Geant4 Cross Reference

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Geant4/processes/electromagnetic/standard/src/G4PAIPhotData.cc

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Differences between /processes/electromagnetic/standard/src/G4PAIPhotData.cc (Version 11.3.0) and /processes/electromagnetic/standard/src/G4PAIPhotData.cc (Version 10.6.p2)


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 25 //                                                 25 //
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 27 // -------------------------------------------     27 // -------------------------------------------------------------------
 28 //                                                 28 //
 29 // GEANT4 Class                                    29 // GEANT4 Class
 30 // File name:     G4PAIPhotData.cc                 30 // File name:     G4PAIPhotData.cc
 31 //                                                 31 //
 32 // Author:        V.Grichine based on G4PAIMod     32 // Author:        V.Grichine based on G4PAIModelData MT
 33 //                                                 33 //
 34 // Creation date: 07.10.2013                       34 // Creation date: 07.10.2013
 35 //                                                 35 //
 36 // Modifications:                                  36 // Modifications:
 37 //                                                 37 //
 38                                                    38 
 39 #include "G4PAIPhotData.hh"                        39 #include "G4PAIPhotData.hh"
 40 #include "G4PAIPhotModel.hh"                       40 #include "G4PAIPhotModel.hh"
 41                                                    41 
 42 #include "G4SystemOfUnits.hh"                      42 #include "G4SystemOfUnits.hh"
 43 #include "G4PhysicalConstants.hh"                  43 #include "G4PhysicalConstants.hh"
 44                                                    44 
 45 #include "G4PhysicsLogVector.hh"                   45 #include "G4PhysicsLogVector.hh"
 46 #include "G4PhysicsFreeVector.hh"                  46 #include "G4PhysicsFreeVector.hh"
 47 #include "G4PhysicsTable.hh"                       47 #include "G4PhysicsTable.hh"
 48 #include "G4MaterialCutsCouple.hh"                 48 #include "G4MaterialCutsCouple.hh"
 49 #include "G4ProductionCutsTable.hh"                49 #include "G4ProductionCutsTable.hh"
 50 #include "G4SandiaTable.hh"                        50 #include "G4SandiaTable.hh"
 51 #include "Randomize.hh"                            51 #include "Randomize.hh"
 52 #include "G4Poisson.hh"                            52 #include "G4Poisson.hh"
 53                                                    53 
 54 //////////////////////////////////////////////     54 ////////////////////////////////////////////////////////////////////////
 55                                                    55 
 56 using namespace std;                               56 using namespace std;
 57                                                    57 
 58 G4PAIPhotData::G4PAIPhotData(G4double tmin, G4     58 G4PAIPhotData::G4PAIPhotData(G4double tmin, G4double tmax, G4int ver)
 59 {                                                  59 { 
 60   const G4int nPerDecade     = 10;                 60   const G4int nPerDecade     = 10; 
 61   const G4double lowestTkin  = 50*keV;             61   const G4double lowestTkin  = 50*keV;
 62   const G4double highestTkin = 10*TeV;             62   const G4double highestTkin = 10*TeV;
 63                                                    63 
 64   // fPAIxSection.SetVerbose(ver);                 64   // fPAIxSection.SetVerbose(ver);
 65                                                    65 
 66   fLowestKineticEnergy  = std::max(tmin, lowes     66   fLowestKineticEnergy  = std::max(tmin, lowestTkin);
 67   fHighestKineticEnergy = tmax;                    67   fHighestKineticEnergy = tmax;
 68                                                    68 
 69   if(tmax < 10*fLowestKineticEnergy)               69   if(tmax < 10*fLowestKineticEnergy) 
 70   {                                                70   { 
 71     fHighestKineticEnergy = 10*fLowestKineticE     71     fHighestKineticEnergy = 10*fLowestKineticEnergy;
 72   }                                                72   } 
 73   else if(tmax > highestTkin)                      73   else if(tmax > highestTkin) 
 74   {                                                74   {
 75     fHighestKineticEnergy = std::max(highestTk     75     fHighestKineticEnergy = std::max(highestTkin, 10*fLowestKineticEnergy);
 76   }                                                76   }
 77   fTotBin = (G4int)(nPerDecade*                    77   fTotBin = (G4int)(nPerDecade*
 78         std::log10(fHighestKineticEnergy/fLowe     78         std::log10(fHighestKineticEnergy/fLowestKineticEnergy));
 79                                                    79 
 80   fParticleEnergyVector = new G4PhysicsLogVect     80   fParticleEnergyVector = new G4PhysicsLogVector(fLowestKineticEnergy,
 81              fHighestKineticEnergy,                81              fHighestKineticEnergy,
 82              fTotBin);                             82              fTotBin);
 83   if(0 < ver) {                                    83   if(0 < ver) {
 84     G4cout << "### G4PAIPhotData: Nbins= " <<      84     G4cout << "### G4PAIPhotData: Nbins= " << fTotBin
 85      << " Tmin(MeV)= " << fLowestKineticEnergy     85      << " Tmin(MeV)= " << fLowestKineticEnergy/MeV
 86      << " Tmax(GeV)= " << fHighestKineticEnerg     86      << " Tmax(GeV)= " << fHighestKineticEnergy/GeV 
 87      << "  tmin(keV)= " << tmin/keV << G4endl;     87      << "  tmin(keV)= " << tmin/keV << G4endl;
 88   }                                                88   }
 89 }                                                  89 }
 90                                                    90 
 91 //////////////////////////////////////////////     91 ////////////////////////////////////////////////////////////////////////////
 92                                                    92 
 93 G4PAIPhotData::~G4PAIPhotData()                    93 G4PAIPhotData::~G4PAIPhotData()
 94 {                                                  94 {
 95   //G4cout << "G4PAIPhotData::~G4PAIPhotData()     95   //G4cout << "G4PAIPhotData::~G4PAIPhotData() " << this << G4endl;
 96   std::size_t n = fPAIxscBank.size();          <<  96   size_t n = fPAIxscBank.size();
 97   if(0 < n)                                        97   if(0 < n) 
 98   {                                                98   {
 99     for(std::size_t i=0; i<n; ++i)             <<  99     for(size_t i=0; i<n; ++i) 
100     {                                             100     {
101       if(fPAIxscBank[i])                          101       if(fPAIxscBank[i]) 
102       {                                           102       {
103   fPAIxscBank[i]->clearAndDestroy();              103   fPAIxscBank[i]->clearAndDestroy();
104   delete fPAIxscBank[i];                          104   delete fPAIxscBank[i];
105   fPAIxscBank[i] = nullptr;                    << 105   fPAIxscBank[i] = 0;
106       }                                           106       }
107       if(fPAIdEdxBank[i])                         107       if(fPAIdEdxBank[i]) 
108       {                                           108       {
109   fPAIdEdxBank[i]->clearAndDestroy();             109   fPAIdEdxBank[i]->clearAndDestroy();
110   delete fPAIdEdxBank[i];                         110   delete fPAIdEdxBank[i];
111   fPAIdEdxBank[i] = nullptr;                   << 111   fPAIdEdxBank[i]= 0;
112       }                                           112       }
113       delete fdEdxTable[i];                       113       delete fdEdxTable[i];
114       delete fdNdxCutTable[i];                    114       delete fdNdxCutTable[i];
115       fdEdxTable[i] = nullptr;                 << 115       fdEdxTable[i] = 0;
116       fdNdxCutTable[i] = nullptr;              << 116       fdNdxCutTable[i] = 0;
117     }                                             117     }
118   }                                               118   }
119   delete fParticleEnergyVector;                   119   delete fParticleEnergyVector;
120   fParticleEnergyVector = nullptr;             << 120   fParticleEnergyVector = 0;
121   //G4cout << "G4PAIPhotData::~G4PAIPhotData()    121   //G4cout << "G4PAIPhotData::~G4PAIPhotData() done for " << this << G4endl;  
122 }                                                 122 }
123                                                   123 
124 //////////////////////////////////////////////    124 ///////////////////////////////////////////////////////////////////////////////
125                                                   125 
126 void G4PAIPhotData::Initialise(const G4Materia    126 void G4PAIPhotData::Initialise(const G4MaterialCutsCouple* couple,
127                                 G4double cut,     127                                 G4double cut, G4PAIPhotModel* model)
128 {                                                 128 {
129   G4ProductionCutsTable* theCoupleTable=          129   G4ProductionCutsTable* theCoupleTable=
130         G4ProductionCutsTable::GetProductionCu    130         G4ProductionCutsTable::GetProductionCutsTable();
131   G4int numOfCouples = (G4int)theCoupleTable-> << 131   size_t numOfCouples = theCoupleTable->GetTableSize();
132   G4int jMatCC;                                << 132   size_t jMatCC;
133                                                   133 
134   for (jMatCC = 0; jMatCC < numOfCouples; ++jM << 134   for (jMatCC = 0; jMatCC < numOfCouples; jMatCC++ )
135   {                                               135   {
136     if( couple == theCoupleTable->GetMaterialC    136     if( couple == theCoupleTable->GetMaterialCutsCouple(jMatCC) ) break;
137   }                                               137   }
138   if( jMatCC == numOfCouples && jMatCC > 0 ) - << 138   if( jMatCC == numOfCouples && jMatCC > 0 ) jMatCC--;
139                                                   139 
140   const vector<G4double>*  deltaCutInKineticEn    140   const vector<G4double>*  deltaCutInKineticEnergy = theCoupleTable->GetEnergyCutsVector(idxG4ElectronCut);
141   const vector<G4double>*  photonCutInKineticE    141   const vector<G4double>*  photonCutInKineticEnergy = theCoupleTable->GetEnergyCutsVector(idxG4GammaCut);
142   G4double deltaCutInKineticEnergyNow  = (*del    142   G4double deltaCutInKineticEnergyNow  = (*deltaCutInKineticEnergy)[jMatCC];
143   G4double photonCutInKineticEnergyNow = (*pho    143   G4double photonCutInKineticEnergyNow = (*photonCutInKineticEnergy)[jMatCC];
144   /*                                           << 144 
145   G4cout<<"G4PAIPhotData::Initialise: "<<"cut     145   G4cout<<"G4PAIPhotData::Initialise: "<<"cut = "<<cut/keV<<" keV; cutEl = "
146         <<deltaCutInKineticEnergyNow/keV<<" ke    146         <<deltaCutInKineticEnergyNow/keV<<" keV; cutPh = "
147   <<photonCutInKineticEnergyNow/keV<<" keV"<<G    147   <<photonCutInKineticEnergyNow/keV<<" keV"<<G4endl;
148   */                                           << 148 
149   // if( deltaCutInKineticEnergyNow != cut ) d    149   // if( deltaCutInKineticEnergyNow != cut ) deltaCutInKineticEnergyNow = cut; // exception??
150                                                   150 
151   auto dEdxCutVector =                         << 151   G4PhysicsLogVector* dEdxCutVector =
152     new G4PhysicsLogVector(fLowestKineticEnerg    152     new G4PhysicsLogVector(fLowestKineticEnergy,
153          fHighestKineticEnergy,                   153          fHighestKineticEnergy,
154          fTotBin);                                154          fTotBin);
155                                                   155 
156   auto dNdxCutVector =                         << 156   G4PhysicsLogVector* dNdxCutVector = 
157     new G4PhysicsLogVector(fLowestKineticEnerg    157     new G4PhysicsLogVector(fLowestKineticEnergy,
158          fHighestKineticEnergy,                   158          fHighestKineticEnergy,
159          fTotBin);                                159          fTotBin);
160   auto dNdxCutPhotonVector =                   << 160   G4PhysicsLogVector* dNdxCutPhotonVector = 
161     new G4PhysicsLogVector(fLowestKineticEnerg    161     new G4PhysicsLogVector(fLowestKineticEnergy,
162          fHighestKineticEnergy,                   162          fHighestKineticEnergy,
163          fTotBin);                                163          fTotBin);
164   auto dNdxCutPlasmonVector =                  << 164   G4PhysicsLogVector* dNdxCutPlasmonVector = 
165     new G4PhysicsLogVector(fLowestKineticEnerg    165     new G4PhysicsLogVector(fLowestKineticEnergy,
166          fHighestKineticEnergy,                   166          fHighestKineticEnergy,
167          fTotBin);                                167          fTotBin);
168                                                   168 
169   const G4Material* mat = couple->GetMaterial(    169   const G4Material* mat = couple->GetMaterial();     
170   fSandia.Initialize(const_cast<G4Material*>(m    170   fSandia.Initialize(const_cast<G4Material*>(mat));
171                                                   171 
172   auto PAItransferTable = new G4PhysicsTable(f << 172   G4PhysicsTable* PAItransferTable = new G4PhysicsTable(fTotBin+1);
173   auto PAIphotonTable = new G4PhysicsTable(fTo << 173   G4PhysicsTable* PAIphotonTable = new G4PhysicsTable(fTotBin+1);
174   auto PAIplasmonTable = new G4PhysicsTable(fT << 174   G4PhysicsTable* PAIplasmonTable = new G4PhysicsTable(fTotBin+1);
175                                                   175 
176   auto PAIdEdxTable = new G4PhysicsTable(fTotB << 176   G4PhysicsTable* PAIdEdxTable = new G4PhysicsTable(fTotBin+1);
177   auto dEdxMeanVector =                        << 177   G4PhysicsLogVector* dEdxMeanVector =
178     new G4PhysicsLogVector(fLowestKineticEnerg    178     new G4PhysicsLogVector(fLowestKineticEnergy,
179          fHighestKineticEnergy,                   179          fHighestKineticEnergy,
180          fTotBin);                                180          fTotBin);
181                                                   181 
182   // low energy Sandia interval                   182   // low energy Sandia interval
183   G4double Tmin = fSandia.GetSandiaMatTablePAI    183   G4double Tmin = fSandia.GetSandiaMatTablePAI(0,0); 
184                                                   184 
185   // energy safety                                185   // energy safety
186   const G4double deltaLow = 100.*eV;              186   const G4double deltaLow = 100.*eV; 
187                                                   187 
188   for (G4int i = 0; i <= fTotBin; ++i)            188   for (G4int i = 0; i <= fTotBin; ++i) 
189   {                                               189   {
190     G4double kinEnergy = fParticleEnergyVector    190     G4double kinEnergy = fParticleEnergyVector->Energy(i);
191     G4double Tmax = model->ComputeMaxEnergy(ki    191     G4double Tmax = model->ComputeMaxEnergy(kinEnergy);
192     G4double tau = kinEnergy/proton_mass_c2;      192     G4double tau = kinEnergy/proton_mass_c2;
193     G4double bg2 = tau*( tau + 2. );              193     G4double bg2 = tau*( tau + 2. );
194                                                   194 
195     if ( Tmax < Tmin + deltaLow ) Tmax = Tmin     195     if ( Tmax < Tmin + deltaLow ) Tmax = Tmin + deltaLow; 
196                                                   196 
197     fPAIxSection.Initialize( mat, Tmax, bg2, &    197     fPAIxSection.Initialize( mat, Tmax, bg2, &fSandia);
198                                                   198 
199     //G4cout << i << ". TransferMax(keV)= "<<     199     //G4cout << i << ". TransferMax(keV)= "<< Tmax/keV << "  cut(keV)= " 
200     //     << cut/keV << "  E(MeV)= " << kinEn    200     //     << cut/keV << "  E(MeV)= " << kinEnergy/MeV << G4endl;
201                                                   201 
202     G4int n = fPAIxSection.GetSplineSize();       202     G4int n = fPAIxSection.GetSplineSize();
203                                                   203 
204     auto transferVector = new G4PhysicsFreeVec << 204     G4PhysicsFreeVector* transferVector = new G4PhysicsFreeVector(n);
205     auto photonVector   = new G4PhysicsFreeVec << 205     G4PhysicsFreeVector* photonVector   = new G4PhysicsFreeVector(n);
206     auto plasmonVector  = new G4PhysicsFreeVec << 206     G4PhysicsFreeVector* plasmonVector  = new G4PhysicsFreeVector(n);
207                                                   207 
208     auto dEdxVector     = new G4PhysicsFreeVec << 208     G4PhysicsFreeVector* dEdxVector     = new G4PhysicsFreeVector(n);
209                                                   209 
210     for( G4int k = 0; k < n; k++ )                210     for( G4int k = 0; k < n; k++ )
211     {                                             211     {
212       G4double t = fPAIxSection.GetSplineEnerg    212       G4double t = fPAIxSection.GetSplineEnergy(k+1);
213                                                   213 
214       transferVector->PutValue(k , t,             214       transferVector->PutValue(k , t, 
215                                t*fPAIxSection.    215                                t*fPAIxSection.GetIntegralPAIxSection(k+1));
216       photonVector->PutValue(k , t,               216       photonVector->PutValue(k , t, 
217                                t*fPAIxSection.    217                                t*fPAIxSection.GetIntegralCerenkov(k+1));
218       plasmonVector->PutValue(k , t,              218       plasmonVector->PutValue(k , t, 
219                                t*fPAIxSection.    219                                t*fPAIxSection.GetIntegralPlasmon(k+1));
220                                                   220 
221       dEdxVector->PutValue(k, t, fPAIxSection.    221       dEdxVector->PutValue(k, t, fPAIxSection.GetIntegralPAIdEdx(k+1));
222     }                                             222     }
223     // G4cout << *transferVector << G4endl;       223     // G4cout << *transferVector << G4endl;
224                                                   224 
225     G4double ionloss = std::max(fPAIxSection.G << 225     G4double ionloss = fPAIxSection.GetMeanEnergyLoss();//  total <dE/dx>
                                                   >> 226 
                                                   >> 227     if(ionloss < 0.0) ionloss = 0.0; 
                                                   >> 228 
226     dEdxMeanVector->PutValue(i,ionloss);          229     dEdxMeanVector->PutValue(i,ionloss);
227                                                   230 
228     G4double dNdxCut = transferVector->Value(d    231     G4double dNdxCut = transferVector->Value(deltaCutInKineticEnergyNow)/deltaCutInKineticEnergyNow;
229     G4double dNdxCutPhoton = photonVector->Val    232     G4double dNdxCutPhoton = photonVector->Value(photonCutInKineticEnergyNow)/photonCutInKineticEnergyNow;
230     G4double dNdxCutPlasmon = plasmonVector->V    233     G4double dNdxCutPlasmon = plasmonVector->Value(deltaCutInKineticEnergyNow)/deltaCutInKineticEnergyNow;
231                                                   234 
232     G4double dEdxCut = dEdxVector->Value(cut)/    235     G4double dEdxCut = dEdxVector->Value(cut)/cut;
233     //G4cout << "i= " << i << " x= " << dNdxCu    236     //G4cout << "i= " << i << " x= " << dNdxCut << G4endl;
234                                                   237 
235     if(dNdxCut < 0.0) { dNdxCut = 0.0; }          238     if(dNdxCut < 0.0) { dNdxCut = 0.0; }
236     if(dNdxCutPhoton < 0.0) { dNdxCutPhoton =     239     if(dNdxCutPhoton < 0.0) { dNdxCutPhoton = 0.0; }
237     if(dNdxCutPlasmon < 0.0) { dNdxCutPlasmon     240     if(dNdxCutPlasmon < 0.0) { dNdxCutPlasmon = 0.0; }
238                                                   241 
239     dNdxCutVector->PutValue(i, dNdxCut);          242     dNdxCutVector->PutValue(i, dNdxCut);
240     dNdxCutPhotonVector->PutValue(i, dNdxCutPh    243     dNdxCutPhotonVector->PutValue(i, dNdxCutPhoton);
241     dNdxCutPlasmonVector->PutValue(i, dNdxCutP    244     dNdxCutPlasmonVector->PutValue(i, dNdxCutPlasmon);
242                                                   245 
243     dEdxCutVector->PutValue(i, dEdxCut);          246     dEdxCutVector->PutValue(i, dEdxCut);
244                                                   247 
245     PAItransferTable->insertAt(i,transferVecto    248     PAItransferTable->insertAt(i,transferVector);
246     PAIphotonTable->insertAt(i,photonVector);     249     PAIphotonTable->insertAt(i,photonVector);
247     PAIplasmonTable->insertAt(i,plasmonVector)    250     PAIplasmonTable->insertAt(i,plasmonVector);
248     PAIdEdxTable->insertAt(i,dEdxVector);         251     PAIdEdxTable->insertAt(i,dEdxVector);
249                                                   252 
250   } // end of Tkin loop                           253   } // end of Tkin loop
251                                                   254 
252   fPAIxscBank.push_back(PAItransferTable);        255   fPAIxscBank.push_back(PAItransferTable);
253   fPAIphotonBank.push_back(PAIphotonTable);       256   fPAIphotonBank.push_back(PAIphotonTable);
254   fPAIplasmonBank.push_back(PAIplasmonTable);     257   fPAIplasmonBank.push_back(PAIplasmonTable);
255                                                   258 
256   fPAIdEdxBank.push_back(PAIdEdxTable);           259   fPAIdEdxBank.push_back(PAIdEdxTable);
257   fdEdxTable.push_back(dEdxMeanVector);           260   fdEdxTable.push_back(dEdxMeanVector);
258                                                   261 
259   fdNdxCutTable.push_back(dNdxCutVector);         262   fdNdxCutTable.push_back(dNdxCutVector);
260   fdNdxCutPhotonTable.push_back(dNdxCutPhotonV    263   fdNdxCutPhotonTable.push_back(dNdxCutPhotonVector);
261   fdNdxCutPlasmonTable.push_back(dNdxCutPlasmo    264   fdNdxCutPlasmonTable.push_back(dNdxCutPlasmonVector);
262                                                   265 
263   fdEdxCutTable.push_back(dEdxCutVector);         266   fdEdxCutTable.push_back(dEdxCutVector);
264 }                                                 267 }
265                                                   268 
266 //////////////////////////////////////////////    269 //////////////////////////////////////////////////////////////////////////////
267                                                   270 
268 G4double G4PAIPhotData::DEDXPerVolume(G4int co    271 G4double G4PAIPhotData::DEDXPerVolume(G4int coupleIndex, G4double scaledTkin,
269        G4double cut) const                        272        G4double cut) const
270 {                                                 273 {
271   // VI: iPlace is the low edge index of the b    274   // VI: iPlace is the low edge index of the bin
272   // iPlace is in interval from 0 to (N-1)        275   // iPlace is in interval from 0 to (N-1)
273   std::size_t iPlace = fParticleEnergyVector-> << 276   size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
274   std::size_t nPlace = fParticleEnergyVector-> << 277   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
275                                                   278 
276   G4bool one = true;                              279   G4bool one = true;
277   if(scaledTkin >= fParticleEnergyVector->Ener    280   if(scaledTkin >= fParticleEnergyVector->Energy(nPlace)) { iPlace = nPlace; }
278   else if(scaledTkin > fParticleEnergyVector->    281   else if(scaledTkin > fParticleEnergyVector->Energy(0)) { 
279     one = false;                                  282     one = false; 
280   }                                               283   }
281                                                   284 
282   // VI: apply interpolation of the vector        285   // VI: apply interpolation of the vector
283   G4double dEdx = fdEdxTable[coupleIndex]->Val    286   G4double dEdx = fdEdxTable[coupleIndex]->Value(scaledTkin);
284   G4double del  = (*(fPAIdEdxBank[coupleIndex]    287   G4double del  = (*(fPAIdEdxBank[coupleIndex]))(iPlace)->Value(cut);
285   if(!one) {                                      288   if(!one) {
286     G4double del2 = (*(fPAIdEdxBank[coupleInde    289     G4double del2 = (*(fPAIdEdxBank[coupleIndex]))(iPlace+1)->Value(cut);
287     G4double E1 = fParticleEnergyVector->Energ    290     G4double E1 = fParticleEnergyVector->Energy(iPlace); 
288     G4double E2 = fParticleEnergyVector->Energ    291     G4double E2 = fParticleEnergyVector->Energy(iPlace+1);
289     G4double W  = 1.0/(E2 - E1);                  292     G4double W  = 1.0/(E2 - E1);
290     G4double W1 = (E2 - scaledTkin)*W;            293     G4double W1 = (E2 - scaledTkin)*W;
291     G4double W2 = (scaledTkin - E1)*W;            294     G4double W2 = (scaledTkin - E1)*W;
292     del *= W1;                                    295     del *= W1;
293     del += W2*del2;                               296     del += W2*del2;
294   }                                               297   }
295   dEdx -= del;                                    298   dEdx -= del;
296                                                   299 
297   if( dEdx < 0.) { dEdx = 0.; }                   300   if( dEdx < 0.) { dEdx = 0.; }
298   return dEdx;                                    301   return dEdx;
299 }                                                 302 }
300                                                   303 
301 //////////////////////////////////////////////    304 /////////////////////////////////////////////////////////////////////////
302                                                   305 
303 G4double                                          306 G4double 
304 G4PAIPhotData::CrossSectionPerVolume(G4int cou    307 G4PAIPhotData::CrossSectionPerVolume(G4int coupleIndex, 
305               G4double scaledTkin,                308               G4double scaledTkin,
306               G4double tcut, G4double tmax) co    309               G4double tcut, G4double tmax) const
307 {                                                 310 {
308   G4double cross, xscEl, xscEl2, xscPh, xscPh2    311   G4double cross, xscEl, xscEl2, xscPh, xscPh2;
309                                                   312 
310   cross=tcut+tmax;                                313   cross=tcut+tmax;
311                                                   314 
312   // iPlace is in interval from 0 to (N-1)        315   // iPlace is in interval from 0 to (N-1)
313                                                   316 
314   std::size_t iPlace = fParticleEnergyVector-> << 317   size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
315   std::size_t nPlace = fParticleEnergyVector-> << 318   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
316                                                   319 
317   G4bool one = true;                              320   G4bool one = true;
318                                                   321 
319   if(      scaledTkin >= fParticleEnergyVector    322   if(      scaledTkin >= fParticleEnergyVector->Energy(nPlace))  iPlace = nPlace; 
320   else if( scaledTkin > fParticleEnergyVector-    323   else if( scaledTkin > fParticleEnergyVector->Energy(0)      )   one   = false; 
321                                                   324   
322                                                   325 
323   xscEl2 = (*fdNdxCutPlasmonTable[coupleIndex]    326   xscEl2 = (*fdNdxCutPlasmonTable[coupleIndex])(iPlace);
324   xscPh2 = (*fdNdxCutPhotonTable[coupleIndex])    327   xscPh2 = (*fdNdxCutPhotonTable[coupleIndex])(iPlace);
325                                                   328 
326   xscPh = xscPh2;                                 329   xscPh = xscPh2;
327   xscEl = xscEl2;                                 330   xscEl = xscEl2;
328                                                   331 
329   cross  = xscPh + xscEl;                         332   cross  = xscPh + xscEl;
330                                                   333  
331   if( !one )                                      334   if( !one ) 
332   {                                               335   {
333     xscEl2 = (*fdNdxCutPlasmonTable[coupleInde    336     xscEl2 = (*fdNdxCutPlasmonTable[coupleIndex])(iPlace+1);
334                                                   337 
335     G4double E1 = fParticleEnergyVector->Energ    338     G4double E1 = fParticleEnergyVector->Energy(iPlace); 
336     G4double E2 = fParticleEnergyVector->Energ    339     G4double E2 = fParticleEnergyVector->Energy(iPlace+1);
337                                                   340 
338     G4double W  = 1.0/(E2 - E1);                  341     G4double W  = 1.0/(E2 - E1);
339     G4double W1 = (E2 - scaledTkin)*W;            342     G4double W1 = (E2 - scaledTkin)*W;
340     G4double W2 = (scaledTkin - E1)*W;            343     G4double W2 = (scaledTkin - E1)*W;
341                                                   344 
342     xscEl *= W1;                                  345     xscEl *= W1;
343     xscEl += W2*xscEl2;                           346     xscEl += W2*xscEl2;
344                                                   347 
345     xscPh2 = (*fdNdxCutPhotonTable[coupleIndex    348     xscPh2 = (*fdNdxCutPhotonTable[coupleIndex])(iPlace+1);
346                                                   349 
347     E1 = fParticleEnergyVector->Energy(iPlace)    350     E1 = fParticleEnergyVector->Energy(iPlace); 
348     E2 = fParticleEnergyVector->Energy(iPlace+    351     E2 = fParticleEnergyVector->Energy(iPlace+1);
349                                                   352 
350     W  = 1.0/(E2 - E1);                           353     W  = 1.0/(E2 - E1);
351     W1 = (E2 - scaledTkin)*W;                     354     W1 = (E2 - scaledTkin)*W;
352     W2 = (scaledTkin - E1)*W;                     355     W2 = (scaledTkin - E1)*W;
353                                                   356 
354     xscPh *= W1;                                  357     xscPh *= W1;
355     xscPh += W2*xscPh2;                           358     xscPh += W2*xscPh2;
356                                                   359 
357     cross = xscEl + xscPh;                        360     cross = xscEl + xscPh;
358   }                                               361   }
359   if( cross < 0.0)  cross = 0.0;                  362   if( cross < 0.0)  cross = 0.0; 
360                                                   363 
361   return cross;                                   364   return cross;
362 }                                                 365 }
363                                                   366 
364 //////////////////////////////////////////////    367 /////////////////////////////////////////////////////////////////////////
365                                                   368 
366 G4double                                          369 G4double 
367 G4PAIPhotData::GetPlasmonRatio(G4int coupleInd    370 G4PAIPhotData::GetPlasmonRatio(G4int coupleIndex, G4double scaledTkin) const
368 {                                                 371 {
369   G4double cross, xscEl, xscEl2, xscPh, xscPh2    372   G4double cross, xscEl, xscEl2, xscPh, xscPh2, plRatio;
370   // iPlace is in interval from 0 to (N-1)        373   // iPlace is in interval from 0 to (N-1)
371                                                   374 
372   std::size_t iPlace = fParticleEnergyVector-> << 375   size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
373   std::size_t nPlace = fParticleEnergyVector-> << 376   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
374                                                   377 
375   G4bool one = true;                              378   G4bool one = true;
376                                                   379 
377   if(      scaledTkin >= fParticleEnergyVector    380   if(      scaledTkin >= fParticleEnergyVector->Energy(nPlace))  iPlace = nPlace; 
378   else if( scaledTkin > fParticleEnergyVector-    381   else if( scaledTkin > fParticleEnergyVector->Energy(0)      )   one   = false; 
379                                                   382   
380                                                   383 
381   xscEl2 = (*fdNdxCutPlasmonTable[coupleIndex]    384   xscEl2 = (*fdNdxCutPlasmonTable[coupleIndex])(iPlace);
382   xscPh2 = (*fdNdxCutPhotonTable[coupleIndex])    385   xscPh2 = (*fdNdxCutPhotonTable[coupleIndex])(iPlace);
383                                                   386 
384   xscPh = xscPh2;                                 387   xscPh = xscPh2;
385   xscEl = xscEl2;                                 388   xscEl = xscEl2;
386                                                   389 
387   cross  = xscPh + xscEl;                         390   cross  = xscPh + xscEl;
388                                                   391  
389   if( !one )                                      392   if( !one ) 
390   {                                               393   {
391     xscEl2 = (*fdNdxCutPlasmonTable[coupleInde    394     xscEl2 = (*fdNdxCutPlasmonTable[coupleIndex])(iPlace+1);
392                                                   395 
393     G4double E1 = fParticleEnergyVector->Energ    396     G4double E1 = fParticleEnergyVector->Energy(iPlace); 
394     G4double E2 = fParticleEnergyVector->Energ    397     G4double E2 = fParticleEnergyVector->Energy(iPlace+1);
395                                                   398 
396     G4double W  = 1.0/(E2 - E1);                  399     G4double W  = 1.0/(E2 - E1);
397     G4double W1 = (E2 - scaledTkin)*W;            400     G4double W1 = (E2 - scaledTkin)*W;
398     G4double W2 = (scaledTkin - E1)*W;            401     G4double W2 = (scaledTkin - E1)*W;
399                                                   402 
400     xscEl *= W1;                                  403     xscEl *= W1;
401     xscEl += W2*xscEl2;                           404     xscEl += W2*xscEl2;
402                                                   405 
403     xscPh2 = (*fdNdxCutPhotonTable[coupleIndex    406     xscPh2 = (*fdNdxCutPhotonTable[coupleIndex])(iPlace+1);
404                                                   407 
405     E1 = fParticleEnergyVector->Energy(iPlace)    408     E1 = fParticleEnergyVector->Energy(iPlace); 
406     E2 = fParticleEnergyVector->Energy(iPlace+    409     E2 = fParticleEnergyVector->Energy(iPlace+1);
407                                                   410 
408     W  = 1.0/(E2 - E1);                           411     W  = 1.0/(E2 - E1);
409     W1 = (E2 - scaledTkin)*W;                     412     W1 = (E2 - scaledTkin)*W;
410     W2 = (scaledTkin - E1)*W;                     413     W2 = (scaledTkin - E1)*W;
411                                                   414 
412     xscPh *= W1;                                  415     xscPh *= W1;
413     xscPh += W2*xscPh2;                           416     xscPh += W2*xscPh2;
414                                                   417 
415     cross = xscEl + xscPh;                        418     cross = xscEl + xscPh;
416   }                                               419   }
417   if( cross <= 0.0)                               420   if( cross <= 0.0)  
418   {                                               421   {
419     plRatio = 2.0;                                422     plRatio = 2.0; 
420   }                                               423   }
421   else                                            424   else
422   {                                               425   {
423     plRatio = xscEl/cross;                        426     plRatio = xscEl/cross;
424                                                   427 
425     if( plRatio > 1. || plRatio < 0.) plRatio     428     if( plRatio > 1. || plRatio < 0.) plRatio = 2.0;
426   }                                               429   }
427   return plRatio;                                 430   return plRatio;
428 }                                                 431 }
429                                                   432 
430 //////////////////////////////////////////////    433 ///////////////////////////////////////////////////////////////////////
431                                                   434 
432 G4double G4PAIPhotData::SampleAlongStepTransfe    435 G4double G4PAIPhotData::SampleAlongStepTransfer(G4int coupleIndex, 
433                                                   436                                                  G4double kinEnergy,
434              G4double scaledTkin,                 437              G4double scaledTkin,
435              G4double stepFactor) const           438              G4double stepFactor) const
436 {                                                 439 {
437   G4double loss = 0.0;                            440   G4double loss = 0.0;
438   G4double omega;                                 441   G4double omega; 
439   G4double position, E1, E2, W1, W2, W, dNdxCu    442   G4double position, E1, E2, W1, W2, W, dNdxCut1, dNdxCut2, meanNumber;
440                                                   443 
441   std::size_t iPlace = fParticleEnergyVector-> << 444   size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
442   std::size_t nPlace = fParticleEnergyVector-> << 445   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
443                                                   446  
444   G4bool one = true;                              447   G4bool one = true;
445                                                   448 
446   if     (scaledTkin >= fParticleEnergyVector-    449   if     (scaledTkin >= fParticleEnergyVector->Energy(nPlace)) iPlace = nPlace; 
447   else if(scaledTkin > fParticleEnergyVector->    450   else if(scaledTkin > fParticleEnergyVector->Energy(0))          one = false; 
448                                                   451 
449   G4PhysicsLogVector* vcut = fdNdxCutTable[cou    452   G4PhysicsLogVector* vcut = fdNdxCutTable[coupleIndex];
450   G4PhysicsVector*      v1 = (*(fPAIxscBank[co    453   G4PhysicsVector*      v1 = (*(fPAIxscBank[coupleIndex]))(iPlace);
451   G4PhysicsVector*      v2 = nullptr;          << 454   G4PhysicsVector*      v2 = 0;
452                                                   455 
453   dNdxCut1    = (*vcut)[iPlace];                  456   dNdxCut1    = (*vcut)[iPlace];
454   G4double e1 = v1->Energy(0);                    457   G4double e1 = v1->Energy(0);
455   G4double e2 = e1;                               458   G4double e2 = e1;
456                                                   459 
457   G4double meanN1 = ((*v1)[0]/e1 - dNdxCut1)*s    460   G4double meanN1 = ((*v1)[0]/e1 - dNdxCut1)*stepFactor;
458                                                   461 
459   meanNumber = meanN1;                            462   meanNumber = meanN1;
460                                                   463 
461   // G4cout<<"iPlace = "<<iPlace<< " meanN1= "    464   // G4cout<<"iPlace = "<<iPlace<< " meanN1= " << meanN1 
462   //  <<"    (*v1)[0]/e1 = "<<(*v1)[0]/e1<< "     465   //  <<"    (*v1)[0]/e1 = "<<(*v1)[0]/e1<< " dNdxCut1= " << dNdxCut1 << G4endl;
463                                                   466 
464   dNdxCut2 = dNdxCut1;                            467   dNdxCut2 = dNdxCut1;
465   W1 = 1.0;                                       468   W1 = 1.0;
466   W2 = 0.0;                                       469   W2 = 0.0;
467   if(!one)                                        470   if(!one) 
468   {                                               471   {
469     v2 = (*(fPAIxscBank[coupleIndex]))(iPlace+    472     v2 = (*(fPAIxscBank[coupleIndex]))(iPlace+1);
470     dNdxCut2 = (*vcut)[iPlace+1];                 473     dNdxCut2 = (*vcut)[iPlace+1];
471     e2 = v2->Energy(0);                           474     e2 = v2->Energy(0);
472                                                   475 
473     G4double meanN2 = ((*v2)[0]/e2 - dNdxCut2)    476     G4double meanN2 = ((*v2)[0]/e2 - dNdxCut2)*stepFactor;
474                                                   477 
475     E1 = fParticleEnergyVector->Energy(iPlace)    478     E1 = fParticleEnergyVector->Energy(iPlace); 
476     E2 = fParticleEnergyVector->Energy(iPlace+    479     E2 = fParticleEnergyVector->Energy(iPlace+1);
477     W = 1.0/(E2 - E1);                            480     W = 1.0/(E2 - E1);
478     W1 = (E2 - scaledTkin)*W;                     481     W1 = (E2 - scaledTkin)*W;
479     W2 = (scaledTkin - E1)*W;                     482     W2 = (scaledTkin - E1)*W;
480     meanNumber = W1*meanN1 + W2*meanN2;           483     meanNumber = W1*meanN1 + W2*meanN2;
481                                                   484 
482     //G4cout<<"meanN= " <<  meanNumber << " me    485     //G4cout<<"meanN= " <<  meanNumber << " meanN2= " << meanN2 
483     //    << " dNdxCut2= " << dNdxCut2 << G4en    486     //    << " dNdxCut2= " << dNdxCut2 << G4endl;
484   }                                               487   }
485   if( meanNumber <= 0.0) return 0.0;              488   if( meanNumber <= 0.0) return 0.0; 
486                                                   489 
487   G4int numOfCollisions = (G4int)G4Poisson(mea << 490   G4int numOfCollisions = G4Poisson(meanNumber);
488                                                   491 
489   //G4cout << "N= " << numOfCollisions << G4en    492   //G4cout << "N= " << numOfCollisions << G4endl;
490                                                   493 
491   if( 0 == numOfCollisions) return 0.0;           494   if( 0 == numOfCollisions) return 0.0; 
492                                                   495 
493   for(G4int i=0; i< numOfCollisions; ++i)         496   for(G4int i=0; i< numOfCollisions; ++i) 
494   {                                               497   {
495     G4double rand = G4UniformRand();              498     G4double rand = G4UniformRand();
496     position = dNdxCut1 + ((*v1)[0]/e1 - dNdxC    499     position = dNdxCut1 + ((*v1)[0]/e1 - dNdxCut1)*rand;
497     omega = GetEnergyTransfer(coupleIndex, iPl    500     omega = GetEnergyTransfer(coupleIndex, iPlace, position);
498                                                   501 
499     //G4cout << "omega(keV)= " << omega/keV <<    502     //G4cout << "omega(keV)= " << omega/keV << G4endl;
500                                                   503 
501     if(!one)                                      504     if(!one) 
502     {                                             505     {
503       position = dNdxCut2 + ((*v2)[0]/e2 - dNd    506       position = dNdxCut2 + ((*v2)[0]/e2 - dNdxCut2)*rand;
504       G4double omega2 = GetEnergyTransfer(coup    507       G4double omega2 = GetEnergyTransfer(coupleIndex, iPlace+1, position);
505       omega = omega*W1 + omega2*W2;               508       omega = omega*W1 + omega2*W2;
506     }                                             509     }
507     //G4cout << "omega(keV)= " << omega/keV <<    510     //G4cout << "omega(keV)= " << omega/keV << G4endl;
508                                                   511 
509     loss += omega;                                512     loss += omega;
510     if( loss > kinEnergy) { break; }              513     if( loss > kinEnergy) { break; }
511   }                                               514   }
512                                                   515   
513   // G4cout<<"PAIPhotData AlongStepLoss = "<<l    516   // G4cout<<"PAIPhotData AlongStepLoss = "<<loss/keV<<" keV, on step = "
514   //<<step/mm<<" mm"<<G4endl;                     517   //<<step/mm<<" mm"<<G4endl; 
515                                                   518 
516   if     ( loss > kinEnergy) loss = kinEnergy;    519   if     ( loss > kinEnergy) loss = kinEnergy; 
517   else if( loss < 0.)        loss = 0.;           520   else if( loss < 0.)        loss = 0.;
518                                                   521  
519   return loss;                                    522   return loss;
520 }                                                 523 }
521                                                   524 
522 //////////////////////////////////////////////    525 ////////////////////////////////////////////////////////////////////////
523                                                   526 
524 G4double G4PAIPhotData::SampleAlongStepPhotonT    527 G4double G4PAIPhotData::SampleAlongStepPhotonTransfer(G4int coupleIndex, 
525                                                   528                                                  G4double kinEnergy,
526              G4double scaledTkin,                 529              G4double scaledTkin,
527              G4double stepFactor) const           530              G4double stepFactor) const
528 {                                                 531 {
529   G4double loss = 0.0;                            532   G4double loss = 0.0;
530   G4double omega;                                 533   G4double omega; 
531   G4double position, E1, E2, W1, W2, W, dNdxCu    534   G4double position, E1, E2, W1, W2, W, dNdxCut1, dNdxCut2, meanNumber;
532                                                   535 
533   std::size_t iPlace = fParticleEnergyVector-> << 536   size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
534   std::size_t nPlace = fParticleEnergyVector-> << 537   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
535                                                   538  
536   G4bool one = true;                              539   G4bool one = true;
537                                                   540 
538   if     (scaledTkin >= fParticleEnergyVector-    541   if     (scaledTkin >= fParticleEnergyVector->Energy(nPlace)) iPlace = nPlace; 
539   else if(scaledTkin > fParticleEnergyVector->    542   else if(scaledTkin > fParticleEnergyVector->Energy(0))          one = false; 
540                                                   543 
541   G4PhysicsLogVector* vcut = fdNdxCutPhotonTab    544   G4PhysicsLogVector* vcut = fdNdxCutPhotonTable[coupleIndex];
542   G4PhysicsVector*      v1 = (*(fPAIphotonBank    545   G4PhysicsVector*      v1 = (*(fPAIphotonBank[coupleIndex]))(iPlace);
543   G4PhysicsVector*      v2 = nullptr;          << 546   G4PhysicsVector*      v2 = 0;
544                                                   547 
545   dNdxCut1    = (*vcut)[iPlace];                  548   dNdxCut1    = (*vcut)[iPlace];
546   G4double e1 = v1->Energy(0);                    549   G4double e1 = v1->Energy(0);
547   G4double e2 = e1;                               550   G4double e2 = e1;
548                                                   551 
549   G4double meanN1 = ((*v1)[0]/e1 - dNdxCut1)*s    552   G4double meanN1 = ((*v1)[0]/e1 - dNdxCut1)*stepFactor;
550                                                   553 
551   meanNumber = meanN1;                            554   meanNumber = meanN1;
552                                                   555 
553   // G4cout<<"iPlace = "<<iPlace<< " meanN1= "    556   // G4cout<<"iPlace = "<<iPlace<< " meanN1= " << meanN1 
554   //  <<"    (*v1)[0]/e1 = "<<(*v1)[0]/e1<< "     557   //  <<"    (*v1)[0]/e1 = "<<(*v1)[0]/e1<< " dNdxCut1= " << dNdxCut1 << G4endl;
555                                                   558 
556   dNdxCut2 = dNdxCut1;                            559   dNdxCut2 = dNdxCut1;
557   W1 = 1.0;                                       560   W1 = 1.0;
558   W2 = 0.0;                                       561   W2 = 0.0;
559   if(!one)                                        562   if(!one) 
560   {                                               563   {
561     v2 = (*(fPAIphotonBank[coupleIndex]))(iPla    564     v2 = (*(fPAIphotonBank[coupleIndex]))(iPlace+1);
562     dNdxCut2 = (*vcut)[iPlace+1];                 565     dNdxCut2 = (*vcut)[iPlace+1];
563     e2 = v2->Energy(0);                           566     e2 = v2->Energy(0);
564                                                   567 
565     G4double meanN2 = ((*v2)[0]/e2 - dNdxCut2)    568     G4double meanN2 = ((*v2)[0]/e2 - dNdxCut2)*stepFactor;
566                                                   569 
567     E1 = fParticleEnergyVector->Energy(iPlace)    570     E1 = fParticleEnergyVector->Energy(iPlace); 
568     E2 = fParticleEnergyVector->Energy(iPlace+    571     E2 = fParticleEnergyVector->Energy(iPlace+1);
569     W = 1.0/(E2 - E1);                            572     W = 1.0/(E2 - E1);
570     W1 = (E2 - scaledTkin)*W;                     573     W1 = (E2 - scaledTkin)*W;
571     W2 = (scaledTkin - E1)*W;                     574     W2 = (scaledTkin - E1)*W;
572     meanNumber = W1*meanN1 + W2*meanN2;           575     meanNumber = W1*meanN1 + W2*meanN2;
573                                                   576 
574     //G4cout<<"meanN= " <<  meanNumber << " me    577     //G4cout<<"meanN= " <<  meanNumber << " meanN2= " << meanN2 
575     //    << " dNdxCut2= " << dNdxCut2 << G4en    578     //    << " dNdxCut2= " << dNdxCut2 << G4endl;
576   }                                               579   }
577   if( meanNumber <= 0.0) return 0.0;              580   if( meanNumber <= 0.0) return 0.0; 
578                                                   581 
579   G4int numOfCollisions = (G4int)G4Poisson(mea << 582   G4int numOfCollisions = G4Poisson(meanNumber);
580                                                   583 
581   //G4cout << "N= " << numOfCollisions << G4en    584   //G4cout << "N= " << numOfCollisions << G4endl;
582                                                   585 
583   if( 0 == numOfCollisions) return 0.0;           586   if( 0 == numOfCollisions) return 0.0; 
584                                                   587 
585   for(G4int i=0; i< numOfCollisions; ++i)         588   for(G4int i=0; i< numOfCollisions; ++i) 
586   {                                               589   {
587     G4double rand = G4UniformRand();              590     G4double rand = G4UniformRand();
588     position = dNdxCut1 + ((*v1)[0]/e1 - dNdxC    591     position = dNdxCut1 + ((*v1)[0]/e1 - dNdxCut1)*rand;
589     omega = GetEnergyPhotonTransfer(coupleInde    592     omega = GetEnergyPhotonTransfer(coupleIndex, iPlace, position);
590                                                   593 
591     //G4cout << "omega(keV)= " << omega/keV <<    594     //G4cout << "omega(keV)= " << omega/keV << G4endl;
592                                                   595 
593     if(!one)                                      596     if(!one) 
594     {                                             597     {
595       position = dNdxCut2 + ((*v2)[0]/e2 - dNd    598       position = dNdxCut2 + ((*v2)[0]/e2 - dNdxCut2)*rand;
596       G4double omega2 = GetEnergyPhotonTransfe    599       G4double omega2 = GetEnergyPhotonTransfer(coupleIndex, iPlace+1, position);
597       omega = omega*W1 + omega2*W2;               600       omega = omega*W1 + omega2*W2;
598     }                                             601     }
599     //G4cout << "omega(keV)= " << omega/keV <<    602     //G4cout << "omega(keV)= " << omega/keV << G4endl;
600                                                   603 
601     loss += omega;                                604     loss += omega;
602     if( loss > kinEnergy) { break; }              605     if( loss > kinEnergy) { break; }
603   }                                               606   }
604                                                   607   
605   // G4cout<<"PAIPhotData AlongStepLoss = "<<l    608   // G4cout<<"PAIPhotData AlongStepLoss = "<<loss/keV<<" keV, on step = "
606   //<<step/mm<<" mm"<<G4endl;                     609   //<<step/mm<<" mm"<<G4endl; 
607                                                   610 
608   if     ( loss > kinEnergy) loss = kinEnergy;    611   if     ( loss > kinEnergy) loss = kinEnergy; 
609   else if( loss < 0.)        loss = 0.;           612   else if( loss < 0.)        loss = 0.;
610                                                   613  
611   return loss;                                    614   return loss;
612 }                                                 615 }
613                                                   616 
614 //////////////////////////////////////////////    617 //////////////////////////////////////////////////////////////////
615                                                   618 
616 G4double G4PAIPhotData::SampleAlongStepPlasmon    619 G4double G4PAIPhotData::SampleAlongStepPlasmonTransfer(G4int coupleIndex, 
617                                                   620                                                  G4double kinEnergy,
618              G4double scaledTkin,                 621              G4double scaledTkin,
619              G4double stepFactor) const           622              G4double stepFactor) const
620 {                                                 623 {
621   G4double loss = 0.0;                            624   G4double loss = 0.0;
622   G4double omega;                                 625   G4double omega; 
623   G4double position, E1, E2, W1, W2, W, dNdxCu    626   G4double position, E1, E2, W1, W2, W, dNdxCut1, dNdxCut2, meanNumber;
624                                                   627 
625   std::size_t iPlace = fParticleEnergyVector-> << 628   size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
626   std::size_t nPlace = fParticleEnergyVector-> << 629   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
627                                                   630  
628   G4bool one = true;                              631   G4bool one = true;
629                                                   632 
630   if     (scaledTkin >= fParticleEnergyVector-    633   if     (scaledTkin >= fParticleEnergyVector->Energy(nPlace)) iPlace = nPlace; 
631   else if(scaledTkin > fParticleEnergyVector->    634   else if(scaledTkin > fParticleEnergyVector->Energy(0))          one = false; 
632                                                   635 
633   G4PhysicsLogVector* vcut = fdNdxCutPlasmonTa    636   G4PhysicsLogVector* vcut = fdNdxCutPlasmonTable[coupleIndex];
634   G4PhysicsVector*      v1 = (*(fPAIplasmonBan    637   G4PhysicsVector*      v1 = (*(fPAIplasmonBank[coupleIndex]))(iPlace);
635   G4PhysicsVector*      v2 = nullptr;          << 638   G4PhysicsVector*      v2 = 0;
636                                                   639 
637   dNdxCut1    = (*vcut)[iPlace];                  640   dNdxCut1    = (*vcut)[iPlace];
638   G4double e1 = v1->Energy(0);                    641   G4double e1 = v1->Energy(0);
639   G4double e2 = e1;                               642   G4double e2 = e1;
640                                                   643 
641   G4double meanN1 = ((*v1)[0]/e1 - dNdxCut1)*s    644   G4double meanN1 = ((*v1)[0]/e1 - dNdxCut1)*stepFactor;
642                                                   645 
643   meanNumber = meanN1;                            646   meanNumber = meanN1;
644                                                   647 
645   // G4cout<<"iPlace = "<<iPlace<< " meanN1= "    648   // G4cout<<"iPlace = "<<iPlace<< " meanN1= " << meanN1 
646   //  <<"    (*v1)[0]/e1 = "<<(*v1)[0]/e1<< "     649   //  <<"    (*v1)[0]/e1 = "<<(*v1)[0]/e1<< " dNdxCut1= " << dNdxCut1 << G4endl;
647                                                   650 
648   dNdxCut2 = dNdxCut1;                            651   dNdxCut2 = dNdxCut1;
649   W1 = 1.0;                                       652   W1 = 1.0;
650   W2 = 0.0;                                       653   W2 = 0.0;
651   if(!one)                                        654   if(!one) 
652   {                                               655   {
653     v2 = (*(fPAIplasmonBank[coupleIndex]))(iPl    656     v2 = (*(fPAIplasmonBank[coupleIndex]))(iPlace+1);
654     dNdxCut2 = (*vcut)[iPlace+1];                 657     dNdxCut2 = (*vcut)[iPlace+1];
655     e2 = v2->Energy(0);                           658     e2 = v2->Energy(0);
656                                                   659 
657     G4double meanN2 = ((*v2)[0]/e2 - dNdxCut2)    660     G4double meanN2 = ((*v2)[0]/e2 - dNdxCut2)*stepFactor;
658                                                   661 
659     E1 = fParticleEnergyVector->Energy(iPlace)    662     E1 = fParticleEnergyVector->Energy(iPlace); 
660     E2 = fParticleEnergyVector->Energy(iPlace+    663     E2 = fParticleEnergyVector->Energy(iPlace+1);
661     W = 1.0/(E2 - E1);                            664     W = 1.0/(E2 - E1);
662     W1 = (E2 - scaledTkin)*W;                     665     W1 = (E2 - scaledTkin)*W;
663     W2 = (scaledTkin - E1)*W;                     666     W2 = (scaledTkin - E1)*W;
664     meanNumber = W1*meanN1 + W2*meanN2;           667     meanNumber = W1*meanN1 + W2*meanN2;
665                                                   668 
666     //G4cout<<"meanN= " <<  meanNumber << " me    669     //G4cout<<"meanN= " <<  meanNumber << " meanN2= " << meanN2 
667     //    << " dNdxCut2= " << dNdxCut2 << G4en    670     //    << " dNdxCut2= " << dNdxCut2 << G4endl;
668   }                                               671   }
669   if( meanNumber <= 0.0) return 0.0;              672   if( meanNumber <= 0.0) return 0.0; 
670                                                   673 
671   G4int numOfCollisions = (G4int)G4Poisson(mea << 674   G4int numOfCollisions = G4Poisson(meanNumber);
672                                                   675 
673   //G4cout << "N= " << numOfCollisions << G4en    676   //G4cout << "N= " << numOfCollisions << G4endl;
674                                                   677 
675   if( 0 == numOfCollisions) return 0.0;           678   if( 0 == numOfCollisions) return 0.0; 
676                                                   679 
677   for(G4int i=0; i< numOfCollisions; ++i)         680   for(G4int i=0; i< numOfCollisions; ++i) 
678   {                                               681   {
679     G4double rand = G4UniformRand();              682     G4double rand = G4UniformRand();
680     position = dNdxCut1 + ((*v1)[0]/e1 - dNdxC    683     position = dNdxCut1 + ((*v1)[0]/e1 - dNdxCut1)*rand;
681     omega = GetEnergyPlasmonTransfer(coupleInd    684     omega = GetEnergyPlasmonTransfer(coupleIndex, iPlace, position);
682                                                   685 
683     //G4cout << "omega(keV)= " << omega/keV <<    686     //G4cout << "omega(keV)= " << omega/keV << G4endl;
684                                                   687 
685     if(!one)                                      688     if(!one) 
686     {                                             689     {
687       position = dNdxCut2 + ((*v2)[0]/e2 - dNd    690       position = dNdxCut2 + ((*v2)[0]/e2 - dNdxCut2)*rand;
688       G4double omega2 = GetEnergyPlasmonTransf    691       G4double omega2 = GetEnergyPlasmonTransfer(coupleIndex, iPlace+1, position);
689       omega = omega*W1 + omega2*W2;               692       omega = omega*W1 + omega2*W2;
690     }                                             693     }
691     //G4cout << "omega(keV)= " << omega/keV <<    694     //G4cout << "omega(keV)= " << omega/keV << G4endl;
692                                                   695 
693     loss += omega;                                696     loss += omega;
694     if( loss > kinEnergy) { break; }              697     if( loss > kinEnergy) { break; }
695   }                                               698   }
696                                                   699   
697   // G4cout<<"PAIPhotData AlongStepLoss = "<<l    700   // G4cout<<"PAIPhotData AlongStepLoss = "<<loss/keV<<" keV, on step = "
698   //<<step/mm<<" mm"<<G4endl;                     701   //<<step/mm<<" mm"<<G4endl; 
699                                                   702 
700   if     ( loss > kinEnergy) loss = kinEnergy;    703   if     ( loss > kinEnergy) loss = kinEnergy; 
701   else if( loss < 0.)        loss = 0.;           704   else if( loss < 0.)        loss = 0.;
702                                                   705  
703   return loss;                                    706   return loss;
704 }                                                 707 }
705                                                   708 
706 //////////////////////////////////////////////    709 ///////////////////////////////////////////////////////////////////////
707 //                                                710 //
708 // Returns post step PAI energy transfer > cut    711 // Returns post step PAI energy transfer > cut electron energy 
709 // according to passed scaled kinetic energy o    712 // according to passed scaled kinetic energy of particle
710                                                   713 
711 G4double G4PAIPhotData::SamplePostStepTransfer    714 G4double G4PAIPhotData::SamplePostStepTransfer(G4int coupleIndex, 
712             G4double scaledTkin) const            715             G4double scaledTkin) const
713 {                                                 716 {  
714   //G4cout<<"G4PAIPhotData::GetPostStepTransfe    717   //G4cout<<"G4PAIPhotData::GetPostStepTransfer"<<G4endl;
715   G4double transfer = 0.0;                        718   G4double transfer = 0.0;
716   G4double rand = G4UniformRand();                719   G4double rand = G4UniformRand();
717                                                   720 
718   std::size_t nPlace = fParticleEnergyVector-> << 721   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
719                                                   722 
720   //  std::size_t iTransfer, iTr1, iTr2;       << 723   //  size_t iTransfer, iTr1, iTr2;
721   G4double position, dNdxCut1, dNdxCut2, E1, E    724   G4double position, dNdxCut1, dNdxCut2, E1, E2, W1, W2, W;
722                                                   725 
723   G4PhysicsVector* cutv = fdNdxCutTable[couple    726   G4PhysicsVector* cutv = fdNdxCutTable[coupleIndex];
724                                                   727 
725   // Fermi plato, try from left                   728   // Fermi plato, try from left
726   if( scaledTkin >= fParticleEnergyVector->Get    729   if( scaledTkin >= fParticleEnergyVector->GetMaxEnergy()) 
727   {                                               730   {
728     position = (*cutv)[nPlace]*rand;              731     position = (*cutv)[nPlace]*rand;
729     transfer = GetEnergyTransfer(coupleIndex,     732     transfer = GetEnergyTransfer(coupleIndex, nPlace, position);
730   }                                               733   }
731   else if( scaledTkin <= fParticleEnergyVector    734   else if( scaledTkin <= fParticleEnergyVector->Energy(0) )
732   {                                               735   {
733     position = (*cutv)[0]*rand;                   736     position = (*cutv)[0]*rand;
734     transfer = GetEnergyTransfer(coupleIndex,     737     transfer = GetEnergyTransfer(coupleIndex, 0, position);
735   }                                               738   }
736   else                                            739   else 
737   {                                               740   {  
738     std::size_t iPlace = fParticleEnergyVector << 741     size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
739                                                   742 
740     dNdxCut1 = (*cutv)[iPlace];                   743     dNdxCut1 = (*cutv)[iPlace];  
741     dNdxCut2 = (*cutv)[iPlace+1];                 744     dNdxCut2 = (*cutv)[iPlace+1];  
742                                                   745 
743     E1 = fParticleEnergyVector->Energy(iPlace)    746     E1 = fParticleEnergyVector->Energy(iPlace); 
744     E2 = fParticleEnergyVector->Energy(iPlace+    747     E2 = fParticleEnergyVector->Energy(iPlace+1);
745     W  = 1.0/(E2 - E1);                           748     W  = 1.0/(E2 - E1);
746     W1 = (E2 - scaledTkin)*W;                     749     W1 = (E2 - scaledTkin)*W;
747     W2 = (scaledTkin - E1)*W;                     750     W2 = (scaledTkin - E1)*W;
748                                                   751 
749     //G4cout<<"iPlace= " << "  dNdxCut1 = "<<d    752     //G4cout<<"iPlace= " << "  dNdxCut1 = "<<dNdxCut1 
750     //    <<" dNdxCut2 = "<<dNdxCut2<< " W1= "    753     //    <<" dNdxCut2 = "<<dNdxCut2<< " W1= " << W1 << " W2= " << W2 <<G4endl;
751                                                   754 
752     position = dNdxCut1*rand;                     755     position = dNdxCut1*rand;
753     G4double tr1 = GetEnergyTransfer(coupleInd    756     G4double tr1 = GetEnergyTransfer(coupleIndex, iPlace, position);
754                                                   757 
755     position = dNdxCut2*rand;                     758     position = dNdxCut2*rand;
756     G4double tr2 = GetEnergyTransfer(coupleInd    759     G4double tr2 = GetEnergyTransfer(coupleIndex, iPlace+1, position);
757                                                   760 
758     transfer = tr1*W1 + tr2*W2;                   761     transfer = tr1*W1 + tr2*W2;
759   }                                               762   }
760   //G4cout<<"PAImodel PostStepTransfer = "<<tr    763   //G4cout<<"PAImodel PostStepTransfer = "<<transfer/keV<<" keV"<<G4endl; 
761   if(transfer < 0.0 ) { transfer = 0.0; }         764   if(transfer < 0.0 ) { transfer = 0.0; }
762   return transfer;                                765   return transfer;
763 }                                                 766 }
764                                                   767 
765 //////////////////////////////////////////////    768 ////////////////////////////////////////////////////////////////////////
766                                                   769 
767 G4double G4PAIPhotData::SamplePostStepPhotonTr    770 G4double G4PAIPhotData::SamplePostStepPhotonTransfer(G4int coupleIndex, 
768             G4double scaledTkin) const            771             G4double scaledTkin) const
769 {                                                 772 {  
770   //G4cout<<"G4PAIPhotData::GetPostStepTransfe    773   //G4cout<<"G4PAIPhotData::GetPostStepTransfer"<<G4endl;
771   G4double transfer = 0.0;                        774   G4double transfer = 0.0;
772   G4double rand = G4UniformRand();                775   G4double rand = G4UniformRand();
773                                                   776 
774   std::size_t nPlace = fParticleEnergyVector-> << 777   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
775                                                   778 
776   //  std::size_t iTransfer, iTr1, iTr2;       << 779   //  size_t iTransfer, iTr1, iTr2;
777   G4double position, dNdxCut1, dNdxCut2, E1, E    780   G4double position, dNdxCut1, dNdxCut2, E1, E2, W1, W2, W;
778                                                   781 
779   G4PhysicsVector* cutv = fdNdxCutPhotonTable[    782   G4PhysicsVector* cutv = fdNdxCutPhotonTable[coupleIndex];
780                                                   783 
781   // Fermi plato, try from left                   784   // Fermi plato, try from left
782                                                   785 
783   if( scaledTkin >= fParticleEnergyVector->Get    786   if( scaledTkin >= fParticleEnergyVector->GetMaxEnergy()) 
784   {                                               787   {
785     position = (*cutv)[nPlace]*rand;              788     position = (*cutv)[nPlace]*rand;
786     transfer = GetEnergyPhotonTransfer(coupleI    789     transfer = GetEnergyPhotonTransfer(coupleIndex, nPlace, position);
787   }                                               790   }
788   else if( scaledTkin <= fParticleEnergyVector    791   else if( scaledTkin <= fParticleEnergyVector->Energy(0) )
789   {                                               792   {
790     position = (*cutv)[0]*rand;                   793     position = (*cutv)[0]*rand;
791     transfer = GetEnergyPhotonTransfer(coupleI    794     transfer = GetEnergyPhotonTransfer(coupleIndex, 0, position);
792   }                                               795   }
793   else                                            796   else 
794   {                                               797   {  
795     std::size_t iPlace = fParticleEnergyVector << 798     size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
796                                                   799 
797     dNdxCut1 = (*cutv)[iPlace];                   800     dNdxCut1 = (*cutv)[iPlace];  
798     dNdxCut2 = (*cutv)[iPlace+1];                 801     dNdxCut2 = (*cutv)[iPlace+1];  
799                                                   802 
800     E1 = fParticleEnergyVector->Energy(iPlace)    803     E1 = fParticleEnergyVector->Energy(iPlace); 
801     E2 = fParticleEnergyVector->Energy(iPlace+    804     E2 = fParticleEnergyVector->Energy(iPlace+1);
802     W  = 1.0/(E2 - E1);                           805     W  = 1.0/(E2 - E1);
803     W1 = (E2 - scaledTkin)*W;                     806     W1 = (E2 - scaledTkin)*W;
804     W2 = (scaledTkin - E1)*W;                     807     W2 = (scaledTkin - E1)*W;
805                                                   808 
806     //G4cout<<"iPlace= " << "  dNdxCut1 = "<<d    809     //G4cout<<"iPlace= " << "  dNdxCut1 = "<<dNdxCut1 
807     //    <<" dNdxCut2 = "<<dNdxCut2<< " W1= "    810     //    <<" dNdxCut2 = "<<dNdxCut2<< " W1= " << W1 << " W2= " << W2 <<G4endl;
808                                                   811 
809     position = dNdxCut1*rand;                     812     position = dNdxCut1*rand;
810                                                   813 
811     G4double tr1 = GetEnergyPhotonTransfer(cou    814     G4double tr1 = GetEnergyPhotonTransfer(coupleIndex, iPlace, position);
812                                                   815 
813     position = dNdxCut2*rand;                     816     position = dNdxCut2*rand;
814     G4double tr2 = GetEnergyPhotonTransfer(cou    817     G4double tr2 = GetEnergyPhotonTransfer(coupleIndex, iPlace+1, position);
815                                                   818 
816     transfer = tr1*W1 + tr2*W2;                   819     transfer = tr1*W1 + tr2*W2;
817   }                                               820   }
818   //G4cout<<"PAImodel PostStepTransfer = "<<tr    821   //G4cout<<"PAImodel PostStepTransfer = "<<transfer/keV<<" keV"<<G4endl; 
819   if(transfer < 0.0 ) { transfer = 0.0; }         822   if(transfer < 0.0 ) { transfer = 0.0; }
820   return transfer;                                823   return transfer;
821 }                                                 824 }
822                                                   825 
823 //////////////////////////////////////////////    826 //////////////////////////////////////////////////////////////////////////
824                                                   827 
825 G4double G4PAIPhotData::SamplePostStepPlasmonT    828 G4double G4PAIPhotData::SamplePostStepPlasmonTransfer(G4int coupleIndex, 
826             G4double scaledTkin) const            829             G4double scaledTkin) const
827 {                                                 830 {  
828   //G4cout<<"G4PAIPhotData::GetPostStepTransfe    831   //G4cout<<"G4PAIPhotData::GetPostStepTransfer"<<G4endl;
829   G4double transfer = 0.0;                        832   G4double transfer = 0.0;
830   G4double rand = G4UniformRand();                833   G4double rand = G4UniformRand();
831                                                   834 
832   std::size_t nPlace = fParticleEnergyVector-> << 835   size_t nPlace = fParticleEnergyVector->GetVectorLength() - 1;
833                                                   836 
834   //  std::size_t iTransfer, iTr1, iTr2;       << 837   //  size_t iTransfer, iTr1, iTr2;
835   G4double position, dNdxCut1, dNdxCut2, E1, E    838   G4double position, dNdxCut1, dNdxCut2, E1, E2, W1, W2, W;
836                                                   839 
837   G4PhysicsVector* cutv = fdNdxCutPlasmonTable    840   G4PhysicsVector* cutv = fdNdxCutPlasmonTable[coupleIndex];
838                                                   841 
839   // Fermi plato, try from left                   842   // Fermi plato, try from left
840   if( scaledTkin >= fParticleEnergyVector->Get    843   if( scaledTkin >= fParticleEnergyVector->GetMaxEnergy()) 
841   {                                               844   {
842     position = (*cutv)[nPlace]*rand;              845     position = (*cutv)[nPlace]*rand;
843     transfer = GetEnergyPlasmonTransfer(couple    846     transfer = GetEnergyPlasmonTransfer(coupleIndex, nPlace, position);
844   }                                               847   }
845   else if( scaledTkin <= fParticleEnergyVector    848   else if( scaledTkin <= fParticleEnergyVector->Energy(0) )
846   {                                               849   {
847     position = (*cutv)[0]*rand;                   850     position = (*cutv)[0]*rand;
848     transfer = GetEnergyPlasmonTransfer(couple    851     transfer = GetEnergyPlasmonTransfer(coupleIndex, 0, position);
849   }                                               852   }
850   else                                            853   else 
851   {                                               854   {  
852     std::size_t iPlace = fParticleEnergyVector << 855     size_t iPlace = fParticleEnergyVector->FindBin(scaledTkin, 0);
853                                                   856 
854     dNdxCut1 = (*cutv)[iPlace];                   857     dNdxCut1 = (*cutv)[iPlace];  
855     dNdxCut2 = (*cutv)[iPlace+1];                 858     dNdxCut2 = (*cutv)[iPlace+1];  
856                                                   859 
857     E1 = fParticleEnergyVector->Energy(iPlace)    860     E1 = fParticleEnergyVector->Energy(iPlace); 
858     E2 = fParticleEnergyVector->Energy(iPlace+    861     E2 = fParticleEnergyVector->Energy(iPlace+1);
859     W  = 1.0/(E2 - E1);                           862     W  = 1.0/(E2 - E1);
860     W1 = (E2 - scaledTkin)*W;                     863     W1 = (E2 - scaledTkin)*W;
861     W2 = (scaledTkin - E1)*W;                     864     W2 = (scaledTkin - E1)*W;
862                                                   865 
863     //G4cout<<"iPlace= " << "  dNdxCut1 = "<<d    866     //G4cout<<"iPlace= " << "  dNdxCut1 = "<<dNdxCut1 
864     //    <<" dNdxCut2 = "<<dNdxCut2<< " W1= "    867     //    <<" dNdxCut2 = "<<dNdxCut2<< " W1= " << W1 << " W2= " << W2 <<G4endl;
865                                                   868 
866     position = dNdxCut1*rand;                     869     position = dNdxCut1*rand;
867     G4double tr1 = GetEnergyPlasmonTransfer(co    870     G4double tr1 = GetEnergyPlasmonTransfer(coupleIndex, iPlace, position);
868                                                   871 
869     position = dNdxCut2*rand;                     872     position = dNdxCut2*rand;
870     G4double tr2 = GetEnergyPlasmonTransfer(co    873     G4double tr2 = GetEnergyPlasmonTransfer(coupleIndex, iPlace+1, position);
871                                                   874 
872     transfer = tr1*W1 + tr2*W2;                   875     transfer = tr1*W1 + tr2*W2;
873   }                                               876   }
874   //G4cout<<"PAImodel PostStepPlasmonTransfer     877   //G4cout<<"PAImodel PostStepPlasmonTransfer = "<<transfer/keV<<" keV"<<G4endl; 
875                                                   878 
876   if(transfer < 0.0 )  transfer = 0.0;            879   if(transfer < 0.0 )  transfer = 0.0;
877                                                   880  
878   return transfer;                                881   return transfer;
879 }                                                 882 }
880                                                   883 
881 //////////////////////////////////////////////    884 ///////////////////////////////////////////////////////////////////////
882 //                                                885 //
883 // Returns PAI energy transfer according to pa    886 // Returns PAI energy transfer according to passed 
884 // indexes of particle kinetic enegry and rand    887 // indexes of particle kinetic enegry and random x-section
885                                                   888 
886 G4double G4PAIPhotData::GetEnergyTransfer(G4in    889 G4double G4PAIPhotData::GetEnergyTransfer(G4int coupleIndex, 
887            std::size_t iPlace,                 << 890              size_t iPlace, 
888            G4double position) const            << 891              G4double position) const
889 {                                                 892 { 
890   G4PhysicsVector* v = (*(fPAIxscBank[coupleIn    893   G4PhysicsVector* v = (*(fPAIxscBank[coupleIndex]))(iPlace); 
891   if(position*v->Energy(0) >= (*v)[0]) { retur    894   if(position*v->Energy(0) >= (*v)[0]) { return v->Energy(0); }
892                                                   895 
893   std::size_t iTransferMax = v->GetVectorLengt << 896   size_t iTransferMax = v->GetVectorLength() - 1;
894                                                   897 
895   std::size_t iTransfer;                       << 898   size_t iTransfer;
896   G4double x1(0.0), x2(0.0), y1(0.0), y2(0.0),    899   G4double x1(0.0), x2(0.0), y1(0.0), y2(0.0), energyTransfer;
897                                                   900 
898   for(iTransfer=1; iTransfer<=iTransferMax; ++    901   for(iTransfer=1; iTransfer<=iTransferMax; ++iTransfer) {
899     x2 = v->Energy(iTransfer);                    902     x2 = v->Energy(iTransfer);
900     y2 = (*v)[iTransfer]/x2;                      903     y2 = (*v)[iTransfer]/x2;
901     if(position >= y2) { break; }                 904     if(position >= y2) { break; }
902   }                                               905   }
903                                                   906 
904   x1 = v->Energy(iTransfer-1);                    907   x1 = v->Energy(iTransfer-1);
905   y1 = (*v)[iTransfer-1]/x1;                      908   y1 = (*v)[iTransfer-1]/x1;
906   //G4cout << "i= " << iTransfer << " imax= "     909   //G4cout << "i= " << iTransfer << " imax= " << iTransferMax
907   //   << " x1= " << x1 << " x2= " << x2 << G4    910   //   << " x1= " << x1 << " x2= " << x2 << G4endl;
908                                                   911 
909   energyTransfer = x1;                            912   energyTransfer = x1;
910   if ( x1 != x2 ) {                               913   if ( x1 != x2 ) {
911     if ( y1 == y2  ) {                            914     if ( y1 == y2  ) {
912       energyTransfer += (x2 - x1)*G4UniformRan    915       energyTransfer += (x2 - x1)*G4UniformRand();
913     } else {                                      916     } else {
914       if(x1*1.1 < x2) {                           917       if(x1*1.1 < x2) {
915   const G4int nbins = 5;                          918   const G4int nbins = 5;
916         G4double del = (x2 - x1)/G4int(nbins);    919         G4double del = (x2 - x1)/G4int(nbins);
917         x2  = x1;                                 920         x2  = x1;
918         for(G4int i=1; i<=nbins; ++i) {           921         for(G4int i=1; i<=nbins; ++i) {
919           x2 += del;                              922           x2 += del;
920           y2 = v->Value(x2)/x2;                   923           y2 = v->Value(x2)/x2;
921           if(position >= y2) { break; }           924           if(position >= y2) { break; }
922           x1 = x2;                                925           x1 = x2;
923           y1 = y2;                                926           y1 = y2;
924   }                                               927   }
925       }                                           928       }
926       energyTransfer = (y2 - y1)*x1*x2/(positi    929       energyTransfer = (y2 - y1)*x1*x2/(position*(x1 - x2) - y1*x1 + y2*x2);
927     }                                             930     }
928   }                                               931   }
929   //  G4cout << "x1(keV)= " << x1/keV << " x2(    932   //  G4cout << "x1(keV)= " << x1/keV << " x2(keV)= " << x2/keV
930   //   << " y1= " << y1 << " y2= " << y2 << "     933   //   << " y1= " << y1 << " y2= " << y2 << " pos= " << position
931   //   << " E(keV)= " << energyTransfer/keV <<    934   //   << " E(keV)= " << energyTransfer/keV << G4endl; 
932   return energyTransfer;                          935   return energyTransfer;
933 }                                                 936 }
934                                                   937 
935 //////////////////////////////////////////////    938 /////////////////////////////////////////////////////////////////
936                                                   939 
937 G4double G4PAIPhotData::GetEnergyPhotonTransfe    940 G4double G4PAIPhotData::GetEnergyPhotonTransfer(G4int coupleIndex, 
938                   std::size_t iPlace,          << 941              size_t iPlace, 
939                   G4double position) const     << 942              G4double position) const
940 {                                                 943 { 
941   G4PhysicsVector* v = (*(fPAIphotonBank[coupl    944   G4PhysicsVector* v = (*(fPAIphotonBank[coupleIndex]))(iPlace); 
942   if(position*v->Energy(0) >= (*v)[0])  return    945   if(position*v->Energy(0) >= (*v)[0])  return v->Energy(0); 
943                                                   946 
944   std::size_t iTransferMax = v->GetVectorLengt << 947   size_t iTransferMax = v->GetVectorLength() - 1;
945                                                   948 
946   std::size_t iTransfer;                       << 949   size_t iTransfer;
947   G4double x1(0.0), x2(0.0), y1(0.0), y2(0.0),    950   G4double x1(0.0), x2(0.0), y1(0.0), y2(0.0), energyTransfer;
948                                                   951 
949   for(iTransfer=1; iTransfer<=iTransferMax; ++    952   for(iTransfer=1; iTransfer<=iTransferMax; ++iTransfer) 
950   {                                               953   {
951     x2 = v->Energy(iTransfer);                    954     x2 = v->Energy(iTransfer);
952     y2 = (*v)[iTransfer]/x2;                      955     y2 = (*v)[iTransfer]/x2;
953     if(position >= y2)  break;                    956     if(position >= y2)  break; 
954   }                                               957   }
955   x1 = v->Energy(iTransfer-1);                    958   x1 = v->Energy(iTransfer-1);
956   y1 = (*v)[iTransfer-1]/x1;                      959   y1 = (*v)[iTransfer-1]/x1;
957                                                   960 
958   //G4cout << "i= " << iTransfer << " imax= "     961   //G4cout << "i= " << iTransfer << " imax= " << iTransferMax
959   //   << " x1= " << x1 << " x2= " << x2 << G4    962   //   << " x1= " << x1 << " x2= " << x2 << G4endl;
960                                                   963 
961   energyTransfer = x1;                            964   energyTransfer = x1;
962                                                   965 
963   if ( x1 != x2 )                                 966   if ( x1 != x2 ) 
964   {                                               967   {
965     if ( y1 == y2  )                              968     if ( y1 == y2  ) 
966     {                                             969     {
967       energyTransfer += (x2 - x1)*G4UniformRan    970       energyTransfer += (x2 - x1)*G4UniformRand();
968     }                                             971     } 
969     else                                          972     else 
970     {                                             973     {
971       if( x1*1.1 < x2 )                           974       if( x1*1.1 < x2 ) 
972       {                                           975       {
973   const G4int nbins = 5;                          976   const G4int nbins = 5;
974         G4double del = (x2 - x1)/G4int(nbins);    977         G4double del = (x2 - x1)/G4int(nbins);
975         x2  = x1;                                 978         x2  = x1;
976                                                   979 
977         for(G4int i=1; i<=nbins; ++i)             980         for(G4int i=1; i<=nbins; ++i) 
978         {                                         981         {
979           x2 += del;                              982           x2 += del;
980           y2 = v->Value(x2)/x2;                   983           y2 = v->Value(x2)/x2;
981           if(position >= y2) { break; }           984           if(position >= y2) { break; }
982           x1 = x2;                                985           x1 = x2;
983           y1 = y2;                                986           y1 = y2;
984   }                                               987   }
985       }                                           988       }
986       energyTransfer = (y2 - y1)*x1*x2/(positi    989       energyTransfer = (y2 - y1)*x1*x2/(position*(x1 - x2) - y1*x1 + y2*x2);
987     }                                             990     }
988   }                                               991   }
989   //  G4cout << "x1(keV)= " << x1/keV << " x2(    992   //  G4cout << "x1(keV)= " << x1/keV << " x2(keV)= " << x2/keV
990   //   << " y1= " << y1 << " y2= " << y2 << "     993   //   << " y1= " << y1 << " y2= " << y2 << " pos= " << position
991   //   << " E(keV)= " << energyTransfer/keV <<    994   //   << " E(keV)= " << energyTransfer/keV << G4endl;
992                                                   995  
993   return energyTransfer;                          996   return energyTransfer;
994 }                                                 997 }
995                                                   998 
996 //////////////////////////////////////////////    999 /////////////////////////////////////////////////////////////////////////
997                                                   1000 
998 G4double G4PAIPhotData::GetEnergyPlasmonTransf    1001 G4double G4PAIPhotData::GetEnergyPlasmonTransfer(G4int coupleIndex, 
999                    std::size_t iPlace,         << 1002              size_t iPlace, 
1000                    G4double position) const   << 1003              G4double position) const
1001 {                                                1004 { 
1002   G4PhysicsVector* v = (*(fPAIplasmonBank[cou    1005   G4PhysicsVector* v = (*(fPAIplasmonBank[coupleIndex]))(iPlace); 
1003                                                  1006 
1004   if( position*v->Energy(0) >= (*v)[0] )  ret    1007   if( position*v->Energy(0) >= (*v)[0] )  return v->Energy(0); 
1005                                                  1008 
1006   std::size_t iTransferMax = v->GetVectorLeng << 1009   size_t iTransferMax = v->GetVectorLength() - 1;
1007                                                  1010 
1008   std::size_t iTransfer;                      << 1011   size_t iTransfer;
1009   G4double x1(0.0), x2(0.0), y1(0.0), y2(0.0)    1012   G4double x1(0.0), x2(0.0), y1(0.0), y2(0.0), energyTransfer;
1010                                                  1013 
1011   for(iTransfer = 1; iTransfer <= iTransferMa    1014   for(iTransfer = 1; iTransfer <= iTransferMax; ++iTransfer) 
1012   {                                              1015   {
1013     x2 = v->Energy(iTransfer);                   1016     x2 = v->Energy(iTransfer);
1014     y2 = (*v)[iTransfer]/x2;                     1017     y2 = (*v)[iTransfer]/x2;
1015     if(position >= y2)  break;                   1018     if(position >= y2)  break; 
1016   }                                              1019   }
1017   x1 = v->Energy(iTransfer-1);                   1020   x1 = v->Energy(iTransfer-1);
1018   y1 = (*v)[iTransfer-1]/x1;                     1021   y1 = (*v)[iTransfer-1]/x1;
1019                                                  1022 
1020   //G4cout << "i= " << iTransfer << " imax= "    1023   //G4cout << "i= " << iTransfer << " imax= " << iTransferMax
1021   //   << " x1= " << x1 << " x2= " << x2 << G    1024   //   << " x1= " << x1 << " x2= " << x2 << G4endl;
1022                                                  1025 
1023   energyTransfer = x1;                           1026   energyTransfer = x1;
1024                                                  1027 
1025   if ( x1 != x2 )                                1028   if ( x1 != x2 ) 
1026   {                                              1029   {
1027     if ( y1 == y2  )                             1030     if ( y1 == y2  ) 
1028     {                                            1031     {
1029       energyTransfer += (x2 - x1)*G4UniformRa    1032       energyTransfer += (x2 - x1)*G4UniformRand();
1030     }                                            1033     } 
1031     else                                         1034     else 
1032     {                                            1035     {
1033       if(x1*1.1 < x2)                            1036       if(x1*1.1 < x2) 
1034       {                                          1037       {
1035   const G4int nbins = 5;                         1038   const G4int nbins = 5;
1036         G4double del = (x2 - x1)/G4int(nbins)    1039         G4double del = (x2 - x1)/G4int(nbins);
1037         x2  = x1;                                1040         x2  = x1;
1038                                                  1041 
1039         for( G4int i = 1; i <= nbins; ++i )      1042         for( G4int i = 1; i <= nbins; ++i ) 
1040         {                                        1043         {
1041           x2 += del;                             1044           x2 += del;
1042           y2 = v->Value(x2)/x2;                  1045           y2 = v->Value(x2)/x2;
1043                                                  1046 
1044           if(position >= y2)  break;             1047           if(position >= y2)  break; 
1045                                                  1048 
1046           x1 = x2;                               1049           x1 = x2;
1047           y1 = y2;                               1050           y1 = y2;
1048   }                                              1051   }
1049       }                                          1052       }
1050       energyTransfer = (y2 - y1)*x1*x2/(posit    1053       energyTransfer = (y2 - y1)*x1*x2/(position*(x1 - x2) - y1*x1 + y2*x2);
1051     }                                            1054     }
1052   }                                              1055   }
1053   //  G4cout << "x1(keV)= " << x1/keV << " x2    1056   //  G4cout << "x1(keV)= " << x1/keV << " x2(keV)= " << x2/keV
1054   //   << " y1= " << y1 << " y2= " << y2 << "    1057   //   << " y1= " << y1 << " y2= " << y2 << " pos= " << position
1055   //   << " E(keV)= " << energyTransfer/keV <    1058   //   << " E(keV)= " << energyTransfer/keV << G4endl; 
1056                                                  1059 
1057   return energyTransfer;                         1060   return energyTransfer;
1058 }                                                1061 }
1059                                                  1062 
1060 //                                               1063 //
1061 //                                               1064 //
1062 /////////////////////////////////////////////    1065 //////////////////////////////////////////////////////////////////////
1063                                                  1066 
1064                                                  1067