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Geant4/processes/electromagnetic/adjoint/src/G4AdjointComptonModel.cc

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Diff markup

Differences between /processes/electromagnetic/adjoint/src/G4AdjointComptonModel.cc (Version 11.3.0) and /processes/electromagnetic/adjoint/src/G4AdjointComptonModel.cc (Version 5.1)


  1 //                                                  1 
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  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
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 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
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 25 //                                                
 26 //                                                
 27                                                   
 28 #include "G4AdjointComptonModel.hh"               
 29                                                   
 30 #include "G4AdjointCSManager.hh"                  
 31 #include "G4AdjointElectron.hh"                   
 32 #include "G4AdjointGamma.hh"                      
 33 #include "G4Gamma.hh"                             
 34 #include "G4KleinNishinaCompton.hh"               
 35 #include "G4ParticleChange.hh"                    
 36 #include "G4PhysicalConstants.hh"                 
 37 #include "G4SystemOfUnits.hh"                     
 38 #include "G4TrackStatus.hh"                       
 39 #include "G4VEmProcess.hh"                        
 40                                                   
 41 //////////////////////////////////////////////    
 42 G4AdjointComptonModel::G4AdjointComptonModel()    
 43   : G4VEmAdjointModel("AdjointCompton")           
 44 {                                                 
 45   SetApplyCutInRange(false);                      
 46   SetUseMatrix(false);                            
 47   SetUseMatrixPerElement(true);                   
 48   SetUseOnlyOneMatrixForAllElements(true);        
 49   fAdjEquivDirectPrimPart   = G4AdjointGamma::    
 50   fAdjEquivDirectSecondPart = G4AdjointElectro    
 51   fDirectPrimaryPart        = G4Gamma::Gamma()    
 52   fSecondPartSameType       = false;              
 53   fDirectModel =                                  
 54     new G4KleinNishinaCompton(G4Gamma::Gamma()    
 55 }                                                 
 56                                                   
 57 //////////////////////////////////////////////    
 58 G4AdjointComptonModel::~G4AdjointComptonModel(    
 59                                                   
 60 //////////////////////////////////////////////    
 61 void G4AdjointComptonModel::SampleSecondaries(    
 62                                                   
 63                                                   
 64 {                                                 
 65   if(!fUseMatrix)                                 
 66     return RapidSampleSecondaries(aTrack, isSc    
 67                                                   
 68   // A recall of the compton scattering law:      
 69   // Egamma2=Egamma1/(1+(Egamma1/E0_electron)(    
 70   // Therefore Egamma2_max= Egamma2(cos_th=1)     
 71   // and       Egamma2_min= Egamma2(cos_th=-1)    
 72   //             Egamma1/(1+2.(Egamma1/E0_elec    
 73   const G4DynamicParticle* theAdjointPrimary =    
 74   G4double adjointPrimKinEnergy = theAdjointPr    
 75   if(adjointPrimKinEnergy > GetHighEnergyLimit    
 76   {                                               
 77     return;                                       
 78   }                                               
 79                                                   
 80   // Sample secondary energy                      
 81   G4double gammaE1;                               
 82   gammaE1 =                                       
 83     SampleAdjSecEnergyFromCSMatrix(adjointPrim    
 84                                                   
 85   // gammaE2                                      
 86   G4double gammaE2 = adjointPrimKinEnergy;        
 87   if(!isScatProjToProj)                           
 88     gammaE2 = gammaE1 - adjointPrimKinEnergy;     
 89                                                   
 90   // Cos th                                       
 91   G4double cos_th = 1. + electron_mass_c2 * (1    
 92   if(!isScatProjToProj)                           
 93   {                                               
 94     cos_th =                                      
 95       (gammaE1 - gammaE2 * cos_th) / theAdjoin    
 96   }                                               
 97   G4double sin_th = 0.;                           
 98   if(std::abs(cos_th) > 1.)                       
 99   {                                               
100     if(cos_th > 0.)                               
101     {                                             
102       cos_th = 1.;                                
103     }                                             
104     else                                          
105       cos_th = -1.;                               
106     sin_th = 0.;                                  
107   }                                               
108   else                                            
109     sin_th = std::sqrt(1. - cos_th * cos_th);     
110                                                   
111   // gamma0 momentum                              
112   G4ThreeVector dir_parallel = theAdjointPrima    
113   G4double phi               = G4UniformRand()    
114   G4ThreeVector gammaMomentum1 =                  
115     gammaE1 *                                     
116     G4ThreeVector(std::cos(phi) * sin_th, std:    
117   gammaMomentum1.rotateUz(dir_parallel);          
118                                                   
119   // correct the weight of particles before ad    
120   CorrectPostStepWeight(fParticleChange, aTrac    
121                         adjointPrimKinEnergy,     
122                                                   
123   if(!isScatProjToProj)                           
124   {  // kill the primary and add a secondary      
125     fParticleChange->ProposeTrackStatus(fStopA    
126     fParticleChange->AddSecondary(                
127       new G4DynamicParticle(fAdjEquivDirectPri    
128   }                                               
129   else                                            
130   {                                               
131     fParticleChange->ProposeEnergy(gammaE1);      
132     fParticleChange->ProposeMomentumDirection(    
133   }                                               
134 }                                                 
135                                                   
136 //////////////////////////////////////////////    
137 void G4AdjointComptonModel::RapidSampleSeconda    
138   const G4Track& aTrack, G4bool isScatProjToPr    
139   G4ParticleChange* fParticleChange)              
140 {                                                 
141   const G4DynamicParticle* theAdjointPrimary =    
142   DefineCurrentMaterial(aTrack.GetMaterialCuts    
143                                                   
144   G4double adjointPrimKinEnergy = theAdjointPr    
145                                                   
146   if(adjointPrimKinEnergy > GetHighEnergyLimit    
147   {                                               
148     return;                                       
149   }                                               
150                                                   
151   G4double diffCSUsed =                           
152     0.1 * fCurrentMaterial->GetElectronDensity    
153   G4double gammaE1 = 0.;                          
154   G4double gammaE2 = 0.;                          
155   if(!isScatProjToProj)                           
156   {                                               
157     G4double Emax = GetSecondAdjEnergyMaxForPr    
158     G4double Emin = GetSecondAdjEnergyMinForPr    
159     if(Emin >= Emax)                              
160       return;                                     
161     G4double f1 = (Emin - adjointPrimKinEnergy    
162     G4double f2 = (Emax - adjointPrimKinEnergy    
163     gammaE1 = adjointPrimKinEnergy / (1. - f1     
164     gammaE2 = gammaE1 - adjointPrimKinEnergy;     
165     diffCSUsed =                                  
166       diffCSUsed *                                
167       (1. + 2. * std::log(1. + electron_mass_c    
168       adjointPrimKinEnergy / gammaE1 / gammaE2    
169   }                                               
170   else                                            
171   {                                               
172     G4double Emax =                               
173       GetSecondAdjEnergyMaxForScatProjToProj(a    
174     G4double Emin =                               
175       GetSecondAdjEnergyMinForScatProjToProj(a    
176     if(Emin >= Emax)                              
177       return;                                     
178     gammaE2    = adjointPrimKinEnergy;            
179     gammaE1    = Emin * std::pow(Emax / Emin,     
180     diffCSUsed = diffCSUsed / gammaE1;            
181   }                                               
182                                                   
183   // Weight correction                            
184   // First w_corr is set to the ratio between     
185   G4double w_corr = fOutsideWeightFactor;         
186   if(fInModelWeightCorr)                          
187   {                                               
188     w_corr =                                      
189       G4AdjointCSManager::GetAdjointCSManager(    
190   }                                               
191   // Then another correction is needed because    
192   // been used rather than the one consistent     
193                                                   
194   G4double diffCS =                               
195     DiffCrossSectionPerAtomPrimToScatPrim(gamm    
196   if(diffCS > 0.)                                 
197     diffCS /= fDirectCS;  // here we have the     
198   // And we remultiply by the lambda of the fo    
199   diffCS *= fDirectProcess->GetCrossSection(ga    
200                                                   
201   w_corr *= diffCS / diffCSUsed;                  
202                                                   
203   G4double new_weight = aTrack.GetWeight() * w    
204   fParticleChange->SetParentWeightByProcess(fa    
205   fParticleChange->SetSecondaryWeightByProcess    
206   fParticleChange->ProposeParentWeight(new_wei    
207                                                   
208   G4double cos_th = 1. + electron_mass_c2 * (1    
209   if(!isScatProjToProj)                           
210   {                                               
211     G4double p_elec = theAdjointPrimary->GetTo    
212     cos_th          = (gammaE1 - gammaE2 * cos    
213   }                                               
214   G4double sin_th = 0.;                           
215   if(std::abs(cos_th) > 1.)                       
216   {                                               
217     if(cos_th > 0.)                               
218     {                                             
219       cos_th = 1.;                                
220     }                                             
221     else                                          
222       cos_th = -1.;                               
223   }                                               
224   else                                            
225     sin_th = std::sqrt(1. - cos_th * cos_th);     
226                                                   
227   // gamma0 momentum                              
228   G4ThreeVector dir_parallel = theAdjointPrima    
229   G4double phi               = G4UniformRand()    
230   G4ThreeVector gammaMomentum1 =                  
231     gammaE1 *                                     
232     G4ThreeVector(std::cos(phi) * sin_th, std:    
233   gammaMomentum1.rotateUz(dir_parallel);          
234                                                   
235   if(!isScatProjToProj)                           
236   {  // kill the primary and add a secondary      
237     fParticleChange->ProposeTrackStatus(fStopA    
238     fParticleChange->AddSecondary(                
239       new G4DynamicParticle(fAdjEquivDirectPri    
240   }                                               
241   else                                            
242   {                                               
243     fParticleChange->ProposeEnergy(gammaE1);      
244     fParticleChange->ProposeMomentumDirection(    
245   }                                               
246 }                                                 
247                                                   
248 //////////////////////////////////////////////    
249 // The implementation here is correct for ener    
250 // photoelectric and compton scattering the me    
251 G4double G4AdjointComptonModel::DiffCrossSecti    
252   G4double gamEnergy0, G4double kinEnergyElec,    
253 {                                                 
254   G4double gamEnergy1   = gamEnergy0 - kinEner    
255   G4double dSigmadEprod = 0.;                     
256   if(gamEnergy1 > 0.)                             
257     dSigmadEprod =                                
258       DiffCrossSectionPerAtomPrimToScatPrim(ga    
259   return dSigmadEprod;                            
260 }                                                 
261                                                   
262 //////////////////////////////////////////////    
263 G4double G4AdjointComptonModel::DiffCrossSecti    
264   G4double gamEnergy0, G4double gamEnergy1, G4    
265 {                                                 
266   // Based on Klein Nishina formula               
267   // In the forward case (see G4KleinNishinaCo    
268   // parametrised but the secondaries are samp    
269   // differential cross section. The different    
270   // is therefore the cross section multiplied    
271   // differential Klein Nishina cross section     
272                                                   
273   // Klein Nishina Cross Section                  
274   G4double epsilon           = gamEnergy0 / el    
275   G4double one_plus_two_epsi = 1. + 2. * epsil    
276   if(gamEnergy1 > gamEnergy0 || gamEnergy1 < g    
277   {                                               
278     return 0.;                                    
279   }                                               
280                                                   
281   G4double CS = std::log(one_plus_two_epsi) *     
282                 (1. - 2. * (1. + epsilon) / (e    
283   CS +=                                           
284     4. / epsilon + 0.5 * (1. - 1. / (one_plus_    
285   CS /= epsilon;                                  
286   // Note that the pi*re2*Z factor is neglecte    
287   // computing dCS_dE1/CS in the differential     
288                                                   
289   // Klein Nishina Differential Cross Section     
290   G4double epsilon1 = gamEnergy1 / electron_ma    
291   G4double v        = epsilon1 / epsilon;         
292   G4double term1    = 1. + 1. / epsilon - 1. /    
293   G4double dCS_dE1  = 1. / v + v + term1 * ter    
294   dCS_dE1 *= 1. / epsilon / gamEnergy0;           
295                                                   
296   // Normalised to the CS used in G4              
297   fDirectCS = fDirectModel->ComputeCrossSectio    
298     G4Gamma::Gamma(), gamEnergy0, Z, 0., 0., 0    
299                                                   
300   dCS_dE1 *= fDirectCS / CS;                      
301                                                   
302   return dCS_dE1;                                 
303 }                                                 
304                                                   
305 //////////////////////////////////////////////    
306 G4double G4AdjointComptonModel::GetSecondAdjEn    
307   G4double primAdjEnergy)                         
308 {                                                 
309   G4double inv_e_max = 1. / primAdjEnergy - 2.    
310   G4double e_max     = GetHighEnergyLimit();      
311   if(inv_e_max > 0.)                              
312     e_max = std::min(1. / inv_e_max, e_max);      
313   return e_max;                                   
314 }                                                 
315                                                   
316 //////////////////////////////////////////////    
317 G4double G4AdjointComptonModel::GetSecondAdjEn    
318   G4double primAdjEnergy)                         
319 {                                                 
320   G4double half_e = primAdjEnergy / 2.;           
321   return half_e + std::sqrt(half_e * (electron    
322 }                                                 
323                                                   
324 //////////////////////////////////////////////    
325 G4double G4AdjointComptonModel::AdjointCrossSe    
326   const G4MaterialCutsCouple* aCouple, G4doubl    
327   G4bool isScatProjToProj)                        
328 {                                                 
329   if(fUseMatrix)                                  
330     return G4VEmAdjointModel::AdjointCrossSect    
331                                                   
332   DefineCurrentMaterial(aCouple);                 
333                                                   
334   G4float Cross     = 0.;                         
335   G4float Emax_proj = 0.;                         
336   G4float Emin_proj = 0.;                         
337   if(!isScatProjToProj)                           
338   {                                               
339     Emax_proj = GetSecondAdjEnergyMaxForProdTo    
340     Emin_proj = GetSecondAdjEnergyMinForProdTo    
341     if(Emax_proj > Emin_proj)                     
342     {                                             
343       Cross = 0.1 *                               
344               std::log((Emax_proj - G4float(pr    
345                        Emax_proj / (Emin_proj     
346               (1. + 2. * std::log(G4float(1. +    
347     }                                             
348   }                                               
349   else                                            
350   {                                               
351     Emax_proj = GetSecondAdjEnergyMaxForScatPr    
352     Emin_proj = GetSecondAdjEnergyMinForScatPr    
353     if(Emax_proj > Emin_proj)                     
354     {                                             
355       Cross = 0.1 * std::log(Emax_proj / Emin_    
356     }                                             
357   }                                               
358                                                   
359   Cross *= fCurrentMaterial->GetElectronDensit    
360   fLastCS = Cross;                                
361   return double(Cross);                           
362 }                                                 
363