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Geant4/examples/advanced/eRosita/physics/src/G4LowEnergyCompton.cc

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Differences between /examples/advanced/eRosita/physics/src/G4LowEnergyCompton.cc (Version 11.3.0) and /examples/advanced/eRosita/physics/src/G4LowEnergyCompton.cc (Version 5.2)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
  7 // * conditions of the Geant4 Software License    
  8 // * LICENSE and available at  http://cern.ch/    
  9 // * include a list of copyright holders.         
 10 // *                                              
 11 // * Neither the authors of this software syst    
 12 // * institutes,nor the agencies providing fin    
 13 // * work  make  any representation or  warran    
 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26 //                                                
 27 // Author: A. Forti                               
 28 //         Maria Grazia Pia (Maria.Grazia.Pia@    
 29 //                                                
 30 // History:                                       
 31 // --------                                       
 32 // Added Livermore data table construction met    
 33 // Modified BuildMeanFreePath to read new data    
 34 // Modified PostStepDoIt to insert sampling wi    
 35 // Added SelectRandomAtom A. Forti                
 36 // Added map of the elements A. Forti             
 37 // 24.04.2001 V.Ivanchenko - Remove RogueWave     
 38 // 06.08.2001 MGP          - Revised according    
 39 // 22.01.2003 V.Ivanchenko - Cut per region       
 40 // 10.03.2003 V.Ivanchenko - Remove CutPerMate    
 41 // 24.04.2003 V.Ivanchenko - Cut per region mf    
 42 //                                                
 43 // -------------------------------------------    
 44                                                   
 45 #include "G4LowEnergyCompton.hh"                  
 46 #include "Randomize.hh"                           
 47 #include "G4PhysicalConstants.hh"                 
 48 #include "G4SystemOfUnits.hh"                     
 49 #include "G4ParticleDefinition.hh"                
 50 #include "G4Track.hh"                             
 51 #include "G4Step.hh"                              
 52 #include "G4ForceCondition.hh"                    
 53 #include "G4Gamma.hh"                             
 54 #include "G4Electron.hh"                          
 55 #include "G4DynamicParticle.hh"                   
 56 #include "G4VParticleChange.hh"                   
 57 #include "G4ThreeVector.hh"                       
 58 #include "G4EnergyLossTables.hh"                  
 59 #include "G4RDVCrossSectionHandler.hh"            
 60 #include "G4RDCrossSectionHandler.hh"             
 61 #include "G4RDVEMDataSet.hh"                      
 62 #include "G4RDCompositeEMDataSet.hh"              
 63 #include "G4RDVDataSetAlgorithm.hh"               
 64 #include "G4RDLogLogInterpolation.hh"             
 65 #include "G4RDVRangeTest.hh"                      
 66 #include "G4RDRangeTest.hh"                       
 67 #include "G4RDRangeNoTest.hh"                     
 68 #include "G4MaterialCutsCouple.hh"                
 69                                                   
 70                                                   
 71 G4LowEnergyCompton::G4LowEnergyCompton(const G    
 72   : G4VDiscreteProcess(processName),              
 73     lowEnergyLimit(250*eV),                       
 74     highEnergyLimit(100*GeV),                     
 75     intrinsicLowEnergyLimit(10*eV),               
 76     intrinsicHighEnergyLimit(100*GeV)             
 77 {                                                 
 78   if (lowEnergyLimit < intrinsicLowEnergyLimit    
 79       highEnergyLimit > intrinsicHighEnergyLim    
 80     {                                             
 81       G4Exception("G4LowEnergyCompton::G4LowEn    
 82                   "OutOfRange", FatalException    
 83                   "Energy outside intrinsic pr    
 84     }                                             
 85                                                   
 86   crossSectionHandler = new G4RDCrossSectionHa    
 87                                                   
 88   G4RDVDataSetAlgorithm* scatterInterpolation     
 89   G4String scatterFile = "comp/ce-sf-";           
 90   scatterFunctionData = new G4RDCompositeEMDat    
 91   scatterFunctionData->LoadData(scatterFile);     
 92                                                   
 93   meanFreePathTable = 0;                          
 94                                                   
 95   rangeTest = new G4RDRangeNoTest;                
 96                                                   
 97   // For Doppler broadening                       
 98   shellData.SetOccupancyData();                   
 99                                                   
100    if (verboseLevel > 0)                          
101      {                                            
102        G4cout << GetProcessName() << " is crea    
103         << "Energy range: "                       
104         << lowEnergyLimit / keV << " keV - "      
105         << highEnergyLimit / GeV << " GeV"        
106         << G4endl;                                
107      }                                            
108 }                                                 
109                                                   
110 G4LowEnergyCompton::~G4LowEnergyCompton()         
111 {                                                 
112   delete meanFreePathTable;                       
113   delete crossSectionHandler;                     
114   delete scatterFunctionData;                     
115   delete rangeTest;                               
116 }                                                 
117                                                   
118 void G4LowEnergyCompton::BuildPhysicsTable(con    
119 {                                                 
120                                                   
121   crossSectionHandler->Clear();                   
122   G4String crossSectionFile = "comp/ce-cs-";      
123   crossSectionHandler->LoadData(crossSectionFi    
124                                                   
125   delete meanFreePathTable;                       
126   meanFreePathTable = crossSectionHandler->Bui    
127                                                   
128   // For Doppler broadening                       
129   G4String file = "/doppler/shell-doppler";       
130   shellData.LoadData(file);                       
131 }                                                 
132                                                   
133 G4VParticleChange* G4LowEnergyCompton::PostSte    
134                 const G4Step& aStep)              
135 {                                                 
136   // The scattered gamma energy is sampled acc    
137   // then accepted or rejected depending on th    
138   // by factor from Klein - Nishina formula.      
139   // Expression of the angular distribution as    
140   // angular and energy distribution and Scatt    
141   // D. E. Cullen "A simple model of photon tr    
142   // Phys. Res. B 101 (1995). Method of sampli    
143   // data are interpolated while in the articl    
144   // Reference to the article is from J. Stepa    
145   // and Electron Interaction Data for GEANT i    
146   // TeV (draft).                                 
147   // The random number techniques of Butcher &    
148   // (Nucl Phys 20(1960),15).                     
149                                                   
150   aParticleChange.Initialize(aTrack);             
151                                                   
152   // Dynamic particle quantities                  
153   const G4DynamicParticle* incidentPhoton = aT    
154   G4double photonEnergy0 = incidentPhoton->Get    
155                                                   
156   if (photonEnergy0 <= lowEnergyLimit)            
157     {                                             
158       aParticleChange.ProposeTrackStatus(fStop    
159       aParticleChange.ProposeEnergy(0.);          
160       aParticleChange.ProposeLocalEnergyDeposi    
161       return G4VDiscreteProcess::PostStepDoIt(    
162     }                                             
163                                                   
164   G4double e0m = photonEnergy0 / electron_mass    
165   G4ParticleMomentum photonDirection0 = incide    
166   G4double epsilon0 = 1. / (1. + 2. * e0m);       
167   G4double epsilon0Sq = epsilon0 * epsilon0;      
168   G4double alpha1 = -std::log(epsilon0);          
169   G4double alpha2 = 0.5 * (1. - epsilon0Sq);      
170   G4double wlPhoton = h_Planck*c_light/photonE    
171                                                   
172   // Select randomly one element in the curren    
173   const G4MaterialCutsCouple* couple = aTrack.    
174   G4int Z = crossSectionHandler->SelectRandomA    
175                                                   
176   // Sample the energy of the scattered photon    
177   G4double epsilon;                               
178   G4double epsilonSq;                             
179   G4double oneCosT;                               
180   G4double sinT2;                                 
181   G4double gReject;                               
182   do                                              
183     {                                             
184       if ( alpha1/(alpha1+alpha2) > G4UniformR    
185   {                                               
186     epsilon = std::exp(-alpha1 * G4UniformRand    
187     epsilonSq = epsilon * epsilon;                
188   }                                               
189       else                                        
190   {                                               
191     epsilonSq = epsilon0Sq + (1. - epsilon0Sq)    
192     epsilon = std::sqrt(epsilonSq);               
193   }                                               
194                                                   
195       oneCosT = (1. - epsilon) / ( epsilon * e    
196       sinT2 = oneCosT * (2. - oneCosT);           
197       G4double x = std::sqrt(oneCosT/2.) / (wl    
198       G4double scatteringFunction = scatterFun    
199       gReject = (1. - epsilon * sinT2 / (1. +     
200                                                   
201     }  while(gReject < G4UniformRand()*Z);        
202                                                   
203   G4double cosTheta = 1. - oneCosT;               
204   G4double sinTheta = std::sqrt (sinT2);          
205   G4double phi = twopi * G4UniformRand() ;        
206   G4double dirX = sinTheta * std::cos(phi);       
207   G4double dirY = sinTheta * std::sin(phi);       
208   G4double dirZ = cosTheta ;                      
209                                                   
210   // Doppler broadening -  Method based on:       
211   // Y. Namito, S. Ban and H. Hirayama,           
212   // "Implementation of the Doppler Broadening    
213   // NIM A 349, pp. 489-494, 1994                 
214                                                   
215   // Maximum number of sampling iterations        
216   G4int maxDopplerIterations = 1000;              
217   G4double bindingE = 0.;                         
218   G4double photonEoriginal = epsilon * photonE    
219   G4double photonE = -1.;                         
220   G4int iteration = 0;                            
221   G4double eMax = photonEnergy0;                  
222   do                                              
223     {                                             
224       iteration++;                                
225       // Select shell based on shell occupancy    
226       G4int shell = shellData.SelectRandomShel    
227       bindingE = shellData.BindingEnergy(Z,she    
228                                                   
229       eMax = photonEnergy0 - bindingE;            
230                                                   
231       // Randomly sample bound electron moment    
232       G4double pSample = profileData.RandomSel    
233       // Rescale from atomic units                
234       G4double pDoppler = pSample * fine_struc    
235       G4double pDoppler2 = pDoppler * pDoppler    
236       G4double var2 = 1. + oneCosT * e0m;         
237       G4double var3 = var2*var2 - pDoppler2;      
238       G4double var4 = var2 - pDoppler2 * cosTh    
239       G4double var = var4*var4 - var3 + pDoppl    
240       if (var > 0.)                               
241   {                                               
242     G4double varSqrt = std::sqrt(var);            
243     G4double scale = photonEnergy0 / var3;        
244           // Random select either root            
245     if (G4UniformRand() < 0.5) photonE = (var4    
246     else photonE = (var4 + varSqrt) * scale;      
247   }                                               
248       else                                        
249   {                                               
250     photonE = -1.;                                
251   }                                               
252    } while ( iteration <= maxDopplerIterations    
253        (photonE < 0. || photonE > eMax || phot    
254                                                   
255   // End of recalculation of photon energy wit    
256   // Revert to original if maximum number of i    
257   if (iteration >= maxDopplerIterations)          
258     {                                             
259       photonE = photonEoriginal;                  
260       bindingE = 0.;                              
261     }                                             
262                                                   
263   // Update G4VParticleChange for the scattere    
264                                                   
265   G4ThreeVector photonDirection1(dirX,dirY,dir    
266   photonDirection1.rotateUz(photonDirection0);    
267   aParticleChange.ProposeMomentumDirection(pho    
268                                                   
269   G4double photonEnergy1 = photonE;               
270   //G4cout << "--> PHOTONENERGY1 = " << photon    
271                                                   
272   if (photonEnergy1 > 0.)                         
273     {                                             
274       aParticleChange.ProposeEnergy(photonEner    
275     }                                             
276   else                                            
277     {                                             
278       aParticleChange.ProposeEnergy(0.) ;         
279       aParticleChange.ProposeTrackStatus(fStop    
280     }                                             
281                                                   
282   // Kinematics of the scattered electron         
283   G4double eKineticEnergy = photonEnergy0 - ph    
284   G4double eTotalEnergy = eKineticEnergy + ele    
285                                                   
286   G4double electronE = photonEnergy0 * (1. - e    
287   G4double electronP2 = electronE*electronE -     
288   G4double sinThetaE = -1.;                       
289   G4double cosThetaE = 0.;                        
290   if (electronP2 > 0.)                            
291     {                                             
292       cosThetaE = (eTotalEnergy + photonEnergy    
293       sinThetaE = -1. * std::sqrt(1. - cosThet    
294     }                                             
295                                                   
296   G4double eDirX = sinThetaE * std::cos(phi);     
297   G4double eDirY = sinThetaE * std::sin(phi);     
298   G4double eDirZ = cosThetaE;                     
299                                                   
300   // Generate the electron only if with large     
301                                                   
302   G4double safety = aStep.GetPostStepPoint()->    
303                                                   
304   if (rangeTest->Escape(G4Electron::Electron()    
305     {                                             
306       G4ThreeVector eDirection(eDirX,eDirY,eDi    
307       eDirection.rotateUz(photonDirection0);      
308                                                   
309       G4DynamicParticle* electron = new G4Dyna    
310       aParticleChange.SetNumberOfSecondaries(1    
311       aParticleChange.AddSecondary(electron);     
312       // Binding energy deposited locally         
313       aParticleChange.ProposeLocalEnergyDeposi    
314     }                                             
315   else                                            
316     {                                             
317       aParticleChange.SetNumberOfSecondaries(0    
318       aParticleChange.ProposeLocalEnergyDeposi    
319     }                                             
320                                                   
321   return G4VDiscreteProcess::PostStepDoIt( aTr    
322 }                                                 
323                                                   
324 G4bool G4LowEnergyCompton::IsApplicable(const     
325 {                                                 
326   return ( &particle == G4Gamma::Gamma() );       
327 }                                                 
328                                                   
329 G4double G4LowEnergyCompton::GetMeanFreePath(c    
330                G4double, // previousStepSize      
331                G4ForceCondition*)                 
332 {                                                 
333   const G4DynamicParticle* photon = track.GetD    
334   G4double energy = photon->GetKineticEnergy()    
335   const G4MaterialCutsCouple* couple = track.G    
336   size_t materialIndex = couple->GetIndex();      
337                                                   
338   G4double meanFreePath;                          
339   if (energy > highEnergyLimit) meanFreePath =    
340   else if (energy < lowEnergyLimit) meanFreePa    
341   else meanFreePath = meanFreePathTable->FindV    
342   return meanFreePath;                            
343 }                                                 
344