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Geant4/processes/electromagnetic/adjoint/src/G4AdjointIonIonisationModel.cc

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Diff markup

Differences between /processes/electromagnetic/adjoint/src/G4AdjointIonIonisationModel.cc (Version 11.3.0) and /processes/electromagnetic/adjoint/src/G4AdjointIonIonisationModel.cc (Version 9.0.p2)


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 26                                                   
 27 #include "G4AdjointIonIonisationModel.hh"         
 28                                                   
 29 #include "G4AdjointCSManager.hh"                  
 30 #include "G4AdjointElectron.hh"                   
 31 #include "G4BetheBlochModel.hh"                   
 32 #include "G4BraggIonModel.hh"                     
 33 #include "G4GenericIon.hh"                        
 34 #include "G4NistManager.hh"                       
 35 #include "G4ParticleChange.hh"                    
 36 #include "G4PhysicalConstants.hh"                 
 37 #include "G4SystemOfUnits.hh"                     
 38 #include "G4TrackStatus.hh"                       
 39                                                   
 40 //////////////////////////////////////////////    
 41 G4AdjointIonIonisationModel::G4AdjointIonIonis    
 42   : G4VEmAdjointModel("Adjoint_IonIonisation")    
 43 {                                                 
 44   fUseMatrix               = true;                
 45   fUseMatrixPerElement     = true;                
 46   fApplyCutInRange         = true;                
 47   fOneMatrixForAllElements = true;                
 48   fSecondPartSameType      = false;               
 49                                                   
 50   // The direct EM Model is taken as BetheBloc    
 51   // computation of the differential cross sec    
 52   // The Bragg model could be used as an alter    
 53   // differential cross section                   
 54                                                   
 55   fBetheBlochDirectEMModel  = new G4BetheBloch    
 56   fBraggIonDirectEMModel    = new G4BraggIonMo    
 57   fAdjEquivDirectSecondPart = G4AdjointElectro    
 58   fDirectPrimaryPart        = nullptr;            
 59 }                                                 
 60                                                   
 61 //////////////////////////////////////////////    
 62 G4AdjointIonIonisationModel::~G4AdjointIonIoni    
 63                                                   
 64 //////////////////////////////////////////////    
 65 void G4AdjointIonIonisationModel::SampleSecond    
 66   const G4Track& aTrack, G4bool isScatProjToPr    
 67   G4ParticleChange* fParticleChange)              
 68 {                                                 
 69   const G4DynamicParticle* theAdjointPrimary =    
 70                                                   
 71   // Elastic inverse scattering                   
 72   G4double adjointPrimKinEnergy = theAdjointPr    
 73   G4double adjointPrimP         = theAdjointPr    
 74                                                   
 75   if(adjointPrimKinEnergy > GetHighEnergyLimit    
 76   {                                               
 77     return;                                       
 78   }                                               
 79                                                   
 80   // Sample secondary energy                      
 81   G4double projectileKinEnergy =                  
 82     SampleAdjSecEnergyFromCSMatrix(adjointPrim    
 83   // Caution !!!this weight correction should     
 84   CorrectPostStepWeight(fParticleChange, aTrac    
 85                         adjointPrimKinEnergy,     
 86                         isScatProjToProj);        
 87                                                   
 88   // Kinematics:                                  
 89   // we consider a two body elastic scattering    
 90   // the projectile knock on an e- at rest and    
 91   G4double projectileM0          = fAdjEquivDi    
 92   G4double projectileTotalEnergy = projectileM    
 93   G4double projectileP2 =                         
 94     projectileTotalEnergy * projectileTotalEne    
 95                                                   
 96   // Companion                                    
 97   G4double companionM0 = fAdjEquivDirectPrimPa    
 98   if(isScatProjToProj)                            
 99   {                                               
100     companionM0 = fAdjEquivDirectSecondPart->G    
101   }                                               
102   G4double companionTotalEnergy =                 
103     companionM0 + projectileKinEnergy - adjoin    
104   G4double companionP2 =                          
105     companionTotalEnergy * companionTotalEnerg    
106                                                   
107   // Projectile momentum                          
108   G4double P_parallel =                           
109     (adjointPrimP * adjointPrimP + projectileP    
110     (2. * adjointPrimP);                          
111   G4double P_perp = std::sqrt(projectileP2 - P    
112   G4ThreeVector dir_parallel = theAdjointPrima    
113   G4double phi               = G4UniformRand()    
114   G4ThreeVector projectileMomentum =              
115     G4ThreeVector(P_perp * std::cos(phi), P_pe    
116   projectileMomentum.rotateUz(dir_parallel);      
117                                                   
118   if(!isScatProjToProj)                           
119   {  // kill the primary and add a secondary      
120     fParticleChange->ProposeTrackStatus(fStopA    
121     fParticleChange->AddSecondary(                
122       new G4DynamicParticle(fAdjEquivDirectPri    
123   }                                               
124   else                                            
125   {                                               
126     fParticleChange->ProposeEnergy(projectileK    
127     fParticleChange->ProposeMomentumDirection(    
128   }                                               
129 }                                                 
130                                                   
131 //////////////////////////////////////////////    
132 G4double G4AdjointIonIonisationModel::DiffCros    
133   G4double kinEnergyProj, G4double kinEnergyPr    
134 {                                                 
135   // Probably that here the Bragg Model should    
136   // kinEnergyProj/nuc<2MeV                       
137   G4double dSigmadEprod = 0.;                     
138   G4double Emax_proj    = GetSecondAdjEnergyMa    
139   G4double Emin_proj    = GetSecondAdjEnergyMi    
140                                                   
141   G4double kinEnergyProjScaled = fMassRatio *     
142                                                   
143   // the produced particle should have a kinet    
144   // projectile                                   
145   if(kinEnergyProj > Emin_proj && kinEnergyPro    
146   {                                               
147     G4double Tmax = kinEnergyProj;                
148                                                   
149     G4double E1 = kinEnergyProd;                  
150     G4double E2 = kinEnergyProd * 1.000001;       
151     G4double dE = (E2 - E1);                      
152     G4double sigma1, sigma2;                      
153     fDirectModel = fBraggIonDirectEMModel;        
154     if(kinEnergyProjScaled > 2. * MeV && !fUse    
155       fDirectModel = fBetheBlochDirectEMModel;    
156     sigma1 = fDirectModel->ComputeCrossSection    
157       fDirectPrimaryPart, kinEnergyProj, Z, A,    
158     sigma2 = fDirectModel->ComputeCrossSection    
159       fDirectPrimaryPart, kinEnergyProj, Z, A,    
160                                                   
161     dSigmadEprod = (sigma1 - sigma2) / dE;        
162                                                   
163     if(dSigmadEprod > 1.)                         
164     {                                             
165       G4cout << "sigma1 " << kinEnergyProj / M    
166              << '\t' << sigma1 << G4endl;         
167       G4cout << "sigma2 " << kinEnergyProj / M    
168              << '\t' << sigma2 << G4endl;         
169       G4cout << "dsigma " << kinEnergyProj / M    
170              << '\t' << dSigmadEprod << G4endl    
171     }                                             
172                                                   
173     if(fDirectModel == fBetheBlochDirectEMMode    
174     {                                             
175       // correction of differential cross sect    
176       // the suppression of particle at second    
177       // Bethe Bloch Model. This correction co    
178       // probability function used to test the    
179       // code taken from G4BetheBlochModel::Sa    
180                                                   
181       G4double deltaKinEnergy = kinEnergyProd;    
182                                                   
183       G4double x = fFormFact * deltaKinEnergy;    
184       if(x > 1.e-6)                               
185       {                                           
186         G4double totEnergy = kinEnergyProj + f    
187         G4double etot2     = totEnergy * totEn    
188         G4double beta2 = kinEnergyProj * (kinE    
189         G4double f1    = 0.0;                     
190         G4double f     = 1.0 - beta2 * deltaKi    
191         if(0.5 == fSpin)                          
192         {                                         
193           f1 = 0.5 * deltaKinEnergy * deltaKin    
194           f += f1;                                
195         }                                         
196         G4double x1 = 1.0 + x;                    
197         G4double gg = 1.0 / (x1 * x1);            
198         if(0.5 == fSpin)                          
199         {                                         
200           G4double x2 =                           
201             0.5 * electron_mass_c2 * deltaKinE    
202           gg *= (1.0 + fMagMoment2 * (x2 - f1     
203         }                                         
204         if(gg > 1.0)                              
205         {                                         
206           G4cout << "### G4BetheBlochModel in     
207                  << G4endl;                       
208           gg = 1.;                                
209         }                                         
210         dSigmadEprod *= gg;                       
211       }                                           
212     }                                             
213   }                                               
214   return dSigmadEprod;                            
215 }                                                 
216                                                   
217 //////////////////////////////////////////////    
218 void G4AdjointIonIonisationModel::SetIon(G4Par    
219                                          G4Par    
220 {                                                 
221   fDirectPrimaryPart      = fwd_ion;              
222   fAdjEquivDirectPrimPart = adj_ion;              
223                                                   
224   DefineProjectileProperty();                     
225 }                                                 
226                                                   
227 //////////////////////////////////////////////    
228 void G4AdjointIonIonisationModel::CorrectPostS    
229   G4ParticleChange* fParticleChange, G4double     
230   G4double adjointPrimKinEnergy, G4double proj    
231 {                                                 
232   // It is needed because the direct cross sec    
233   // differential cross section is not the one    
234   // the direct model where the GenericIon stu    
235   // of effective charge.  In the direct model    
236   // not reflect the integral cross section. T    
237   // we used to compute the differential CS ma    
238   // the forward case despite the fact that it    
239   // the FWD case. For this reason an extra we    
240   // end.                                         
241                                                   
242   G4double new_weight = old_weight;               
243                                                   
244   // the correction of CS due to the problem e    
245   G4double kinEnergyProjScaled = fMassRatio *     
246   fDirectModel                 = fBraggIonDire    
247   if(kinEnergyProjScaled > 2. * MeV && !fUseOn    
248     fDirectModel = fBetheBlochDirectEMModel;      
249   G4double UsedFwdCS = fDirectModel->ComputeCr    
250     fDirectPrimaryPart, projectileKinEnergy, 1    
251   G4double chargeSqRatio = 1.;                    
252   if(fChargeSquare > 1.)                          
253     chargeSqRatio = fDirectModel->GetChargeSqu    
254       fDirectPrimaryPart, fCurrentMaterial, pr    
255   G4double CorrectFwdCS =                         
256     chargeSqRatio * fDirectModel->ComputeCross    
257                       G4GenericIon::GenericIon    
258                       fTcutSecond, 1.e20);        
259   // May be some check is needed if UsedFwdCS     
260   // avoid a secondary to be produced,            
261   if(UsedFwdCS > 0.)                              
262     new_weight *= CorrectFwdCS / UsedFwdCS;       
263                                                   
264   // additional CS correction needed for cross    
265   // May be wrong for ions. Most of the time n    
266   new_weight *=                                   
267     G4AdjointCSManager::GetAdjointCSManager()-    
268     fCsBiasingFactor;                             
269                                                   
270   new_weight *= projectileKinEnergy / adjointP    
271                                                   
272   fParticleChange->SetParentWeightByProcess(fa    
273   fParticleChange->SetSecondaryWeightByProcess    
274   fParticleChange->ProposeParentWeight(new_wei    
275 }                                                 
276                                                   
277 //////////////////////////////////////////////    
278 void G4AdjointIonIonisationModel::DefineProjec    
279 {                                                 
280   // Slightly modified code taken from G4Bethe    
281   G4String pname = fDirectPrimaryPart->GetPart    
282                                                   
283   fMass           = fDirectPrimaryPart->GetPDG    
284   fMassRatio      = G4GenericIon::GenericIon()    
285   fSpin           = fDirectPrimaryPart->GetPDG    
286   G4double q      = fDirectPrimaryPart->GetPDG    
287   fChargeSquare   = q * q;                        
288   fRatio          = electron_mass_c2 / fMass;     
289   fOnePlusRatio2  = (1. + fRatio) * (1. + fRat    
290   fOneMinusRatio2 = (1. - fRatio) * (1. - fRat    
291   G4double magmom = fDirectPrimaryPart->GetPDG    
292                     (0.5 * eplus * hbar_Planck    
293   fMagMoment2 = magmom * magmom - 1.0;            
294   if(fDirectPrimaryPart->GetLeptonNumber() ==     
295   {                                               
296     G4double x = 0.8426 * GeV;                    
297     if(fSpin == 0.0 && fMass < GeV)               
298     {                                             
299       x = 0.736 * GeV;                            
300     }                                             
301     else if(fMass > GeV)                          
302     {                                             
303       x /= G4NistManager::Instance()->GetZ13(f    
304     }                                             
305     fFormFact = 2.0 * electron_mass_c2 / (x *     
306   }                                               
307 }                                                 
308                                                   
309 //////////////////////////////////////////////    
310 G4double G4AdjointIonIonisationModel::GetSecon    
311   G4double primAdjEnergy)                         
312 {                                                 
313   return primAdjEnergy * fOnePlusRatio2 /         
314          (fOneMinusRatio2 - 2. * fRatio * prim    
315 }                                                 
316                                                   
317 //////////////////////////////////////////////    
318 G4double G4AdjointIonIonisationModel::GetSecon    
319   G4double primAdjEnergy, G4double tcut)          
320 {                                                 
321   return primAdjEnergy + tcut;                    
322 }                                                 
323                                                   
324 //////////////////////////////////////////////    
325 G4double G4AdjointIonIonisationModel::GetSecon    
326   G4double)                                       
327 {                                                 
328   return GetHighEnergyLimit();                    
329 }                                                 
330                                                   
331 //////////////////////////////////////////////    
332 G4double G4AdjointIonIonisationModel::GetSecon    
333   G4double primAdjEnergy)                         
334 {                                                 
335   return (2. * primAdjEnergy - 4. * fMass +       
336           std::sqrt(4. * primAdjEnergy * primA    
337                     8. * primAdjEnergy * fMass    
338          4.;                                      
339 }                                                 
340