Geant4 Cross Reference

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Geant4/processes/electromagnetic/dna/models/src/G4VLEPTSModel.cc

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Diff markup

Differences between /processes/electromagnetic/dna/models/src/G4VLEPTSModel.cc (Version 11.3.0) and /processes/electromagnetic/dna/models/src/G4VLEPTSModel.cc (Version 11.0.p2)


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 26 #include "G4VLEPTSModel.hh"                        26 #include "G4VLEPTSModel.hh"
 27                                                    27 
 28 #include "CLHEP/Units/SystemOfUnits.h"             28 #include "CLHEP/Units/SystemOfUnits.h"
 29                                                    29 
 30 //....oooOO0OOooo........oooOO0OOooo........oo     30 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 31 G4VLEPTSModel::G4VLEPTSModel(const G4String& m <<  31 G4VLEPTSModel::G4VLEPTSModel(const G4String& modelName) : G4VEmModel(modelName),isInitialised(false) 
 32 {                                                  32 {
 33   theMeanFreePathTable=nullptr;                <<  33   theMeanFreePathTable=NULL;
 34                                                    34 
 35   theNumbBinTable=100;                             35   theNumbBinTable=100;
 36                                                    36 
 37   verboseLevel = 0;                                37   verboseLevel = 0;
 38                                                << 
 39   theLowestEnergyLimit = 0.5*CLHEP::eV;        << 
 40                                                << 
 41   theHighestEnergyLimit = 1.0*CLHEP::MeV;      << 
 42                                                << 
 43   theXSType = XSEnergy;                        << 
 44 }                                                  38 }
 45                                                    39 
 46                                                    40 
 47 //....oooOO0OOooo........oooOO0OOooo........oo     41 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 48 G4VLEPTSModel::~G4VLEPTSModel()                    42 G4VLEPTSModel::~G4VLEPTSModel() 
 49 {                                                  43 {
 50                                                    44 
 51   if(theMeanFreePathTable != nullptr) {        <<  45   if(theMeanFreePathTable) {
 52     theMeanFreePathTable->clearAndDestroy();       46     theMeanFreePathTable->clearAndDestroy();
 53     delete theMeanFreePathTable;                   47     delete theMeanFreePathTable;
 54   }                                                48   }
 55 }                                                  49 }
 56                                                    50 
 57                                                    51 
 58 //....oooOO0OOooo........oooOO0OOooo........oo     52 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo....
 59 void G4VLEPTSModel::Init()                         53 void G4VLEPTSModel::Init() 
 60 {                                                  54 {
 61   theLowestEnergyLimit = 0.5*CLHEP::eV;            55   theLowestEnergyLimit = 0.5*CLHEP::eV;
 62   theHighestEnergyLimit = 1.0*CLHEP::MeV;          56   theHighestEnergyLimit = 1.0*CLHEP::MeV;
 63   //t    theHighestEnergyLimit = 15.0*CLHEP::M     57   //t    theHighestEnergyLimit = 15.0*CLHEP::MeV;
 64   SetLowEnergyLimit(theLowestEnergyLimit);         58   SetLowEnergyLimit(theLowestEnergyLimit);
 65   SetHighEnergyLimit(theHighestEnergyLimit);       59   SetHighEnergyLimit(theHighestEnergyLimit);
 66   theNumbBinTable = 100;                           60   theNumbBinTable = 100;
 67                                                    61 
 68 }                                                  62 }
 69                                                    63 
 70                                                    64 
 71                                                    65 
 72 //....oooOO0OOooo........oooOO0OOooo........oo     66 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 73 G4double G4VLEPTSModel::GetMeanFreePath(const      67 G4double G4VLEPTSModel::GetMeanFreePath(const G4Material* aMaterial,
 74              const G4ParticleDefinition* ,         68              const G4ParticleDefinition* ,
 75              G4double kineticEnergy )              69              G4double kineticEnergy )
 76 {                                                  70 {
 77   G4double MeanFreePath;                           71   G4double MeanFreePath;
 78                                                    72 
 79   if( verboseLevel >= 3 ) G4cout << aMaterial-     73   if( verboseLevel >= 3 ) G4cout << aMaterial->GetIndex() << " G4VLEPTSModel::GetMeanFreePath " << kineticEnergy << " > " << theHighestEnergyLimit << " < " << theLowestEnergyLimit << G4endl;
 80   if (kineticEnergy > theHighestEnergyLimit ||     74   if (kineticEnergy > theHighestEnergyLimit || kineticEnergy < theLowestEnergyLimit)
 81     MeanFreePath = DBL_MAX;                        75     MeanFreePath = DBL_MAX;
 82   else                                             76   else
 83     MeanFreePath = (*theMeanFreePathTable)(aMa     77     MeanFreePath = (*theMeanFreePathTable)(aMaterial->GetIndex())->Value(kineticEnergy);
 84                                                    78 
 85   return MeanFreePath;                             79   return MeanFreePath;
 86 }                                                  80 }
 87                                                    81 
 88                                                    82 
 89 //....oooOO0OOooo........oooOO0OOooo........oo     83 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 90 void G4VLEPTSModel::BuildPhysicsTable(const G4     84 void G4VLEPTSModel::BuildPhysicsTable(const G4ParticleDefinition& aParticleType) 
 91 {                                                  85 {
 92   //CHECK IF PATH VARIABLE IS DEFINED              86   //CHECK IF PATH VARIABLE IS DEFINED
 93   const char* path = G4FindDataDir("G4LEDATA") <<  87   char* path = std::getenv("G4LEDATA");
 94   if( path == nullptr ) {                      <<  88   if( !path ) {
 95     G4Exception("G4VLEPTSModel",                   89     G4Exception("G4VLEPTSModel",
 96     "",                                            90     "",
 97     FatalException,                                91     FatalException,
 98     "variable G4LEDATA not defined");              92     "variable G4LEDATA not defined");
 99   }                                                93   }
100                                                    94 
101   // Build microscopic cross section table and     95   // Build microscopic cross section table and mean free path table
102                                                    96    
103   G4String aParticleName = aParticleType.GetPa     97   G4String aParticleName = aParticleType.GetParticleName();
104                                                    98 
105   if (theMeanFreePathTable != nullptr) {       <<  99   if (theMeanFreePathTable) {
106     theMeanFreePathTable->clearAndDestroy();      100     theMeanFreePathTable->clearAndDestroy();
107     delete theMeanFreePathTable;                  101     delete theMeanFreePathTable;
108   }                                               102   }
109                                                   103   
110   theMeanFreePathTable = new G4PhysicsTable(G4    104   theMeanFreePathTable = new G4PhysicsTable(G4Material::GetNumberOfMaterials());
111                                                   105 
112   //LOOP TO MATERIALS IN GEOMETRY                 106   //LOOP TO MATERIALS IN GEOMETRY 
113   const G4MaterialTable * materialTable = G4Ma    107   const G4MaterialTable * materialTable = G4Material::GetMaterialTable() ;
114   std::vector<G4Material*>::const_iterator mat    108   std::vector<G4Material*>::const_iterator matite;
115   for( matite = materialTable->cbegin(); matit << 109   for( matite = materialTable->begin(); matite != materialTable->end(); matite++ ) {
116     const G4Material * aMaterial = (*matite);     110     const G4Material * aMaterial = (*matite);
117     G4String mateName = aMaterial->GetName();     111     G4String mateName = aMaterial->GetName();
118                                                   112 
119     //READ PARAMETERS FOR THIS MATERIAL           113     //READ PARAMETERS FOR THIS MATERIAL
120     std::string dirName = std::string(path) +     114     std::string dirName = std::string(path) + "/lepts/";
121     std::string fnParam  = dirName + mateName     115     std::string fnParam  = dirName + mateName + "." + aParticleName + ".param.dat";  
122     std::string baseName = std::string(path) +    116     std::string baseName = std::string(path) + "/lepts/" + mateName + "." + aParticleName;
123     G4bool bData = ReadParam( fnParam, aMateri    117     G4bool bData = ReadParam( fnParam, aMaterial );
124     if( !bData )  continue; // MATERIAL NOT EX    118     if( !bData )  continue; // MATERIAL NOT EXISTING, DO NOT READ OTHER FILES
125                                                   119 
126     //READ INTEGRAL CROSS SECTION FOR THIS MAT    120     //READ INTEGRAL CROSS SECTION FOR THIS MATERIAL
127     std::string fnIXS  = baseName + ".IXS.dat"    121     std::string fnIXS  = baseName + ".IXS.dat";
128                                                   122     
129     std::map< G4int, std::vector<G4double> > i    123     std::map< G4int, std::vector<G4double> > integralXS = ReadIXS(fnIXS, aMaterial);
130     if( verboseLevel >= 2 ) G4cout << GetName(    124     if( verboseLevel >= 2 ) G4cout << GetName() << " : " << theXSType << " " << mateName << " INTEGRALXS " << integralXS.size() << G4endl;
131                                                   125 
132     if( integralXS.empty() ) {                 << 126     if( integralXS.size() == 0 ) {
133       G4cerr << " Integral cross sections will    127       G4cerr << " Integral cross sections will be set to 0. for material " << mateName << G4endl;
134       auto  ptrVector = new G4PhysicsLogVector << 128       G4PhysicsLogVector* ptrVector = new G4PhysicsLogVector(theLowestEnergyLimit, theHighestEnergyLimit, 2);
135       ptrVector->PutValue(0, DBL_MAX);            129       ptrVector->PutValue(0, DBL_MAX);
136       ptrVector->PutValue(1, DBL_MAX);            130       ptrVector->PutValue(1, DBL_MAX);
137                                                   131 
138       std::size_t matIdx = aMaterial->GetIndex << 132       unsigned int matIdx = aMaterial->GetIndex();
139       theMeanFreePathTable->insertAt( matIdx ,    133       theMeanFreePathTable->insertAt( matIdx , ptrVector ) ;
140                                                   134 
141     } else {                                      135     } else {
142                                                   136     
143       if( verboseLevel >= 2 ) {                   137       if( verboseLevel >= 2 ) {
144   std::map< G4int, std::vector<G4double> >::co    138   std::map< G4int, std::vector<G4double> >::const_iterator itei;
145   for( itei = integralXS.begin(); itei != inte    139   for( itei = integralXS.begin(); itei != integralXS.end(); itei++ ){
146     G4cout << GetName() << " : " << (*itei).fi    140     G4cout << GetName() << " : " << (*itei).first << " INTEGRALXS NDATA " << (*itei).second.size() << G4endl;
147   }                                               141   }
148       }                                           142       }
149                                                   143       
150       BuildMeanFreePathTable( aMaterial, integ    144       BuildMeanFreePathTable( aMaterial, integralXS );
151                                                   145 
152       std::string fnDXS = baseName + ".DXS.dat    146       std::string fnDXS = baseName + ".DXS.dat";
153       std::string fnRMT = baseName + ".RMT.dat    147       std::string fnRMT = baseName + ".RMT.dat";
154       std::string fnEloss = baseName + ".Eloss    148       std::string fnEloss = baseName + ".Eloss.dat";
155       std::string fnEloss2 = baseName + ".Elos    149       std::string fnEloss2 = baseName + ".Eloss2.dat";
156                                                   150       
157       theDiffXS[aMaterial] = new G4LEPTSDiffXS    151       theDiffXS[aMaterial] = new G4LEPTSDiffXS(fnDXS);
158       if( !theDiffXS[aMaterial]->IsFileFound()    152       if( !theDiffXS[aMaterial]->IsFileFound() ) {
159   G4Exception("G4VLEPTSModel::BuildPhysicsTabl    153   G4Exception("G4VLEPTSModel::BuildPhysicsTable",
160         "",                                       154         "",
161         FatalException,                           155         FatalException,
162         (G4String("File not found :" + fnDXS).    156         (G4String("File not found :" + fnDXS).c_str()));
163       }                                           157       }
164                                                   158 
165       theRMTDistr[aMaterial] = new G4LEPTSDist    159       theRMTDistr[aMaterial] = new G4LEPTSDistribution();
166       theRMTDistr[aMaterial]->ReadFile(fnRMT);    160       theRMTDistr[aMaterial]->ReadFile(fnRMT);
167                                                   161 
168       theElostDistr[aMaterial] = new G4LEPTSEl    162       theElostDistr[aMaterial] = new G4LEPTSElossDistr(fnEloss);
169       if( !theElostDistr[aMaterial]->IsFileFou    163       if( !theElostDistr[aMaterial]->IsFileFound() ) {
170   G4Exception("G4VLEPTSModel::BuildPhysicsTabl    164   G4Exception("G4VLEPTSModel::BuildPhysicsTable",
171         "",                                       165         "",
172         FatalException,                           166         FatalException,
173         (G4String("File not found :" + fnEloss    167         (G4String("File not found :" + fnEloss).c_str()));
174       }                                           168       }
175     }                                             169     }
176                                                   170 
177   }                                               171   }
178                                                   172   
179 }                                                 173 }
180                                                   174 
181 void G4VLEPTSModel::BuildMeanFreePathTable( co    175 void G4VLEPTSModel::BuildMeanFreePathTable( const G4Material* aMaterial, std::map< G4int, std::vector<G4double> >& integralXS )
182 {                                                 176 {
183   G4double LowEdgeEnergy, fValue;                 177   G4double LowEdgeEnergy, fValue;
184                                                   178 
185   //BUILD MEAN FREE PATH TABLE FROM INTEGRAL C    179   //BUILD MEAN FREE PATH TABLE FROM INTEGRAL CROSS SECTION
186   std::size_t matIdx = aMaterial->GetIndex();  << 180   unsigned int matIdx = aMaterial->GetIndex();
187   auto  ptrVector = new G4PhysicsLogVector(the << 181   G4PhysicsLogVector* ptrVector = new G4PhysicsLogVector(theLowestEnergyLimit, theHighestEnergyLimit, theNumbBinTable);
188                                                   182   
189   for (G4int ii=0; ii < theNumbBinTable; ++ii) << 183   for (G4int ii=0; ii < theNumbBinTable; ii++) {
190     LowEdgeEnergy = ptrVector->Energy(ii);        184     LowEdgeEnergy = ptrVector->Energy(ii);
191     if( verboseLevel >= 2 ) G4cout << GetName(    185     if( verboseLevel >= 2 ) G4cout << GetName() << " " << ii << " Energy " << LowEdgeEnergy << " > " << theLowestEnergyLimit << " < " << theHighestEnergyLimit << G4endl;
192     //-      fValue = ComputeMFP(LowEdgeEnergy    186     //-      fValue = ComputeMFP(LowEdgeEnergy, material, aParticleName);
193     fValue = 0.;                                  187     fValue = 0.;
194     if( LowEdgeEnergy >= theLowestEnergyLimit     188     if( LowEdgeEnergy >= theLowestEnergyLimit && 
195   LowEdgeEnergy <= theHighestEnergyLimit) {       189   LowEdgeEnergy <= theHighestEnergyLimit) {
196       G4double NbOfMoleculesPerVolume = aMater    190       G4double NbOfMoleculesPerVolume = aMaterial->GetDensity()/theMolecularMass[aMaterial]*CLHEP::Avogadro; 
197                                                   191       
198       G4double SIGMA = 0. ;                       192       G4double SIGMA = 0. ;
199       //-      for ( std::size_t elm=0 ; elm < << 193       //-      for ( size_t elm=0 ; elm < aMaterial->GetNumberOfElements() ; elm++ ) {
200   G4double crossSection = 0.;                     194   G4double crossSection = 0.;
201                                                   195   
202   G4double eVEnergy = LowEdgeEnergy/CLHEP::eV;    196   G4double eVEnergy = LowEdgeEnergy/CLHEP::eV;
203                                                   197   
204   //-    if( verboseLevel >= 2 )  G4cout << "     198   //-    if( verboseLevel >= 2 )  G4cout << " eVEnergy " << eVEnergy << " LowEdgeE " << LowEdgeEnergy << " " << integralXS[theXSType][1] << G4endl;
205                                                   199   
206   if(eVEnergy < integralXS[0][1] ) {              200   if(eVEnergy < integralXS[0][1] ) {
207     crossSection = 0.;                            201     crossSection = 0.;
208   } else {                                        202   } else {
209     G4int Bin = 0; // locate bin                  203     G4int Bin = 0; // locate bin                                                                           
210     G4double aa, bb;                              204     G4double aa, bb;
211     for( G4int jj=1; jj<theNXSdat[aMaterial];     205     for( G4int jj=1; jj<theNXSdat[aMaterial]; jj++) {  // Extrapolate for E > Emax !!!                               
212       if( verboseLevel >= 3 ) G4cout << " GET     206       if( verboseLevel >= 3 ) G4cout << " GET BIN " << jj << " "<< eVEnergy << " > " << integralXS[0][jj] << G4endl; 
213       if( eVEnergy > integralXS[0][jj]) {         207       if( eVEnergy > integralXS[0][jj]) {
214         Bin = jj;                                 208         Bin = jj;
215       } else {                                    209       } else {
216         break;                                    210         break;
217       }                                           211       }
218     }                                             212     }
219     aa = integralXS[0][Bin];                      213     aa = integralXS[0][Bin];
220     bb = integralXS[0][Bin+1];                    214     bb = integralXS[0][Bin+1];
221     crossSection = (integralXS[theXSType][Bin]    215     crossSection = (integralXS[theXSType][Bin] + (integralXS[theXSType][Bin+1]-integralXS[theXSType][Bin])/(bb-aa)*(eVEnergy-aa) ) * 1.e-16*CLHEP::cm2;
222                                                   216     
223     if( verboseLevel >= 3 ) G4cout << " crossS    217     if( verboseLevel >= 3 ) G4cout << " crossSection " <<  crossSection << " " <<integralXS[theXSType][Bin] << " + " << (integralXS[theXSType][Bin+1]-integralXS[theXSType][Bin]) << " / " << (bb-aa) << " *" << (eVEnergy-aa) << " * " << 1.e-16*CLHEP::cm2 << G4endl;;
224                                                   218     
225     //    SIGMA += NbOfAtomsPerVolume[elm] * c    219     //    SIGMA += NbOfAtomsPerVolume[elm] * crossSection;
226     SIGMA = NbOfMoleculesPerVolume * crossSect    220     SIGMA = NbOfMoleculesPerVolume * crossSection;
227     if( verboseLevel >= 2 ) G4cout << GetName(    221     if( verboseLevel >= 2 ) G4cout << GetName() << " ADDING SIGMA " << SIGMA << " NAtoms " << NbOfMoleculesPerVolume
228            << " Bin " << Bin << " TOTAL " << a    222            << " Bin " << Bin << " TOTAL " << aa << " " << bb 
229            << " XS " << integralXS[theXSType][    223            << " XS " << integralXS[theXSType][Bin]  << " " << integralXS[theXSType][Bin+1] << G4endl;
230   }                                               224   }
231                                                   225   
232   //-}                                            226   //-}
233                                                   227       
234       fValue = SIGMA > DBL_MIN ? 1./SIGMA : DB    228       fValue = SIGMA > DBL_MIN ? 1./SIGMA : DBL_MAX;
235     }                                             229     }
236                                                   230     
237     ptrVector->PutValue(ii, fValue);              231     ptrVector->PutValue(ii, fValue);
238     if( verboseLevel >= 2 ) G4cout << GetName(    232     if( verboseLevel >= 2 ) G4cout << GetName() << " BUILDXS " << ii << " : " << LowEdgeEnergy << " = " << fValue << G4endl;
239   }                                               233   }
240                                                   234   
241   theMeanFreePathTable->insertAt( matIdx , ptr    235   theMeanFreePathTable->insertAt( matIdx , ptrVector ) ;
242 }                                                 236 }
243                                                   237 
244                                                   238 
245 //....oooOO0OOooo........oooOO0OOooo........oo    239 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
246 G4double G4VLEPTSModel::SampleAngle(const G4Ma    240 G4double G4VLEPTSModel::SampleAngle(const G4Material* aMaterial, G4double e, G4double el) 
247 {                                                 241 {
248   G4double x;                                     242   G4double x;
249                                                   243 
250   if( e < 10001) {                                244   if( e < 10001) {
251     x = theDiffXS[aMaterial]->SampleAngleMT(e,    245     x = theDiffXS[aMaterial]->SampleAngleMT(e, el);
252   }                                               246   }
253   else {                                          247   else {
254     G4double Ei = e;                              248     G4double Ei = e;                                       //incidente
255     G4double Ed = e -el;                          249     G4double Ed = e -el;                                   //dispersado
256                                                   250       
257     G4double Pi = std::sqrt( std::pow( (Ei/27.    251     G4double Pi = std::sqrt( std::pow( (Ei/27.2/137),2) +2*Ei/27.2); //incidente
258     G4double Pd = std::sqrt( std::pow( (Ed/27.    252     G4double Pd = std::sqrt( std::pow( (Ed/27.2/137),2) +2*Ed/27.2); //dispersado
259                                                   253 
260     G4double Kmin = Pi - Pd;                      254     G4double Kmin = Pi - Pd;
261     G4double Kmax = Pi + Pd;                      255     G4double Kmax = Pi + Pd;
262                                                   256 
263     G4double KR = theRMTDistr[aMaterial]->Samp    257     G4double KR = theRMTDistr[aMaterial]->Sample(Kmin, Kmax);          //sorteo mom. transf.
264                                                   258       
265     G4double co = (Pi*Pi + Pd*Pd - KR*KR) / (2    259     G4double co = (Pi*Pi + Pd*Pd - KR*KR) / (2*Pi*Pd);    //cos ang. disp.
266     if( co > 1. ) co = 1.;                        260     if( co > 1. ) co = 1.;
267     x = std::acos(co); //*360/twopi;              261     x = std::acos(co); //*360/twopi;                         //ang. dispers.
268   }                                               262   }
269   return(x);                                      263   return(x);
270 }                                                 264 }
271                                                   265 
272 //....oooOO0OOooo........oooOO0OOooo........oo    266 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
273 G4ThreeVector G4VLEPTSModel::SampleNewDirectio    267 G4ThreeVector G4VLEPTSModel::SampleNewDirection(const G4Material* aMaterial, G4ThreeVector P0Dir, G4double e, G4double el) {
274                                                   268   
275   G4double x = SampleAngle(aMaterial, e, el);     269   G4double x = SampleAngle(aMaterial, e, el);
276                                                   270 
277   G4double cosTeta = std::cos(x); //*twopi/360    271   G4double cosTeta = std::cos(x); //*twopi/360.0);
278   G4double sinTeta = std::sqrt(1.0-cosTeta*cos    272   G4double sinTeta = std::sqrt(1.0-cosTeta*cosTeta);
279   G4double Phi     = CLHEP::twopi * G4UniformR    273   G4double Phi     = CLHEP::twopi * G4UniformRand() ;
280   G4double dirx    = sinTeta*std::cos(Phi) , d    274   G4double dirx    = sinTeta*std::cos(Phi) , diry = sinTeta*std::sin(Phi) , dirz = cosTeta ;
281                                                   275 
282   G4ThreeVector P1Dir(dirx, diry, dirz);          276   G4ThreeVector P1Dir(dirx, diry, dirz);
283 #ifdef DEBUG_LEPTS                                277 #ifdef DEBUG_LEPTS
284   if( verboseLevel >= 2 ) G4cout << " G4VLEPTS    278   if( verboseLevel >= 2 ) G4cout << " G4VLEPTSModel::SampleNewDirection " <<P1Dir << G4endl; 
285 #endif                                            279 #endif
286   P1Dir.rotateUz(P0Dir);                          280   P1Dir.rotateUz(P0Dir);
287 #ifdef DEBUG_LEPTS                                281 #ifdef DEBUG_LEPTS
288   if( verboseLevel >= 2 ) G4cout << " G4VLEPTS    282   if( verboseLevel >= 2 ) G4cout << " G4VLEPTSModel::SampleNewDirection rotated " <<P1Dir << " " << P0Dir <<  G4endl; 
289 #endif                                            283 #endif
290                                                   284 
291   return(P1Dir);                                  285   return(P1Dir);
292 }                                                 286 }
293                                                   287 
294                                                   288 
295 //....oooOO0OOooo........oooOO0OOooo........oo    289 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
296 G4ThreeVector G4VLEPTSModel::SampleNewDirectio    290 G4ThreeVector G4VLEPTSModel::SampleNewDirection(G4ThreeVector P0Dir, G4double x) 
297 {                                                 291 {
298   G4double cosTeta = std::cos(x); //*twopi/360    292   G4double cosTeta = std::cos(x); //*twopi/360.0);
299   G4double sinTeta = std::sqrt(1.0-cosTeta*cos    293   G4double sinTeta = std::sqrt(1.0-cosTeta*cosTeta);
300   G4double Phi     = CLHEP::twopi * G4UniformR    294   G4double Phi     = CLHEP::twopi * G4UniformRand() ;
301   G4double dirx    = sinTeta*std::cos(Phi) , d    295   G4double dirx    = sinTeta*std::cos(Phi) , diry = sinTeta*std::sin(Phi) , dirz = cosTeta ;
302                                                   296 
303   G4ThreeVector P1Dir( dirx,diry,dirz );          297   G4ThreeVector P1Dir( dirx,diry,dirz );
304   P1Dir.rotateUz(P0Dir);                          298   P1Dir.rotateUz(P0Dir);
305                                                   299 
306   return(P1Dir);                                  300   return(P1Dir);
307 }                                                 301 }
308                                                   302 
309                                                   303 
310 //....oooOO0OOooo........oooOO0OOooo........oo    304 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
311 G4double G4VLEPTSModel::SampleEnergyLoss(const    305 G4double G4VLEPTSModel::SampleEnergyLoss(const G4Material* aMaterial, G4double eMin, G4double eMax) 
312 {                                                 306 {
313   G4double el;                                    307   G4double el;
314   el = theElostDistr[aMaterial]->Sample(eMin/C    308   el = theElostDistr[aMaterial]->Sample(eMin/CLHEP::eV, eMax/CLHEP::eV)*CLHEP::eV;
315                                                   309 
316 #ifdef DEBUG_LEPTS                                310 #ifdef DEBUG_LEPTS
317   if( verboseLevel >= 2 ) G4cout << aMaterial-    311   if( verboseLevel >= 2 ) G4cout << aMaterial->GetName() <<"SampleEnergyLoss/eV " << el/CLHEP::eV << " eMax/eV " << eMax/CLHEP::eV << " "
318    << " " << GetName() << G4endl;                 312    << " " << GetName() << G4endl;
319 #endif                                            313 #endif
320   return el;                                      314   return el;
321 }                                                 315 }
322                                                   316 
323                                                   317 
324 //....oooOO0OOooo........oooOO0OOooo........oo    318 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
325 G4bool G4VLEPTSModel::ReadParam(const G4String << 319 G4bool G4VLEPTSModel::ReadParam(G4String fnParam, const G4Material* aMaterial ) 
326 {                                                 320 {
327   std::ifstream fin(fnParam);                     321   std::ifstream fin(fnParam);
328   if (!fin.is_open()) {                           322   if (!fin.is_open()) {
329     G4Exception("G4VLEPTSModel::ReadParam",       323     G4Exception("G4VLEPTSModel::ReadParam",
330     "",                                           324     "",
331     JustWarning,                                  325     JustWarning,
332     (G4String("File not found: ")+ fnParam).c_    326     (G4String("File not found: ")+ fnParam).c_str());
333     return false;                                 327     return false;
334   }                                               328   }
335                                                   329 
336   G4double IonisPot, IonisPotInt;                 330   G4double IonisPot, IonisPotInt;
337                                                   331 
338   fin >> IonisPot >> IonisPotInt;                 332   fin >> IonisPot >> IonisPotInt;
339   if( verboseLevel >= 1 ) G4cout << "Read para    333   if( verboseLevel >= 1 ) G4cout << "Read param   (" << fnParam << ")\t IonisPot: " << IonisPot
340    << " IonisPotInt: "  << IonisPotInt << G4en    334    << " IonisPotInt: "  << IonisPotInt << G4endl;
341                                                   335 
342   theIonisPot[aMaterial] = IonisPot * CLHEP::e    336   theIonisPot[aMaterial] = IonisPot * CLHEP::eV;
343   theIonisPotInt[aMaterial] = IonisPotInt * CL    337   theIonisPotInt[aMaterial] = IonisPotInt * CLHEP::eV;
344                                                   338 
345   G4double MolecularMass = 0;                     339   G4double MolecularMass = 0;
346   auto  nelem = (G4int)aMaterial->GetNumberOfE << 340   size_t nelem = aMaterial->GetNumberOfElements();
347   const G4int*  atomsV = aMaterial->GetAtomsVe    341   const G4int*  atomsV = aMaterial->GetAtomsVector();
348   for( G4int ii = 0; ii < nelem; ++ii ) {      << 342   for( size_t ii = 0; ii < nelem; ii++ ) {
349     MolecularMass += aMaterial->GetElement(ii)    343     MolecularMass += aMaterial->GetElement(ii)->GetA()*atomsV[ii]/CLHEP::g;
350     //    G4cout << " MMASS1 " << mmass/CLHEP:    344     //    G4cout << " MMASS1 " << mmass/CLHEP::g << " " << aMaterial->GetElement(ii)->GetName() << " " << aMaterial->GetElement(ii)->GetA()/CLHEP::g << G4endl;
351   }                                               345   }
352   //  G4cout << " MMASS " << MolecularMass <<     346   //  G4cout << " MMASS " << MolecularMass << " " << MolecularMass*CLHEP::g <<  " ME " << mmass << " " << mmass/CLHEP::g << G4endl; 
353   theMolecularMass[aMaterial] = MolecularMass*    347   theMolecularMass[aMaterial] = MolecularMass* CLHEP::g/CLHEP::mole;
354   //  theMolecularMass[aMaterial] = aMaterial-    348   //  theMolecularMass[aMaterial] = aMaterial->GetMassOfMolecule()*CLHEP::Avogadro;  // Material mixtures do not calculate molecular mass
355                                                   349 
356   if( verboseLevel >= 1) G4cout << " IonisPot:    350   if( verboseLevel >= 1) G4cout << " IonisPot: " << IonisPot/CLHEP::eV << " eV " 
357         << " IonisPotInt: " << IonisPotInt/CLH    351         << " IonisPotInt: " << IonisPotInt/CLHEP::eV << " eV" 
358         << " MolecularMass " << MolecularMass/    352         << " MolecularMass " << MolecularMass/(CLHEP::g/CLHEP::mole) << " g/mole" << G4endl;
359                                                   353 
360   return true;                                    354   return true;
361 }                                                 355 }
362                                                   356 
363 //....oooOO0OOooo........oooOO0OOooo........oo    357 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
364 std::map< G4int, std::vector<G4double> > G4VLE << 358 std::map< G4int, std::vector<G4double> > G4VLEPTSModel::ReadIXS(G4String fnIXS, const G4Material* aMaterial ) 
365 {                                                 359 {
366   std::map< G4int, std::vector<G4double> > int    360   std::map< G4int, std::vector<G4double> > integralXS; // process type - energy
367   //G4cout << "fnIXS (" << fnIXS << ")" << G4e    361   //G4cout << "fnIXS (" << fnIXS << ")" << G4endl;
368                                                   362 
369   std::ifstream fin(fnIXS);                       363   std::ifstream fin(fnIXS);
370   if (!fin.is_open()) {                           364   if (!fin.is_open()) {
371     G4Exception("G4VLEPTSModel::ReadIXS",         365     G4Exception("G4VLEPTSModel::ReadIXS",
372     "",                                           366     "",
373     JustWarning,                                  367     JustWarning,
374     (G4String("File not found: ")+ fnIXS).c_st    368     (G4String("File not found: ")+ fnIXS).c_str());
375     return integralXS;                            369     return integralXS;
376   }                                               370   }
377                                                   371 
378   G4int nXSdat, nXSsub;                           372   G4int nXSdat, nXSsub;
379   fin >> nXSdat >> nXSsub;                        373   fin >> nXSdat >> nXSsub;
380   if( verboseLevel >= 1 ) G4cout << "Read IXS     374   if( verboseLevel >= 1 ) G4cout << "Read IXS   (" << fnIXS << ")\t nXSdat: " << nXSdat
381    << " nXSsub: "  << nXSsub << G4endl;           375    << " nXSsub: "  << nXSsub << G4endl;
382   theNXSdat[aMaterial] = nXSdat;                  376   theNXSdat[aMaterial] = nXSdat;
383   theNXSsub[aMaterial] = nXSsub;                  377   theNXSsub[aMaterial] = nXSsub;
384                                                   378 
385   G4double xsdat;                                 379   G4double xsdat;
386   for (G4int ip=0; ip<=nXSsub; ip++) {            380   for (G4int ip=0; ip<=nXSsub; ip++) {   
387     integralXS[ip].push_back(0.);                 381     integralXS[ip].push_back(0.);
388   }                                               382   }
389   for (G4int ie=1; ie<=nXSdat; ie++) {            383   for (G4int ie=1; ie<=nXSdat; ie++) {
390     for (G4int ip=0; ip<=nXSsub; ip++) {          384     for (G4int ip=0; ip<=nXSsub; ip++) {   
391       fin >> xsdat;                               385       fin >> xsdat;
392       integralXS[ip].push_back(xsdat);            386       integralXS[ip].push_back(xsdat);
393       if( verboseLevel >= 3 )  G4cout << GetNa    387       if( verboseLevel >= 3 )  G4cout << GetName() << " FILL IXS " << ip << " " << ie << " = " << integralXS[ip][ie] << " " << xsdat << G4endl; 
394       // xsdat 1e-16*cm2                          388       // xsdat 1e-16*cm2
395     }                                             389     }
396   }                                               390   }
397   fin.close();                                    391   fin.close();
398                                                   392 
399   return integralXS;                              393   return integralXS;
400 }                                                 394 }
401                                                   395 
402                                                   396