                 25 //
                                                   >>  26 //
                                                   >>  27 // $Id$
                                                   >>  28 //
                                                   >>  29 // G4ForwardXrayTR class -- implementation file
                                                   >>  30 //
 26 // History:                                        31 // History:
 27 // 1st version 11.09.97 V. Grichine (Vladimir.     32 // 1st version 11.09.97 V. Grichine (Vladimir.Grichine@cern.ch )
 28 // 2nd version 17.12.97 V. Grichine                33 // 2nd version 17.12.97 V. Grichine
 29 // 17-09-01, migration of Materials to pure ST     34 // 17-09-01, migration of Materials to pure STL (mma)
 30 // 10-03-03, migration to "cut per region" (V.     35 // 10-03-03, migration to "cut per region" (V.Ivanchenko)
 31 // 03.06.03, V.Ivanchenko fix compilation warn     36 // 03.06.03, V.Ivanchenko fix compilation warnings
 32                                                    37 
 33 #include "G4ForwardXrayTR.hh"                      38 #include "G4ForwardXrayTR.hh"
 34                                                    39 
 35 #include "globals.hh"                              40 #include "globals.hh"
 36 #include "G4Gamma.hh"                          << 
 37 #include "G4GeometryTolerance.hh"              << 
 38 #include "G4Material.hh"                       << 
 39 #include "G4PhysicalConstants.hh"                  41 #include "G4PhysicalConstants.hh"
 40 #include "G4PhysicsLinearVector.hh"            <<  42 #include "G4SystemOfUnits.hh"
 41 #include "G4PhysicsLogVector.hh"               <<  43 #include "G4Poisson.hh"
                                                   >>  44 #include "G4Material.hh"
 42 #include "G4PhysicsTable.hh"                       45 #include "G4PhysicsTable.hh"
 43 #include "G4PhysicsVector.hh"                      46 #include "G4PhysicsVector.hh"
 44 #include "G4Poisson.hh"                        <<  47 #include "G4PhysicsLinearVector.hh"
                                                   >>  48 #include "G4PhysicsLogVector.hh"
 45 #include "G4ProductionCutsTable.hh"                49 #include "G4ProductionCutsTable.hh"
 46 #include "G4SystemOfUnits.hh"                  <<  50 #include "G4GeometryTolerance.hh"
 47 #include "G4PhysicsModelCatalog.hh"            <<  51 
                                                   >>  52 // Initialization of local constants
                                                   >>  53 
                                                   >>  54 G4int    G4ForwardXrayTR::fSympsonNumber =  100;
                                                   >>  55 
                                                   >>  56 G4double G4ForwardXrayTR::fTheMinEnergyTR = 1.0*keV;
                                                   >>  57 G4double G4ForwardXrayTR::fTheMaxEnergyTR = 100.0*keV;
                                                   >>  58 G4double G4ForwardXrayTR::fTheMaxAngle    = 1.0e-3;
                                                   >>  59 G4double G4ForwardXrayTR::fTheMinAngle    =  5.0e-6;
                                                   >>  60 G4int    G4ForwardXrayTR::fBinTR          =  50;
                                                   >>  61 
                                                   >>  62 G4double G4ForwardXrayTR::fMinProtonTkin = 100.0*GeV;
                                                   >>  63 G4double G4ForwardXrayTR::fMaxProtonTkin = 100.0*TeV;
                                                   >>  64 G4int    G4ForwardXrayTR::fTotBin        =  50;
                                                   >>  65 
                                                   >>  66 G4double G4ForwardXrayTR::fPlasmaCof = 4.0*pi*fine_structure_const*
                                                   >>  67                                        hbarc*hbarc*hbarc/electron_mass_c2;
                                                   >>  68 
                                                   >>  69 G4double G4ForwardXrayTR::fCofTR     = fine_structure_const/pi;
                                                   >>  70 
 48                                                    71 
 49 //////////////////////////////////////////////     72 //////////////////////////////////////////////////////////////////////
 50 //                                                 73 //
 51 // Constructor for creation of physics tables      74 // Constructor for creation of physics tables (angle and energy TR
 52 // distributions) for a couple of selected mat     75 // distributions) for a couple of selected materials.
 53 //                                                 76 //
 54 // Recommended for use in applications with ma     77 // Recommended for use in applications with many materials involved,
 55 // when only few (usually couple) materials ar     78 // when only few (usually couple) materials are interested for generation
 56 // of TR on the interface between them             79 // of TR on the interface between them
 57 G4ForwardXrayTR::G4ForwardXrayTR(const G4Strin <<  80 
 58                                  const G4Strin <<  81 
 59                                  const G4Strin <<  82 G4ForwardXrayTR::
 60   : G4TransitionRadiation(processName)         <<  83 G4ForwardXrayTR( const G4String& matName1,   //  G4Material* pMat1,
 61 {                                              <<  84      const G4String& matName2,    //  G4Material* pMat2,
 62   secID = G4PhysicsModelCatalog::GetModelID("m <<  85                  const G4String& processName                          )
 63   fPtrGamma                = nullptr;          <<  86   :        G4TransitionRadiation(processName)
 64   fGammaCutInKineticEnergy = nullptr;          <<  87 {
 65   fGammaTkinCut = fMinEnergyTR = fMaxEnergyTR  <<  88   fPtrGamma = 0;
 66   fGamma = fSigma1 = fSigma2 = 0.0;            <<  89   fGammaCutInKineticEnergy = 0;
 67   fAngleDistrTable           = nullptr;        <<  90   fGammaTkinCut = fMinEnergyTR = fMaxEnergyTR =  fMaxThetaTR = fGamma = 
 68   fEnergyDistrTable          = nullptr;        <<  91     fSigma1 = fSigma2 = 0.0; 
                                                   >>  92   fAngleDistrTable = 0;
                                                   >>  93   fEnergyDistrTable = 0;
 69   fMatIndex1 = fMatIndex2 = 0;                     94   fMatIndex1 = fMatIndex2 = 0;
 70                                                    95 
 71   // Proton energy vector initialization           96   // Proton energy vector initialization
 72   fProtonEnergyVector =                        <<  97   //
 73     new G4PhysicsLogVector(fMinProtonTkin, fMa <<  98   fProtonEnergyVector = new G4PhysicsLogVector(fMinProtonTkin,
                                                   >>  99                                                fMaxProtonTkin, fTotBin  );
 74   G4int iMat;                                     100   G4int iMat;
 75   const G4ProductionCutsTable* theCoupleTable  << 101   const G4ProductionCutsTable* theCoupleTable=
 76     G4ProductionCutsTable::GetProductionCutsTa << 102         G4ProductionCutsTable::GetProductionCutsTable();
 77   G4int numOfCouples = (G4int)theCoupleTable-> << 103   G4int numOfCouples = theCoupleTable->GetTableSize();
 78                                                   104 
 79   G4bool build = true;                            105   G4bool build = true;
 80                                                   106 
 81   for(iMat = 0; iMat < numOfCouples; ++iMat)   << 107   for(iMat=0;iMat<numOfCouples;iMat++)    // check first material name
 82   {                                               108   {
 83     const G4MaterialCutsCouple* couple =       << 109     const G4MaterialCutsCouple* couple = theCoupleTable->GetMaterialCutsCouple(iMat);
 84       theCoupleTable->GetMaterialCutsCouple(iM << 110     if( matName1 == couple->GetMaterial()->GetName() )
 85     if(matName1 == couple->GetMaterial()->GetN << 
 86     {                                             111     {
 87       fMatIndex1 = couple->GetIndex();            112       fMatIndex1 = couple->GetIndex();
 88       break;                                      113       break;
 89     }                                             114     }
 90   }                                               115   }
 91   if(iMat == numOfCouples)                        116   if(iMat == numOfCouples)
 92   {                                               117   {
 93     G4Exception("G4ForwardXrayTR::G4ForwardXra << 118     G4Exception("G4ForwardXrayTR::G4ForwardXrayTR", "ForwardXrayTR01", JustWarning, "Invalid first material name in G4ForwardXrayTR constructor!");
 94                 JustWarning,                   << 
 95                 "Invalid first material name i << 
 96     build = false;                                119     build = false;
 97   }                                               120   }
 98                                                   121 
 99   if(build)                                    << 122   if(build) {
100   {                                            << 123     for(iMat=0;iMat<numOfCouples;iMat++)    // check second material name
101     for(iMat = 0; iMat < numOfCouples; ++iMat) << 
102     {                                          << 
103       const G4MaterialCutsCouple* couple =     << 
104         theCoupleTable->GetMaterialCutsCouple( << 
105       if(matName2 == couple->GetMaterial()->Ge << 
106       {                                           124       {
107         fMatIndex2 = couple->GetIndex();       << 125   const G4MaterialCutsCouple* couple = theCoupleTable->GetMaterialCutsCouple(iMat);
108         break;                                 << 126   if( matName2 == couple->GetMaterial()->GetName() )
                                                   >> 127     {
                                                   >> 128       fMatIndex2 = couple->GetIndex();
                                                   >> 129       break;
                                                   >> 130     }
109       }                                           131       }
110     }                                          << 
111     if(iMat == numOfCouples)                      132     if(iMat == numOfCouples)
112     {                                          << 133       {
113       G4Exception(                             << 134         G4Exception("G4ForwardXrayTR::G4ForwardXrayTR", "ForwardXrayTR02", JustWarning, "Invalid second material name in G4ForwardXrayTR constructor!");
114         "G4ForwardXrayTR::G4ForwardXrayTR", "F << 135   build = false;
115         "Invalid second material name in G4For << 136       }
116       build = false;                           << 
117     }                                          << 
118   }                                            << 
119   if(build)                                    << 
120   {                                            << 
121     BuildXrayTRtables();                       << 
122   }                                               137   }
                                                   >> 138   //  G4cout<<"G4ForwardXray constructor is called"<<G4endl;
                                                   >> 139   if(build) { BuildXrayTRtables(); }
123 }                                                 140 }
124                                                   141 
125 //////////////////////////////////////////////    142 /////////////////////////////////////////////////////////////////////////
                                                   >> 143 //
126 // Constructor used by X-ray transition radiat    144 // Constructor used by X-ray transition radiation parametrisation models
127 G4ForwardXrayTR::G4ForwardXrayTR(const G4Strin << 145 
128   : G4TransitionRadiation(processName)         << 146 G4ForwardXrayTR::
129 {                                              << 147 G4ForwardXrayTR( const G4String& processName  )
130   fPtrGamma                = nullptr;          << 148    :        G4TransitionRadiation(processName)
131   fGammaCutInKineticEnergy = nullptr;          << 149 {
132   fGammaTkinCut = fMinEnergyTR = fMaxEnergyTR  << 150   fPtrGamma = 0;
133   fGamma = fSigma1 = fSigma2 = 0.0;            << 151   fGammaCutInKineticEnergy = 0;
134   fAngleDistrTable           = nullptr;        << 152   fGammaTkinCut = fMinEnergyTR = fMaxEnergyTR =  fMaxThetaTR = fGamma = 
135   fEnergyDistrTable          = nullptr;        << 153     fSigma1 = fSigma2 = 0.0; 
                                                   >> 154   fAngleDistrTable = 0;
                                                   >> 155   fEnergyDistrTable = 0;
136   fMatIndex1 = fMatIndex2 = 0;                    156   fMatIndex1 = fMatIndex2 = 0;
137                                                   157 
138   // Proton energy vector initialization          158   // Proton energy vector initialization
139   fProtonEnergyVector =                        << 159   //
140     new G4PhysicsLogVector(fMinProtonTkin, fMa << 160   fProtonEnergyVector = new G4PhysicsLogVector(fMinProtonTkin,
                                                   >> 161                                                fMaxProtonTkin, fTotBin  );
141 }                                                 162 }
142                                                   163 
                                                   >> 164 
143 //////////////////////////////////////////////    165 //////////////////////////////////////////////////////////////////////
                                                   >> 166 //
144 // Destructor                                     167 // Destructor
                                                   >> 168 //
                                                   >> 169 
145 G4ForwardXrayTR::~G4ForwardXrayTR()               170 G4ForwardXrayTR::~G4ForwardXrayTR()
146 {                                                 171 {
147   delete fAngleDistrTable;                        172   delete fAngleDistrTable;
148   delete fEnergyDistrTable;                       173   delete fEnergyDistrTable;
149   delete fProtonEnergyVector;                     174   delete fProtonEnergyVector;
150 }                                                 175 }
151                                                   176 
152 void G4ForwardXrayTR::ProcessDescription(std:: << 177 G4double G4ForwardXrayTR::GetMeanFreePath(const G4Track&,
153 {                                              << 178             G4double,
154   out << "Simulation of forward X-ray transiti << 179             G4ForceCondition* condition)
155          "relativistic charged particles cross << 
156          "two materials.\n";                   << 
157 }                                              << 
158                                                << 
159 G4double G4ForwardXrayTR::GetMeanFreePath(cons << 
160                                           G4Fo << 
161 {                                                 180 {
162   *condition = Forced;                            181   *condition = Forced;
163   return DBL_MAX;  // so TR doesn't limit mean << 182   return DBL_MAX;      // so TR doesn't limit mean free path
164 }                                                 183 }
165                                                   184 
166 //////////////////////////////////////////////    185 //////////////////////////////////////////////////////////////////////////////
                                                   >> 186 //
167 // Build physics tables for energy and angular    187 // Build physics tables for energy and angular distributions of X-ray TR photon
                                                   >> 188 
168 void G4ForwardXrayTR::BuildXrayTRtables()         189 void G4ForwardXrayTR::BuildXrayTRtables()
169 {                                                 190 {
170   G4int iMat, jMat, iTkin, iTR, iPlace;           191   G4int iMat, jMat, iTkin, iTR, iPlace;
171   const G4ProductionCutsTable* theCoupleTable  << 192   const G4ProductionCutsTable* theCoupleTable=
172     G4ProductionCutsTable::GetProductionCutsTa << 193         G4ProductionCutsTable::GetProductionCutsTable();
173   G4int numOfCouples = (G4int)theCoupleTable-> << 194   G4int numOfCouples = theCoupleTable->GetTableSize();
174                                                   195 
175   fGammaCutInKineticEnergy = theCoupleTable->G    196   fGammaCutInKineticEnergy = theCoupleTable->GetEnergyCutsVector(idxG4GammaCut);
176                                                   197 
177   fAngleDistrTable  = new G4PhysicsTable(2 * f << 198   fAngleDistrTable  = new G4PhysicsTable(2*fTotBin);
178   fEnergyDistrTable = new G4PhysicsTable(2 * f << 199   fEnergyDistrTable = new G4PhysicsTable(2*fTotBin);
179                                                   200 
180   for(iMat = 0; iMat < numOfCouples;           << 201 
181       ++iMat)  // loop over pairs of different << 202   for(iMat=0;iMat<numOfCouples;iMat++)     // loop over pairs of different materials
182   {                                               203   {
183     if(iMat != fMatIndex1 && iMat != fMatIndex << 204     if( iMat != fMatIndex1 && iMat != fMatIndex2 ) continue;
184       continue;                                << 
185                                                   205 
186     for(jMat = 0; jMat < numOfCouples; ++jMat) << 206     for(jMat=0;jMat<numOfCouples;jMat++)  // transition iMat -> jMat !!!
187     {                                             207     {
188       if(iMat == jMat || (jMat != fMatIndex1 & << 208       if( iMat == jMat || ( jMat != fMatIndex1 && jMat != fMatIndex2 ) )
189       {                                           209       {
190         continue;                                 210         continue;
191       }                                           211       }
192       else                                        212       else
193       {                                           213       {
194         const G4MaterialCutsCouple* iCouple =  << 214         const G4MaterialCutsCouple* iCouple = theCoupleTable->GetMaterialCutsCouple(iMat);
195           theCoupleTable->GetMaterialCutsCoupl << 215         const G4MaterialCutsCouple* jCouple = theCoupleTable->GetMaterialCutsCouple(jMat);
196         const G4MaterialCutsCouple* jCouple =  << 
197           theCoupleTable->GetMaterialCutsCoupl << 
198         const G4Material* mat1 = iCouple->GetM    216         const G4Material* mat1 = iCouple->GetMaterial();
199         const G4Material* mat2 = jCouple->GetM    217         const G4Material* mat2 = jCouple->GetMaterial();
200                                                   218 
201         fSigma1 = fPlasmaCof * (mat1->GetElect << 219         fSigma1 = fPlasmaCof*(mat1->GetElectronDensity());
202         fSigma2 = fPlasmaCof * (mat2->GetElect << 220         fSigma2 = fPlasmaCof*(mat2->GetElectronDensity());
                                                   >> 221 
                                                   >> 222         // fGammaTkinCut = fGammaCutInKineticEnergy[jMat]; // TR photon in jMat !
203                                                   223 
204         fGammaTkinCut = 0.0;                      224         fGammaTkinCut = 0.0;
205                                                   225 
206         if(fGammaTkinCut > fTheMinEnergyTR)  / << 226         if(fGammaTkinCut > fTheMinEnergyTR)    // setting of min/max TR energies
207         {                                      << 227   {
208           fMinEnergyTR = fGammaTkinCut;           228           fMinEnergyTR = fGammaTkinCut;
209         }                                      << 229   }
210         else                                      230         else
211         {                                      << 231   {
212           fMinEnergyTR = fTheMinEnergyTR;         232           fMinEnergyTR = fTheMinEnergyTR;
213         }                                      << 233   }
214         if(fGammaTkinCut > fTheMaxEnergyTR)       234         if(fGammaTkinCut > fTheMaxEnergyTR)
215         {                                      << 235   {
216           fMaxEnergyTR = 2.0 * fGammaTkinCut;  << 236           fMaxEnergyTR = 2.0*fGammaTkinCut;    // usually very low TR rate
217         }                                      << 237   }
218         else                                      238         else
219         {                                      << 239   {
220           fMaxEnergyTR = fTheMaxEnergyTR;         240           fMaxEnergyTR = fTheMaxEnergyTR;
221         }                                      << 241   }
222         for(iTkin = 0; iTkin < fTotBin; ++iTki << 242         for(iTkin=0;iTkin<fTotBin;iTkin++)      // Lorentz factor loop
223         {                                      << 243   {
224           auto energyVector =                  << 244           G4PhysicsLogVector*
225             new G4PhysicsLogVector(fMinEnergyT << 245                     energyVector = new G4PhysicsLogVector( fMinEnergyTR,
                                                   >> 246                                                            fMaxEnergyTR,
                                                   >> 247                                                            fBinTR         );
226                                                   248 
227           fGamma = 1.0 + (fProtonEnergyVector- << 249           fGamma = 1.0 +   (fProtonEnergyVector->
228                           proton_mass_c2);     << 250                             GetLowEdgeEnergy(iTkin)/proton_mass_c2);
229                                                   251 
230           fMaxThetaTR = 10000.0 / (fGamma * fG << 252           fMaxThetaTR = 10000.0/(fGamma*fGamma);
231                                                   253 
232           if(fMaxThetaTR > fTheMaxAngle)          254           if(fMaxThetaTR > fTheMaxAngle)
233           {                                       255           {
234             fMaxThetaTR = fTheMaxAngle;           256             fMaxThetaTR = fTheMaxAngle;
235           }                                    << 257     }
236           else                                    258           else
237           {                                    << 259     {
238             if(fMaxThetaTR < fTheMinAngle)        260             if(fMaxThetaTR < fTheMinAngle)
239             {                                  << 261       {
240               fMaxThetaTR = fTheMinAngle;         262               fMaxThetaTR = fTheMinAngle;
241             }                                  << 263       }
242           }                                    << 264     }
243           auto angleVector =                   << 265    // G4cout<<G4endl<<"fGamma = "<<fGamma<<"  fMaxThetaTR = "<<fMaxThetaTR<<G4endl;
244             new G4PhysicsLinearVector(0.0, fMa << 266           G4PhysicsLinearVector*
                                                   >> 267                      angleVector = new G4PhysicsLinearVector(        0.0,
                                                   >> 268                                                              fMaxThetaTR,
                                                   >> 269                                                                   fBinTR  );
245           G4double energySum = 0.0;               270           G4double energySum = 0.0;
246           G4double angleSum  = 0.0;               271           G4double angleSum  = 0.0;
247                                                   272 
248           energyVector->PutValue(fBinTR - 1, e << 273           energyVector->PutValue(fBinTR-1,energySum);
249           angleVector->PutValue(fBinTR - 1, an << 274           angleVector->PutValue(fBinTR-1,angleSum);
250                                                   275 
251           for(iTR = fBinTR - 2; iTR >= 0; --iT << 276           for(iTR=fBinTR-2;iTR>=0;iTR--)
252           {                                    << 277     {
253             energySum +=                       << 278             energySum += fCofTR*EnergySum(energyVector->GetLowEdgeEnergy(iTR),
254               fCofTR * EnergySum(energyVector- << 279                                         energyVector->GetLowEdgeEnergy(iTR+1));
255                                  energyVector- << 280 
256                                                << 281             angleSum  += fCofTR*AngleSum(angleVector->GetLowEdgeEnergy(iTR),
257             angleSum +=                        << 282                                          angleVector->GetLowEdgeEnergy(iTR+1));
258               fCofTR * AngleSum(angleVector->G << 283 
259                                 angleVector->G << 284             energyVector->PutValue(iTR,energySum);
260                                                << 285             angleVector ->PutValue(iTR,angleSum);
261             energyVector->PutValue(iTR, energy << 286     }
262             angleVector->PutValue(iTR, angleSu << 287     // G4cout<<"sumE = "<<energySum<<"; sumA = "<<angleSum<<G4endl;
263           }                                    << 
264                                                   288 
265           if(jMat < iMat)                         289           if(jMat < iMat)
266           {                                    << 290     {
267             iPlace = fTotBin + iTkin;          << 291             iPlace = fTotBin+iTkin;   // (iMat*(numOfMat-1)+jMat)*
268           }                                    << 292     }
269           else  // jMat > iMat right part of m << 293           else   // jMat > iMat right part of matrices (jMat-1) !
270           {                                    << 294     {
271             iPlace = iTkin;                    << 295             iPlace = iTkin;  // (iMat*(numOfMat-1)+jMat-1)*fTotBin+
272           }                                    << 296     }
273           fEnergyDistrTable->insertAt(iPlace,  << 297           fEnergyDistrTable->insertAt(iPlace,energyVector);
274           fAngleDistrTable->insertAt(iPlace, a << 298           fAngleDistrTable->insertAt(iPlace,angleVector);
275         }  //                      iTkin       << 299   }    //                      iTkin
276       }    //         jMat != iMat             << 300       }      //         jMat != iMat
277     }      //     jMat                         << 301     }        //     jMat
278   }        // iMat                             << 302   }          // iMat
                                                   >> 303   //  G4cout<<"G4ForwardXrayTR::BuildXrayTRtables have been called"<<G4endl;
279 }                                                 304 }
280                                                   305 
281 //////////////////////////////////////////////    306 ///////////////////////////////////////////////////////////////////////
282 //                                                307 //
283 // This function returns the spectral and angl    308 // This function returns the spectral and angle density of TR quanta
284 // in X-ray energy region generated forward wh    309 // in X-ray energy region generated forward when a relativistic
285 // charged particle crosses interface between     310 // charged particle crosses interface between two materials.
286 // The high energy small theta approximation i    311 // The high energy small theta approximation is applied.
287 // (matter1 -> matter2)                           312 // (matter1 -> matter2)
288 // varAngle =2* (1 - std::cos(Theta)) or appro    313 // varAngle =2* (1 - std::cos(Theta)) or approximately = Theta*Theta
289 //                                                314 //
290 G4double G4ForwardXrayTR::SpectralAngleTRdensi << 315 
291                                                << 316 G4double
292 {                                              << 317 G4ForwardXrayTR::SpectralAngleTRdensity( G4double energy,
293   G4double formationLength1, formationLength2; << 318                                          G4double varAngle ) const
294   formationLength1 =                           << 319 {
295     1.0 / (1.0 / (fGamma * fGamma) + fSigma1 / << 320   G4double  formationLength1, formationLength2;
296   formationLength2 =                           << 321   formationLength1 = 1.0/
297     1.0 / (1.0 / (fGamma * fGamma) + fSigma2 / << 322   (1.0/(fGamma*fGamma)
298   return (varAngle / energy) * (formationLengt << 323   + fSigma1/(energy*energy)
299          (formationLength1 - formationLength2) << 324   + varAngle);
                                                   >> 325   formationLength2 = 1.0/
                                                   >> 326   (1.0/(fGamma*fGamma)
                                                   >> 327   + fSigma2/(energy*energy)
                                                   >> 328   + varAngle);
                                                   >> 329   return (varAngle/energy)*(formationLength1 - formationLength2)
                                                   >> 330               *(formationLength1 - formationLength2);
                                                   >> 331 
300 }                                                 332 }
301                                                   333 
                                                   >> 334 
302 //////////////////////////////////////////////    335 //////////////////////////////////////////////////////////////////
                                                   >> 336 //
303 // Analytical formula for angular density of X    337 // Analytical formula for angular density of X-ray TR photons
304 G4double G4ForwardXrayTR::AngleDensity(G4doubl << 338 //
                                                   >> 339 
                                                   >> 340 G4double G4ForwardXrayTR::AngleDensity( G4double energy,
                                                   >> 341                                         G4double varAngle ) const
305 {                                                 342 {
306   G4double x, x2, c, d, f, a2, b2, a4, b4;     << 343   G4double x, x2, /*a, b,*/ c, d, f, a2, b2, a4, b4;
307   G4double cof1, cof2, cof3;                      344   G4double cof1, cof2, cof3;
308   x    = 1.0 / energy;                         << 345   x = 1.0/energy;
309   x2   = x * x;                                << 346   x2 = x*x;
310   c    = 1.0 / fSigma1;                        << 347   c = 1.0/fSigma1;
311   d    = 1.0 / fSigma2;                        << 348   d = 1.0/fSigma2;
312   f    = (varAngle + 1.0 / (fGamma * fGamma)); << 349   f = (varAngle + 1.0/(fGamma*fGamma));
313   a2   = c * f;                                << 350   a2 = c*f;
314   b2   = d * f;                                << 351   b2 = d*f;
315   a4   = a2 * a2;                              << 352   a4 = a2*a2;
316   b4   = b2 * b2;                              << 353   b4 = b2*b2;
317   cof1 = c * c * (0.5 / (a2 * (x2 + a2)) + 0.5 << 354   //a = std::sqrt(a2);
318   cof3 = d * d * (0.5 / (b2 * (x2 + b2)) + 0.5 << 355   // b = std::sqrt(b2);
319   cof2 = -c * d *                              << 356   cof1 = c*c*(0.5/(a2*(x2 +a2)) +0.5*std::log(x2/(x2 +a2))/a4);
320          (std::log(x2 / (x2 + b2)) / b2 - std: << 357   cof3 = d*d*(0.5/(b2*(x2 +b2)) +0.5*std::log(x2/(x2 +b2))/b4);
321          (a2 - b2);                            << 358   cof2 = -c*d*(std::log(x2/(x2 +b2))/b2 - std::log(x2/(x2 +a2))/a2)/(a2 - b2)  ;
322   return -varAngle * (cof1 + cof2 + cof3);     << 359   return -varAngle*(cof1 + cof2 + cof3);
323 }                                                 360 }
324                                                   361 
325 //////////////////////////////////////////////    362 /////////////////////////////////////////////////////////////////////
                                                   >> 363 //
326 // Definite integral of X-ray TR spectral-angl    364 // Definite integral of X-ray TR spectral-angle density from energy1
327 // to energy2                                     365 // to energy2
328 G4double G4ForwardXrayTR::EnergyInterval(G4dou << 366 //
329                                          G4dou << 367 
                                                   >> 368 G4double G4ForwardXrayTR::EnergyInterval( G4double energy1,
                                                   >> 369                                           G4double energy2,
                                                   >> 370                                           G4double varAngle ) const
330 {                                                 371 {
331   return AngleDensity(energy2, varAngle) - Ang << 372   return     AngleDensity(energy2,varAngle)
                                                   >> 373            - AngleDensity(energy1,varAngle);
332 }                                                 374 }
333                                                   375 
334 //////////////////////////////////////////////    376 //////////////////////////////////////////////////////////////////////
                                                   >> 377 //
335 // Integral angle distribution of X-ray TR pho    378 // Integral angle distribution of X-ray TR photons based on analytical
336 // formula for angle density                      379 // formula for angle density
337 G4double G4ForwardXrayTR::AngleSum(G4double va << 380 //
                                                   >> 381 
                                                   >> 382 G4double G4ForwardXrayTR::AngleSum( G4double varAngle1,
                                                   >> 383                                     G4double varAngle2     )   const
338 {                                                 384 {
339   G4int i;                                        385   G4int i;
340   G4double h, sumEven = 0.0, sumOdd = 0.0;     << 386   G4double h , sumEven = 0.0 , sumOdd = 0.0;
341   h = 0.5 * (varAngle2 - varAngle1) / fSympson << 387   h = 0.5*(varAngle2 - varAngle1)/fSympsonNumber;
342   for(i = 1; i < fSympsonNumber; ++i)          << 388   for(i=1;i<fSympsonNumber;i++)
343   {                                            << 389   {
344     sumEven +=                                 << 390    sumEven += EnergyInterval(fMinEnergyTR,fMaxEnergyTR,varAngle1 + 2*i*h   );
345       EnergyInterval(fMinEnergyTR, fMaxEnergyT << 391    sumOdd  += EnergyInterval(fMinEnergyTR,fMaxEnergyTR,
346     sumOdd +=                                  << 392                                                    varAngle1 + (2*i - 1)*h );
347       EnergyInterval(fMinEnergyTR, fMaxEnergyT << 393   }
348   }                                            << 394   sumOdd += EnergyInterval(fMinEnergyTR,fMaxEnergyTR,
349   sumOdd += EnergyInterval(fMinEnergyTR, fMaxE << 395                         varAngle1 + (2*fSympsonNumber - 1)*h    );
350                            varAngle1 + (2 * fS << 396 
351                                                << 397   return h*(EnergyInterval(fMinEnergyTR,fMaxEnergyTR,varAngle1)
352   return h *                                   << 398           + EnergyInterval(fMinEnergyTR,fMaxEnergyTR,varAngle2)
353          (EnergyInterval(fMinEnergyTR, fMaxEne << 399           + 4.0*sumOdd + 2.0*sumEven                          )/3.0;
354           EnergyInterval(fMinEnergyTR, fMaxEne << 
355           2.0 * sumEven) /                     << 
356          3.0;                                  << 
357 }                                                 400 }
358                                                   401 
359 //////////////////////////////////////////////    402 /////////////////////////////////////////////////////////////////////
                                                   >> 403 //
360 // Analytical Expression for   spectral densit    404 // Analytical Expression for   spectral density of Xray TR photons
361 // x = 2*(1 - std::cos(Theta)) ~ Theta^2          405 // x = 2*(1 - std::cos(Theta)) ~ Theta^2
362 G4double G4ForwardXrayTR::SpectralDensity(G4do << 406 //
                                                   >> 407 
                                                   >> 408 G4double G4ForwardXrayTR::SpectralDensity( G4double energy,
                                                   >> 409                                            G4double      x  ) const
363 {                                                 410 {
364   G4double a, b;                                  411   G4double a, b;
365   a = 1.0 / (fGamma * fGamma) + fSigma1 / (ene << 412   a =  1.0/(fGamma*fGamma)
366   b = 1.0 / (fGamma * fGamma) + fSigma2 / (ene << 413      + fSigma1/(energy*energy) ;
367   return ((a + b) * std::log((x + b) / (x + a) << 414   b =  1.0/(fGamma*fGamma)
368           b / (x + b)) /                       << 415      + fSigma2/(energy*energy) ;
369          energy;                               << 416   return ( (a + b)*std::log((x + b)/(x + a))/(a - b)
                                                   >> 417           + a/(x + a) + b/(x + b) )/energy;
                                                   >> 418 
370 }                                                 419 }
371                                                   420 
372 //////////////////////////////////////////////    421 ////////////////////////////////////////////////////////////////////
                                                   >> 422 //
373 //  The spectral density in some angle interva    423 //  The spectral density in some angle interval from varAngle1 to
374 //  varAngle2                                     424 //  varAngle2
375 G4double G4ForwardXrayTR::AngleInterval(G4doub << 425 //
376                                         G4doub << 426 
                                                   >> 427 G4double G4ForwardXrayTR::AngleInterval( G4double    energy,
                                                   >> 428                                          G4double varAngle1,
                                                   >> 429                                          G4double varAngle2   ) const
377 {                                                 430 {
378   return SpectralDensity(energy, varAngle2) -  << 431   return     SpectralDensity(energy,varAngle2)
379          SpectralDensity(energy, varAngle1);   << 432            - SpectralDensity(energy,varAngle1);
380 }                                                 433 }
381                                                   434 
382 //////////////////////////////////////////////    435 ////////////////////////////////////////////////////////////////////
                                                   >> 436 //
383 // Integral spectral distribution of X-ray TR     437 // Integral spectral distribution of X-ray TR photons based on
384 // analytical formula for spectral density        438 // analytical formula for spectral density
385 G4double G4ForwardXrayTR::EnergySum(G4double e << 439 //
                                                   >> 440 
                                                   >> 441 G4double G4ForwardXrayTR::EnergySum( G4double energy1,
                                                   >> 442                                      G4double energy2     )   const
386 {                                                 443 {
387   G4int i;                                        444   G4int i;
388   G4double h, sumEven = 0.0, sumOdd = 0.0;     << 445   G4double h , sumEven = 0.0 , sumOdd = 0.0;
389   h = 0.5 * (energy2 - energy1) / fSympsonNumb << 446   h = 0.5*(energy2 - energy1)/fSympsonNumber;
390   for(i = 1; i < fSympsonNumber; ++i)          << 447   for(i=1;i<fSympsonNumber;i++)
391   {                                            << 448   {
392     sumEven += AngleInterval(energy1 + 2 * i * << 449    sumEven += AngleInterval(energy1 + 2*i*h,0.0,fMaxThetaTR);
393     sumOdd += AngleInterval(energy1 + (2 * i - << 450    sumOdd  += AngleInterval(energy1 + (2*i - 1)*h,0.0,fMaxThetaTR);
394   }                                            << 451   }
395   sumOdd +=                                    << 452   sumOdd += AngleInterval(energy1 + (2*fSympsonNumber - 1)*h,
396     AngleInterval(energy1 + (2 * fSympsonNumbe << 453                           0.0,fMaxThetaTR);
397                                                << 454 
398   return h *                                   << 455   return h*(  AngleInterval(energy1,0.0,fMaxThetaTR)
399          (AngleInterval(energy1, 0.0, fMaxThet << 456             + AngleInterval(energy2,0.0,fMaxThetaTR)
400           AngleInterval(energy2, 0.0, fMaxThet << 457             + 4.0*sumOdd + 2.0*sumEven                          )/3.0;
401           2.0 * sumEven) /                     << 
402          3.0;                                  << 
403 }                                                 458 }
404                                                   459 
405 //////////////////////////////////////////////    460 /////////////////////////////////////////////////////////////////////////
                                                   >> 461 //
406 // PostStepDoIt function for creation of forwa    462 // PostStepDoIt function for creation of forward X-ray photons in TR process
407 // on boundary between two materials with real << 463 // on boubndary between two materials with really different plasma energies
                                                   >> 464 //
                                                   >> 465 
408 G4VParticleChange* G4ForwardXrayTR::PostStepDo    466 G4VParticleChange* G4ForwardXrayTR::PostStepDoIt(const G4Track& aTrack,
409                                                << 467                         const G4Step&  aStep)
410 {                                                 468 {
411   aParticleChange.Initialize(aTrack);             469   aParticleChange.Initialize(aTrack);
                                                   >> 470   //  G4cout<<"call G4ForwardXrayTR::PostStepDoIt"<<G4endl;
412   G4int iMat, jMat, iTkin, iPlace, numOfTR, iT    471   G4int iMat, jMat, iTkin, iPlace, numOfTR, iTR, iTransfer;
413                                                   472 
414   G4double energyPos, anglePos, energyTR, thet    473   G4double energyPos, anglePos, energyTR, theta, phi, dirX, dirY, dirZ;
415   G4double W, W1, W2, E1, E2;                     474   G4double W, W1, W2, E1, E2;
416                                                   475 
417   G4StepPoint* pPreStepPoint  = aStep.GetPreSt    476   G4StepPoint* pPreStepPoint  = aStep.GetPreStepPoint();
418   G4StepPoint* pPostStepPoint = aStep.GetPostS    477   G4StepPoint* pPostStepPoint = aStep.GetPostStepPoint();
419   G4double tol =                               << 478   G4double tol=0.5*G4GeometryTolerance::GetInstance()->GetSurfaceTolerance();
420     0.5 * G4GeometryTolerance::GetInstance()-> << 
421                                                   479 
422   if(pPostStepPoint->GetStepStatus() != fGeomB << 480   if (pPostStepPoint->GetStepStatus() != fGeomBoundary)
423   {                                               481   {
424     return G4VDiscreteProcess::PostStepDoIt(aT    482     return G4VDiscreteProcess::PostStepDoIt(aTrack, aStep);
425   }                                               483   }
426   if(aTrack.GetStepLength() <= tol)            << 484   if (aTrack.GetStepLength() <= tol)
427   {                                               485   {
428     return G4VDiscreteProcess::PostStepDoIt(aT    486     return G4VDiscreteProcess::PostStepDoIt(aTrack, aStep);
429   }                                               487   }
430   // Arrived at boundary, so begin to try TR   << 488   // Come on boundary, so begin to try TR
431                                                   489 
432   const G4MaterialCutsCouple* iCouple = pPreSt << 490   const G4MaterialCutsCouple* iCouple = pPreStepPoint ->GetPhysicalVolume()->
433                                           ->Ge << 491        GetLogicalVolume()->GetMaterialCutsCouple();
434                                           ->Ge << 492   const G4MaterialCutsCouple* jCouple = pPostStepPoint ->GetPhysicalVolume()->
435   const G4MaterialCutsCouple* jCouple = pPostS << 493        GetLogicalVolume()->GetMaterialCutsCouple();
436                                           ->Ge << 
437                                           ->Ge << 
438   const G4Material* iMaterial = iCouple->GetMa    494   const G4Material* iMaterial = iCouple->GetMaterial();
439   const G4Material* jMaterial = jCouple->GetMa    495   const G4Material* jMaterial = jCouple->GetMaterial();
440   iMat                        = iCouple->GetIn << 496   iMat = iCouple->GetIndex();
441   jMat                        = jCouple->GetIn << 497   jMat = jCouple->GetIndex();
442                                                   498 
443   // The case of equal or approximate (in term    499   // The case of equal or approximate (in terms of plasma energy) materials
444   // No TR photons ?!                             500   // No TR photons ?!
445                                                   501 
446   if(iMat == jMat ||                           << 502   if (     iMat == jMat
447      ((fMatIndex1 >= 0 && fMatIndex2 >= 0) &&  << 503       || (    (fMatIndex1 >= 0 && fMatIndex1 >= 0)
448       (iMat != fMatIndex1 && iMat != fMatIndex << 504            && ( iMat != fMatIndex1 && iMat != fMatIndex2 )
449       (jMat != fMatIndex1 && jMat != fMatIndex << 505            && ( jMat != fMatIndex1 && jMat != fMatIndex2 )  )
450                                                   506 
451      || iMaterial->GetState() == jMaterial->Ge << 507       || iMaterial->GetState() == jMaterial->GetState()
452                                                   508 
453      || (iMaterial->GetState() == kStateSolid  << 509       ||(iMaterial->GetState() == kStateSolid && jMaterial->GetState() == kStateLiquid )
454          jMaterial->GetState() == kStateLiquid << 
455                                                   510 
456      || (iMaterial->GetState() == kStateLiquid << 511       ||(iMaterial->GetState() == kStateLiquid && jMaterial->GetState() == kStateSolid  )   )
457          jMaterial->GetState() == kStateSolid) << 
458   {                                               512   {
459     return G4VDiscreteProcess::PostStepDoIt(aT    513     return G4VDiscreteProcess::PostStepDoIt(aTrack, aStep);
460   }                                               514   }
461                                                   515 
462   const G4DynamicParticle* aParticle = aTrack.    516   const G4DynamicParticle* aParticle = aTrack.GetDynamicParticle();
463   G4double charge = aParticle->GetDefinition()    517   G4double charge = aParticle->GetDefinition()->GetPDGCharge();
464                                                   518 
465   if(charge == 0.0)  // Uncharged particle doe << 519   if(charge == 0.0) // Uncharged particle doesn't Generate TR photons
466   {                                               520   {
467     return G4VDiscreteProcess::PostStepDoIt(aT    521     return G4VDiscreteProcess::PostStepDoIt(aTrack, aStep);
468   }                                               522   }
469   // Now we are ready to Generate TR photons      523   // Now we are ready to Generate TR photons
470                                                   524 
471   G4double chargeSq  = charge * charge;        << 525   G4double chargeSq = charge*charge;
472   G4double kinEnergy = aParticle->GetKineticEn << 526   G4double kinEnergy     = aParticle->GetKineticEnergy();
473   G4double massRatio =                         << 527   G4double massRatio = proton_mass_c2/aParticle->GetDefinition()->GetPDGMass();
474     proton_mass_c2 / aParticle->GetDefinition( << 528   G4double TkinScaled = kinEnergy*massRatio;
475   G4double TkinScaled = kinEnergy * massRatio; << 529   for(iTkin=0;iTkin<fTotBin;iTkin++)
476   for(iTkin = 0; iTkin < fTotBin; ++iTkin)     << 
477   {                                               530   {
478     if(TkinScaled < fProtonEnergyVector->GetLo << 531     if(TkinScaled < fProtonEnergyVector->GetLowEdgeEnergy(iTkin)) // <= ?
479     {                                             532     {
480       break;                                      533       break;
481     }                                             534     }
482   }                                               535   }
483   if(jMat < iMat)                                 536   if(jMat < iMat)
484   {                                               537   {
485     iPlace = fTotBin + iTkin - 1;              << 538     iPlace = fTotBin + iTkin - 1; // (iMat*(numOfMat - 1) + jMat)*
486   }                                               539   }
487   else                                            540   else
488   {                                               541   {
489     iPlace = iTkin - 1;                        << 542     iPlace = iTkin - 1;  // (iMat*(numOfMat - 1) + jMat - 1)*fTotBin +
490   }                                               543   }
                                                   >> 544   //  G4PhysicsVector*  energyVector1 = (*fEnergyDistrTable)(iPlace)    ;
                                                   >> 545   //  G4PhysicsVector*  energyVector2 = (*fEnergyDistrTable)(iPlace + 1);
                                                   >> 546 
                                                   >> 547   //  G4PhysicsVector*   angleVector1 = (*fAngleDistrTable)(iPlace)     ;
                                                   >> 548   //  G4PhysicsVector*   angleVector2 = (*fAngleDistrTable)(iPlace + 1) ;
491                                                   549 
492   G4ParticleMomentum particleDir = aParticle->    550   G4ParticleMomentum particleDir = aParticle->GetMomentumDirection();
493                                                   551 
494   if(iTkin == fTotBin)  // TR plato, try from  << 552   if(iTkin == fTotBin)                 // TR plato, try from left
495   {                                               553   {
496     numOfTR = (G4int)G4Poisson(                << 554  // G4cout<<iTkin<<" mean TR number = "<<( (*(*fEnergyDistrTable)(iPlace))(0) +
497       ((*(*fEnergyDistrTable)(iPlace))(0) + (* << 555  //                                   (*(*fAngleDistrTable)(iPlace))(0) )
498       chargeSq * 0.5);                         << 556  //      *chargeSq*0.5<<G4endl;
                                                   >> 557 
                                                   >> 558     numOfTR = G4Poisson( ( (*(*fEnergyDistrTable)(iPlace))(0) +
                                                   >> 559                            (*(*fAngleDistrTable)(iPlace))(0) )
                                                   >> 560                          *chargeSq*0.5 );
499     if(numOfTR == 0)                              561     if(numOfTR == 0)
500     {                                             562     {
501       return G4VDiscreteProcess::PostStepDoIt(    563       return G4VDiscreteProcess::PostStepDoIt(aTrack, aStep);
502     }                                             564     }
503     else                                          565     else
504     {                                             566     {
                                                   >> 567       // G4cout<<"Number of X-ray TR photons = "<<numOfTR<<G4endl;
                                                   >> 568 
505       aParticleChange.SetNumberOfSecondaries(n    569       aParticleChange.SetNumberOfSecondaries(numOfTR);
506                                                   570 
507       for(iTR = 0; iTR < numOfTR; ++iTR)       << 571       for(iTR=0;iTR<numOfTR;iTR++)
508       {                                           572       {
509         energyPos = (*(*fEnergyDistrTable)(iPl << 573         energyPos = (*(*fEnergyDistrTable)(iPlace))(0)*G4UniformRand();
510         for(iTransfer = 0; iTransfer < fBinTR  << 574         for(iTransfer=0;iTransfer<fBinTR-1;iTransfer++)
511         {                                      << 575   {
512           if(energyPos >= (*(*fEnergyDistrTabl << 576           if(energyPos >= (*(*fEnergyDistrTable)(iPlace))(iTransfer)) break;
513             break;                             << 577   }
514         }                                      << 
515         energyTR = (*fEnergyDistrTable)(iPlace    578         energyTR = (*fEnergyDistrTable)(iPlace)->GetLowEdgeEnergy(iTransfer);
516                                                   579 
                                                   >> 580   // G4cout<<"energyTR = "<<energyTR/keV<<"keV"<<G4endl;
                                                   >> 581 
517         kinEnergy -= energyTR;                    582         kinEnergy -= energyTR;
518         aParticleChange.ProposeEnergy(kinEnerg    583         aParticleChange.ProposeEnergy(kinEnergy);
519                                                   584 
520         anglePos = (*(*fAngleDistrTable)(iPlac << 585         anglePos = (*(*fAngleDistrTable)(iPlace))(0)*G4UniformRand();
521         for(iTransfer = 0; iTransfer < fBinTR  << 586         for(iTransfer=0;iTransfer<fBinTR-1;iTransfer++)
522         {                                      << 587   {
523           if(anglePos > (*(*fAngleDistrTable)( << 588           if(anglePos > (*(*fAngleDistrTable)(iPlace))(iTransfer)) break;
524             break;                             << 589   }
525         }                                      << 590         theta = std::sqrt((*fAngleDistrTable)(iPlace)->GetLowEdgeEnergy(iTransfer-1));
526         theta = std::sqrt(                     << 591 
527           (*fAngleDistrTable)(iPlace)->GetLowE << 592   // G4cout<<iTransfer<<" :  theta = "<<theta<<G4endl;
528                                                << 593 
529         phi  = twopi * G4UniformRand();        << 594         phi = twopi*G4UniformRand();
530         dirX = std::sin(theta) * std::cos(phi) << 595         dirX = std::sin(theta)*std::cos(phi) ;
531         dirY = std::sin(theta) * std::sin(phi) << 596         dirY = std::sin(theta)*std::sin(phi) ;
532         dirZ = std::cos(theta);                << 597         dirZ = std::cos(theta)          ;
533         G4ThreeVector directionTR(dirX, dirY,  << 598         G4ThreeVector directionTR(dirX,dirY,dirZ);
534         directionTR.rotateUz(particleDir);        599         directionTR.rotateUz(particleDir);
535         auto aPhotonTR = new G4DynamicParticle << 600         G4DynamicParticle* aPhotonTR = new G4DynamicParticle(G4Gamma::Gamma(),
536                                                << 601                                                              directionTR,
537   // Create the G4Track                        << 602                                                              energyTR     );
538   auto aSecondaryTrack = new G4Track(aPhotonTR << 603         aParticleChange.AddSecondary(aPhotonTR);
539   aSecondaryTrack->SetTouchableHandle(aStep.Ge << 
540   aSecondaryTrack->SetParentID(aTrack.GetTrack << 
541   aSecondaryTrack->SetCreatorModelID(secID);   << 
542   aParticleChange.AddSecondary(aSecondaryTrack << 
543       }                                           604       }
544     }                                             605     }
545   }                                               606   }
546   else                                            607   else
547   {                                               608   {
548     if(iTkin == 0)  // Tkin is too small, negl << 609     if(iTkin == 0) // Tkin is too small, neglect of TR photon generation
549     {                                             610     {
550       return G4VDiscreteProcess::PostStepDoIt(    611       return G4VDiscreteProcess::PostStepDoIt(aTrack, aStep);
551     }                                             612     }
552     else  // general case: Tkin between two ve << 613     else          // general case: Tkin between two vectors of the material
553     {                                             614     {
554       E1 = fProtonEnergyVector->GetLowEdgeEner    615       E1 = fProtonEnergyVector->GetLowEdgeEnergy(iTkin - 1);
555       E2 = fProtonEnergyVector->GetLowEdgeEner << 616       E2 = fProtonEnergyVector->GetLowEdgeEnergy(iTkin)    ;
556       W  = 1.0 / (E2 - E1);                    << 617        W = 1.0/(E2 - E1);
557       W1 = (E2 - TkinScaled) * W;              << 618       W1 = (E2 - TkinScaled)*W;
558       W2 = (TkinScaled - E1) * W;              << 619       W2 = (TkinScaled - E1)*W;
559                                                << 620 
560       numOfTR = (G4int)G4Poisson((((*(*fEnergy << 621   // G4cout<<iTkin<<" mean TR number = "<<(((*(*fEnergyDistrTable)(iPlace))(0)+
561                                    (*(*fAngleD << 622   // (*(*fAngleDistrTable)(iPlace))(0))*W1 +
562                                     W1 +       << 623   //                                ((*(*fEnergyDistrTable)(iPlace + 1))(0)+
563                                   ((*(*fEnergy << 624   // (*(*fAngleDistrTable)(iPlace + 1))(0))*W2)
564                                    (*(*fAngleD << 625   //                                    *chargeSq*0.5<<G4endl;
565                                     W2) *      << 626 
566                                  chargeSq * 0. << 627       numOfTR = G4Poisson((((*(*fEnergyDistrTable)(iPlace))(0)+
                                                   >> 628                             (*(*fAngleDistrTable)(iPlace))(0))*W1 +
                                                   >> 629                            ((*(*fEnergyDistrTable)(iPlace + 1))(0)+
                                                   >> 630                             (*(*fAngleDistrTable)(iPlace + 1))(0))*W2)
                                                   >> 631                           *chargeSq*0.5 );
567       if(numOfTR == 0)                            632       if(numOfTR == 0)
568       {                                           633       {
569         return G4VDiscreteProcess::PostStepDoI    634         return G4VDiscreteProcess::PostStepDoIt(aTrack, aStep);
570       }                                           635       }
571       else                                        636       else
572       {                                           637       {
                                                   >> 638         // G4cout<<"Number of X-ray TR photons = "<<numOfTR<<G4endl;
                                                   >> 639 
573         aParticleChange.SetNumberOfSecondaries    640         aParticleChange.SetNumberOfSecondaries(numOfTR);
574         for(iTR = 0; iTR < numOfTR; ++iTR)     << 641         for(iTR=0;iTR<numOfTR;iTR++)
575         {                                         642         {
576           energyPos = ((*(*fEnergyDistrTable)( << 643           energyPos = ((*(*fEnergyDistrTable)(iPlace))(0)*W1+
577                        (*(*fEnergyDistrTable)( << 644                        (*(*fEnergyDistrTable)(iPlace + 1))(0)*W2)*G4UniformRand();
578                       G4UniformRand();         << 645           for(iTransfer=0;iTransfer<fBinTR-1;iTransfer++)
579           for(iTransfer = 0; iTransfer < fBinT << 646       {
580           {                                    << 647             if(energyPos >= ((*(*fEnergyDistrTable)(iPlace))(iTransfer)*W1+
581             if(energyPos >=                    << 648                        (*(*fEnergyDistrTable)(iPlace + 1))(iTransfer)*W2)) break;
582                ((*(*fEnergyDistrTable)(iPlace) << 649       }
583                 (*(*fEnergyDistrTable)(iPlace  << 650           energyTR = ((*fEnergyDistrTable)(iPlace)->GetLowEdgeEnergy(iTransfer))*W1+
584               break;                           << 651                ((*fEnergyDistrTable)(iPlace + 1)->GetLowEdgeEnergy(iTransfer))*W2;
585           }                                    << 652 
586           energyTR =                           << 653     // G4cout<<"energyTR = "<<energyTR/keV<<"keV"<<G4endl;
587             ((*fEnergyDistrTable)(iPlace)->Get << 
588             ((*fEnergyDistrTable)(iPlace + 1)- << 
589               W2;                              << 
590                                                   654 
591           kinEnergy -= energyTR;                  655           kinEnergy -= energyTR;
592           aParticleChange.ProposeEnergy(kinEne    656           aParticleChange.ProposeEnergy(kinEnergy);
593                                                   657 
594           anglePos = ((*(*fAngleDistrTable)(iP << 658           anglePos = ((*(*fAngleDistrTable)(iPlace))(0)*W1+
595                       (*(*fAngleDistrTable)(iP << 659                        (*(*fAngleDistrTable)(iPlace + 1))(0)*W2)*G4UniformRand();
596                      G4UniformRand();          << 660           for(iTransfer=0;iTransfer<fBinTR-1;iTransfer++)
597           for(iTransfer = 0; iTransfer < fBinT << 661     {
598           {                                    << 662             if(anglePos > ((*(*fAngleDistrTable)(iPlace))(iTransfer)*W1+
599             if(anglePos > ((*(*fAngleDistrTabl << 663                       (*(*fAngleDistrTable)(iPlace + 1))(iTransfer)*W2)) break;
600                            (*(*fAngleDistrTabl << 664     }
601               break;                           << 665           theta = std::sqrt(((*fAngleDistrTable)(iPlace)->
602           }                                    << 666                         GetLowEdgeEnergy(iTransfer-1))*W1+
603           theta = std::sqrt(                   << 667                   ((*fAngleDistrTable)(iPlace + 1)->
604             ((*fAngleDistrTable)(iPlace)->GetL << 668                         GetLowEdgeEnergy(iTransfer-1))*W2);
605               W1 +                             << 669 
606             ((*fAngleDistrTable)(iPlace + 1)-> << 670     // G4cout<<iTransfer<<" : theta = "<<theta<<G4endl;
607               W2);                             << 671 
608                                                << 672           phi = twopi*G4UniformRand();
609           phi  = twopi * G4UniformRand();      << 673           dirX = std::sin(theta)*std::cos(phi) ;
610           dirX = std::sin(theta) * std::cos(ph << 674           dirY = std::sin(theta)*std::sin(phi) ;
611           dirY = std::sin(theta) * std::sin(ph << 675           dirZ = std::cos(theta)          ;
612           dirZ = std::cos(theta);              << 676           G4ThreeVector directionTR(dirX,dirY,dirZ);
613           G4ThreeVector directionTR(dirX, dirY << 
614           directionTR.rotateUz(particleDir);      677           directionTR.rotateUz(particleDir);
615           auto aPhotonTR =                     << 678           G4DynamicParticle* aPhotonTR = new G4DynamicParticle(G4Gamma::Gamma(),
616             new G4DynamicParticle(G4Gamma::Gam << 679                                                                directionTR,
617                                                << 680                                                                energyTR     );
618     // Create the G4Track                      << 681           aParticleChange.AddSecondary(aPhotonTR);
619     G4Track* aSecondaryTrack = new G4Track(aPh << 
620     aSecondaryTrack->SetTouchableHandle(aStep. << 
621     aSecondaryTrack->SetParentID(aTrack.GetTra << 
622     aSecondaryTrack->SetCreatorModelID(secID); << 
623     aParticleChange.AddSecondary(aSecondaryTra << 
624         }                                         682         }
625       }                                           683       }
626     }                                             684     }
627   }                                               685   }
628   return &aParticleChange;                        686   return &aParticleChange;
629 }                                                 687 }
630                                                   688 
631 //////////////////////////////////////////////    689 ////////////////////////////////////////////////////////////////////////////
                                                   >> 690 //
632 // Test function for checking of PostStepDoIt     691 // Test function for checking of PostStepDoIt random preparation of TR photon
633 // energy                                         692 // energy
634 G4double G4ForwardXrayTR::GetEnergyTR(G4int iM << 693 //
                                                   >> 694 
                                                   >> 695 G4double
                                                   >> 696 G4ForwardXrayTR::GetEnergyTR(G4int iMat, G4int jMat, G4int iTkin) const
635 {                                                 697 {
636   G4int iPlace, numOfTR, iTR, iTransfer;       << 698   G4int  iPlace, numOfTR, iTR, iTransfer;
637   G4double energyTR = 0.0;  // return this val << 699   G4double energyTR = 0.0; // return this value for no TR photons
638   G4double energyPos;                          << 700   G4double energyPos ;
639   G4double W1, W2;                             << 701   G4double  W1, W2;
640                                                << 702 
641   const G4ProductionCutsTable* theCoupleTable  << 703   const G4ProductionCutsTable* theCoupleTable=
642     G4ProductionCutsTable::GetProductionCutsTa << 704         G4ProductionCutsTable::GetProductionCutsTable();
643   G4int numOfCouples = (G4int)theCoupleTable-> << 705   G4int numOfCouples = theCoupleTable->GetTableSize();
644                                                   706 
645   // The case of equal or approximate (in term    707   // The case of equal or approximate (in terms of plasma energy) materials
646   // No TR photons ?!                             708   // No TR photons ?!
647                                                   709 
648   const G4MaterialCutsCouple* iCouple =        << 710   const G4MaterialCutsCouple* iCouple = theCoupleTable->GetMaterialCutsCouple(iMat);
649     theCoupleTable->GetMaterialCutsCouple(iMat << 711   const G4MaterialCutsCouple* jCouple = theCoupleTable->GetMaterialCutsCouple(jMat);
650   const G4MaterialCutsCouple* jCouple =        << 
651     theCoupleTable->GetMaterialCutsCouple(jMat << 
652   const G4Material* iMaterial = iCouple->GetMa    712   const G4Material* iMaterial = iCouple->GetMaterial();
653   const G4Material* jMaterial = jCouple->GetMa    713   const G4Material* jMaterial = jCouple->GetMaterial();
654                                                   714 
655   if(iMat == jMat                              << 715   if (     iMat == jMat
656                                                   716 
657      || iMaterial->GetState() == jMaterial->Ge << 717       || iMaterial->GetState() == jMaterial->GetState()
658                                                   718 
659      || (iMaterial->GetState() == kStateSolid  << 719       ||(iMaterial->GetState() == kStateSolid && jMaterial->GetState() == kStateLiquid )
660          jMaterial->GetState() == kStateLiquid << 
661                                                   720 
662      || (iMaterial->GetState() == kStateLiquid << 721       ||(iMaterial->GetState() == kStateLiquid && jMaterial->GetState() == kStateSolid  )   )
663          jMaterial->GetState() == kStateSolid) << 
664                                                   722 
665   {                                               723   {
666     return energyTR;                              724     return energyTR;
667   }                                               725   }
668                                                   726 
669   if(jMat < iMat)                                 727   if(jMat < iMat)
670   {                                               728   {
671     iPlace = (iMat * (numOfCouples - 1) + jMat << 729     iPlace = (iMat*(numOfCouples - 1) + jMat)*fTotBin + iTkin - 1;
672   }                                               730   }
673   else                                            731   else
674   {                                               732   {
675     iPlace = (iMat * (numOfCouples - 1) + jMat << 733     iPlace = (iMat*(numOfCouples - 1) + jMat - 1)*fTotBin + iTkin - 1;
676   }                                               734   }
677   G4PhysicsVector* energyVector1 = (*fEnergyDi << 735   G4PhysicsVector*  energyVector1 = (*fEnergyDistrTable)(iPlace)    ;
678   G4PhysicsVector* energyVector2 = (*fEnergyDi << 736   G4PhysicsVector*  energyVector2 = (*fEnergyDistrTable)(iPlace + 1);
679                                                   737 
680   if(iTkin == fTotBin)  // TR plato, try from  << 738   if(iTkin == fTotBin)                 // TR plato, try from left
681   {                                               739   {
682     numOfTR = (G4int)G4Poisson((*energyVector1 << 740     numOfTR = G4Poisson( (*energyVector1)(0)  );
683     if(numOfTR == 0)                              741     if(numOfTR == 0)
684     {                                             742     {
685       return energyTR;                            743       return energyTR;
686     }                                             744     }
687     else                                          745     else
688     {                                             746     {
689       for(iTR = 0; iTR < numOfTR; ++iTR)       << 747       for(iTR=0;iTR<numOfTR;iTR++)
690       {                                           748       {
691         energyPos = (*energyVector1)(0) * G4Un << 749         energyPos = (*energyVector1)(0)*G4UniformRand();
692         for(iTransfer = 0; iTransfer < fBinTR  << 750         for(iTransfer=0;iTransfer<fBinTR-1;iTransfer++)
693         {                                      << 751   {
694           if(energyPos >= (*energyVector1)(iTr << 752           if(energyPos >= (*energyVector1)(iTransfer)) break;
695             break;                             << 753   }
696         }                                      << 
697         energyTR += energyVector1->GetLowEdgeE    754         energyTR += energyVector1->GetLowEdgeEnergy(iTransfer);
698       }                                           755       }
699     }                                             756     }
700   }                                               757   }
701   else                                            758   else
702   {                                               759   {
703     if(iTkin == 0)  // Tkin is too small, negl << 760     if(iTkin == 0) // Tkin is too small, neglect of TR photon generation
704     {                                             761     {
705       return energyTR;                            762       return energyTR;
706     }                                             763     }
707     else  // general case: Tkin between two ve << 764     else          // general case: Tkin between two vectors of the material
708     {     // use trivial mean half/half        << 765     {             // use trivial mean half/half
709       W1      = 0.5;                           << 766       W1 = 0.5;
710       W2      = 0.5;                           << 767       W2 = 0.5;
711       numOfTR = (G4int)G4Poisson((*energyVecto << 768      numOfTR = G4Poisson( (*energyVector1)(0)*W1 +
                                                   >> 769                           (*energyVector2)(0)*W2  );
712       if(numOfTR == 0)                            770       if(numOfTR == 0)
713       {                                           771       {
714         return energyTR;                          772         return energyTR;
715       }                                           773       }
716       else                                        774       else
717       {                                           775       {
718         G4cout << "It is still OK in GetEnergy << 776   G4cout<<"It is still OK in GetEnergyTR(int,int,int)"<<G4endl;
719         for(iTR = 0; iTR < numOfTR; ++iTR)     << 777         for(iTR=0;iTR<numOfTR;iTR++)
720         {                                         778         {
721           energyPos = ((*energyVector1)(0) * W << 779           energyPos = ((*energyVector1)(0)*W1+
722                       G4UniformRand();         << 780                        (*energyVector2)(0)*W2)*G4UniformRand();
723           for(iTransfer = 0; iTransfer < fBinT << 781           for(iTransfer=0;iTransfer<fBinTR-1;iTransfer++)
724           {                                    << 782       {
725             if(energyPos >= ((*energyVector1)( << 783             if(energyPos >= ((*energyVector1)(iTransfer)*W1+
726                              (*energyVector2)( << 784                              (*energyVector2)(iTransfer)*W2)) break;
727               break;                           << 785       }
728           }                                    << 786           energyTR += (energyVector1->GetLowEdgeEnergy(iTransfer))*W1+
729           energyTR += (energyVector1->GetLowEd << 787                       (energyVector2->GetLowEdgeEnergy(iTransfer))*W2;
730                       (energyVector2->GetLowEd << 788 
731         }                                         789         }
732       }                                           790       }
733     }                                             791     }
734   }                                               792   }
735                                                   793 
736   return energyTR;                                794   return energyTR;
737 }                                                 795 }
738                                                   796 
739 //////////////////////////////////////////////    797 ////////////////////////////////////////////////////////////////////////////
                                                   >> 798 //
740 // Test function for checking of PostStepDoIt     799 // Test function for checking of PostStepDoIt random preparation of TR photon
741 // theta angle relative to particle direction     800 // theta angle relative to particle direction
742 G4double G4ForwardXrayTR::GetThetaTR(G4int, G4 << 801 //
743                                                   802 
744 G4int G4ForwardXrayTR::GetSympsonNumber() { re << 
745                                                   803 
746 G4int G4ForwardXrayTR::GetBinTR() { return fBi << 804 G4double
                                                   >> 805 G4ForwardXrayTR::GetThetaTR(G4int, G4int, G4int) const
                                                   >> 806 {
                                                   >> 807   G4double theta = 0.0;
                                                   >> 808 
                                                   >> 809   return theta;
                                                   >> 810 }
747                                                   811 
748 G4double G4ForwardXrayTR::GetMinProtonTkin() { << 
749                                                   812 
750 G4double G4ForwardXrayTR::GetMaxProtonTkin() { << 
751                                                   813 
752 G4int G4ForwardXrayTR::GetTotBin() { return fT << 814 // end of G4ForwardXrayTR implementation file
                                                   >> 815 //
                                                   >> 816 ///////////////////////////////////////////////////////////////////////////
753                                                   817