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Geant4/processes/electromagnetic/highenergy/src/G4AnnihiToMuPair.cc

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Differences between /processes/electromagnetic/highenergy/src/G4AnnihiToMuPair.cc (Version 11.3.0) and /processes/electromagnetic/highenergy/src/G4AnnihiToMuPair.cc (Version 10.0.p2)


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                                                   >>  27 // $Id: G4AnnihiToMuPair.cc 66241 2012-12-13 18:34:42Z gunter $
 27 //                                                 28 //
 28 //         ------------ G4AnnihiToMuPair physi     29 //         ------------ G4AnnihiToMuPair physics process ------
 29 //         by H.Burkhardt, S. Kelner and R. Ko     30 //         by H.Burkhardt, S. Kelner and R. Kokoulin, November 2002
 30 // -------------------------------------------     31 // -----------------------------------------------------------------------------
 31 //                                                 32 //
 32 //....oooOO0OOooo........oooOO0OOooo........oo     33 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......//
 33 //                                                 34 //
 34 // 27.01.03 : first implementation (hbu)           35 // 27.01.03 : first implementation (hbu)
 35 // 04.02.03 : cosmetic simplifications (mma)       36 // 04.02.03 : cosmetic simplifications (mma)
 36 // 25.10.04 : migrade to new interfaces of Par     37 // 25.10.04 : migrade to new interfaces of ParticleChange (vi)
 37 // 28.02.18 : cross section now including SSS  << 
 38 //                                                 38 //
 39 //....oooOO0OOooo........oooOO0OOooo........oo     39 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 40                                                    40 
 41 #include "G4AnnihiToMuPair.hh"                     41 #include "G4AnnihiToMuPair.hh"
 42                                                    42 
 43 #include "G4Exp.hh"                            <<  43 #include "G4ios.hh"
 44 #include "G4LossTableManager.hh"               <<  44 #include "Randomize.hh"
 45 #include "G4Material.hh"                       << 
 46 #include "G4MuonMinus.hh"                      << 
 47 #include "G4MuonPlus.hh"                       << 
 48 #include "G4PhysicalConstants.hh"                  45 #include "G4PhysicalConstants.hh"
                                                   >>  46 #include "G4SystemOfUnits.hh"
                                                   >>  47 
 49 #include "G4Positron.hh"                           48 #include "G4Positron.hh"
                                                   >>  49 #include "G4MuonPlus.hh"
                                                   >>  50 #include "G4MuonMinus.hh"
                                                   >>  51 #include "G4Material.hh"
 50 #include "G4Step.hh"                               52 #include "G4Step.hh"
 51 #include "G4SystemOfUnits.hh"                  << 
 52 #include "G4TauMinus.hh"                       << 
 53 #include "G4TauPlus.hh"                        << 
 54 #include "G4ios.hh"                            << 
 55 #include "Randomize.hh"                        << 
 56                                                    53 
 57 //....oooOO0OOooo........oooOO0OOooo........oo     54 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 58                                                    55 
                                                   >>  56 using namespace std;
                                                   >>  57 
 59 G4AnnihiToMuPair::G4AnnihiToMuPair(const G4Str     58 G4AnnihiToMuPair::G4AnnihiToMuPair(const G4String& processName,
 60     G4ProcessType type):G4VDiscreteProcess (pr     59     G4ProcessType type):G4VDiscreteProcess (processName, type)
 61 {                                                  60 {
 62   //e+ Energy threshold                        <<  61  //e+ Energy threshold
 63   if(processName == "AnnihiToTauPair") {       <<  62  const G4double Mu_massc2 = G4MuonPlus::MuonPlus()->GetPDGMass();
 64     SetProcessSubType(fAnnihilationToTauTau);  <<  63  LowestEnergyLimit  = 2*Mu_massc2*Mu_massc2/electron_mass_c2 - electron_mass_c2;
 65     part1 = G4TauPlus::TauPlus();              <<  64  
 66     part2 = G4TauMinus::TauMinus();            <<  65  //modele ok up to 1000 TeV due to neglected Z-interference
 67     fInfo = "e+e->tau+tau-";                   <<  66  HighestEnergyLimit = 1000*TeV;
 68   } else {                                     <<  67  
 69     SetProcessSubType(fAnnihilationToMuMu);    <<  68  CurrentSigma = 0.0;
 70     part1 = G4MuonPlus::MuonPlus();            <<  69  CrossSecFactor = 1.;
 71     part2 = G4MuonMinus::MuonMinus();          <<  70  SetProcessSubType(6);
 72   }                                            << 
 73   fMass = part1->GetPDGMass();                 << 
 74   fLowEnergyLimit = 2. * fMass * fMass / CLHEP << 
 75                                                    71 
 76   // model is ok up to 1000 TeV due to neglect << 
 77   fHighEnergyLimit = 1000. * TeV;              << 
 78                                                << 
 79   fCurrentSigma = 0.0;                         << 
 80   fCrossSecFactor = 1.;                        << 
 81   fManager = G4LossTableManager::Instance();   << 
 82   fManager->Register(this);                    << 
 83 }                                                  72 }
 84                                                    73 
 85 //....oooOO0OOooo........oooOO0OOooo........oo     74 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 86                                                    75 
 87 G4AnnihiToMuPair::~G4AnnihiToMuPair() // (empt     76 G4AnnihiToMuPair::~G4AnnihiToMuPair() // (empty) destructor
 88 {                                              <<  77 { }
 89   fManager->DeRegister(this);                  << 
 90 }                                              << 
 91                                                    78 
 92 //....oooOO0OOooo........oooOO0OOooo........oo     79 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 93                                                    80 
 94 G4bool G4AnnihiToMuPair::IsApplicable(const G4     81 G4bool G4AnnihiToMuPair::IsApplicable(const G4ParticleDefinition& particle)
 95 {                                                  82 {
 96   return ( &particle == G4Positron::Positron()     83   return ( &particle == G4Positron::Positron() );
 97 }                                                  84 }
 98                                                    85 
 99 //....oooOO0OOooo........oooOO0OOooo........oo     86 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
100                                                    87 
101 void G4AnnihiToMuPair::BuildPhysicsTable(const     88 void G4AnnihiToMuPair::BuildPhysicsTable(const G4ParticleDefinition&)
                                                   >>  89 // Build cross section and mean free path tables
                                                   >>  90 //here no tables, just calling PrintInfoDefinition
102 {                                                  91 {
                                                   >>  92   CurrentSigma = 0.0;
103   PrintInfoDefinition();                           93   PrintInfoDefinition();
104 }                                                  94 }
105                                                    95 
106 //....oooOO0OOooo........oooOO0OOooo........oo     96 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
107                                                    97 
108 void G4AnnihiToMuPair::SetCrossSecFactor(G4dou     98 void G4AnnihiToMuPair::SetCrossSecFactor(G4double fac)
109 // Set the factor to artificially increase the     99 // Set the factor to artificially increase the cross section
110 {                                                 100 { 
111   fCrossSecFactor = fac;                       << 101   CrossSecFactor = fac;
112   //G4cout << "The cross section for AnnihiToM << 102   G4cout << "The cross section for AnnihiToMuPair is artificially "
113   //       << "increased by the CrossSecFactor << 103          << "increased by the CrossSecFactor=" << CrossSecFactor << G4endl;
114 }                                                 104 }
115                                                   105 
116 //....oooOO0OOooo........oooOO0OOooo........oo    106 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
117                                                   107 
118 G4double G4AnnihiToMuPair::ComputeCrossSection << 108 G4double G4AnnihiToMuPair::ComputeCrossSectionPerAtom(G4double Epos, G4double Z)
119 // Calculates the microscopic cross section in    109 // Calculates the microscopic cross section in GEANT4 internal units.
120 // It gives a good description from threshold     110 // It gives a good description from threshold to 1000 GeV
121 {                                                 111 {
122   G4double rmuon = CLHEP::elm_coupling/fMass;  << 112   static const G4double Mmuon = G4MuonPlus::MuonPlus()->GetPDGMass();
123   G4double sig0 = CLHEP::pi*rmuon*rmuon/3.;    << 113   static const G4double Rmuon = elm_coupling/Mmuon; //classical particle radius
124   const G4double pial = CLHEP::pi*CLHEP::fine_ << 114   static const G4double Sig0  = pi*Rmuon*Rmuon/3.;  //constant in crossSection
125                                                   115 
126   if (e <= fLowEnergyLimit) return 0.0;        << 116   G4double CrossSection = 0.;
                                                   >> 117   if (Epos < LowestEnergyLimit) return CrossSection;
127                                                   118    
128   const G4double xi = fLowEnergyLimit/e;       << 119   G4double xi = LowestEnergyLimit/Epos;
129   const G4double piaxi = pial * std::sqrt(xi); << 120   G4double SigmaEl = Sig0*xi*(1.+xi/2.)*sqrt(1.-xi); // per electron
130   G4double sigma = sig0 * xi * (1. + xi*0.5);  << 121   CrossSection = SigmaEl*Z;         // number of electrons per atom
131   //G4cout << "### xi= " << xi << " piaxi=" << << 122   return CrossSection;
132                                                << 
133   // argument of the exponent below 0.1 or abo << 
134   // Sigma per electron * number of electrons  << 
135   if(xi <= 1.0 - 100*piaxi*piaxi) {            << 
136     sigma *= std::sqrt(1.0 - xi);              << 
137   }                                            << 
138   else if (xi >= 1.0 - 0.01 * piaxi * piaxi) { << 
139     sigma *= piaxi;                            << 
140   }                                            << 
141   else {                                       << 
142     sigma *= piaxi / (1. - G4Exp(-piaxi / std: << 
143   }                                            << 
144   // G4cout << "### sigma= " << sigma << G4end << 
145   return sigma;                                << 
146 }                                                 123 }
147                                                   124 
148 //....oooOO0OOooo........oooOO0OOooo........oo    125 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
149                                                   126 
150 G4double G4AnnihiToMuPair::ComputeCrossSection << 127 G4double G4AnnihiToMuPair::CrossSectionPerVolume(G4double PositronEnergy, 
151                                                << 128              const G4Material* aMaterial)
152 {                                                 129 {
153   return ComputeCrossSectionPerElectron(energy << 130   const G4ElementVector* theElementVector = aMaterial->GetElementVector();
154 }                                              << 131   const G4double* NbOfAtomsPerVolume = aMaterial->GetVecNbOfAtomsPerVolume();
155                                                   132 
156 //....oooOO0OOooo........oooOO0OOooo........oo << 133   G4double SIGMA = 0.0;
157                                                   134 
158 G4double G4AnnihiToMuPair::CrossSectionPerVolu << 135   for ( size_t i=0 ; i < aMaterial->GetNumberOfElements() ; ++i )
159              const G4Material* aMaterial)      << 136   {
160 {                                              << 137     G4double AtomicZ = (*theElementVector)[i]->GetZ();
161   return ComputeCrossSectionPerElectron(energy << 138     SIGMA += NbOfAtomsPerVolume[i] *
                                                   >> 139       ComputeCrossSectionPerAtom(PositronEnergy,AtomicZ);
                                                   >> 140   }
                                                   >> 141   return SIGMA;
162 }                                                 142 }
163                                                   143 
164 //....oooOO0OOooo........oooOO0OOooo........oo    144 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
165                                                   145 
166 G4double G4AnnihiToMuPair::GetMeanFreePath(con    146 G4double G4AnnihiToMuPair::GetMeanFreePath(const G4Track& aTrack,
167                                            G4d    147                                            G4double, G4ForceCondition*)
                                                   >> 148 
168 // returns the positron mean free path in GEAN    149 // returns the positron mean free path in GEANT4 internal units
                                                   >> 150 
169 {                                                 151 {
170   const G4DynamicParticle* aDynamicPositron =     152   const G4DynamicParticle* aDynamicPositron = aTrack.GetDynamicParticle();
171   G4double energy = aDynamicPositron->GetTotal << 153   G4double PositronEnergy = aDynamicPositron->GetKineticEnergy()
172   const G4Material* aMaterial = aTrack.GetMate << 154                                               +electron_mass_c2;
173                                                << 155   G4Material* aMaterial = aTrack.GetMaterial();
174   // cross section before step                 << 156   CurrentSigma = CrossSectionPerVolume(PositronEnergy, aMaterial);
175   fCurrentSigma = CrossSectionPerVolume(energy << 
176                                                   157 
177   // increase the CrossSection by CrossSecFact    158   // increase the CrossSection by CrossSecFactor (default 1)
178   return (fCurrentSigma > 0.0) ? 1.0/(fCurrent << 159   G4double mfp = DBL_MAX;
                                                   >> 160   if(CurrentSigma > DBL_MIN) mfp = 1.0/(CurrentSigma*CrossSecFactor);
                                                   >> 161 
                                                   >> 162   return mfp;
179 }                                                 163 }
180                                                   164 
181 //....oooOO0OOooo........oooOO0OOooo........oo    165 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
182                                                   166 
183 G4VParticleChange* G4AnnihiToMuPair::PostStepD    167 G4VParticleChange* G4AnnihiToMuPair::PostStepDoIt(const G4Track& aTrack,
184                                                   168                                                   const G4Step&  aStep)
185 //                                                169 //
186 // generation of e+e- -> mu+mu-                   170 // generation of e+e- -> mu+mu-
187 //                                                171 //
188 {                                                 172 {
                                                   >> 173 
189   aParticleChange.Initialize(aTrack);             174   aParticleChange.Initialize(aTrack);
                                                   >> 175   static const G4double Mele=electron_mass_c2;
                                                   >> 176   static const G4double Mmuon=G4MuonPlus::MuonPlus()->GetPDGMass();
190                                                   177 
191   // current Positron energy and direction, re    178   // current Positron energy and direction, return if energy too low
192   const G4DynamicParticle *aDynamicPositron =     179   const G4DynamicParticle *aDynamicPositron = aTrack.GetDynamicParticle();
193   const G4double Mele = CLHEP::electron_mass_c << 180   G4double Epos = aDynamicPositron->GetKineticEnergy() + Mele; 
194   G4double Epos = aDynamicPositron->GetTotalEn << 
195   G4double xs = CrossSectionPerVolume(Epos, aT << 
196                                                   181 
197   // test of cross section                        182   // test of cross section
198   if(xs > 0.0 && fCurrentSigma*G4UniformRand() << 183   if(CurrentSigma*G4UniformRand() > 
199     return G4VDiscreteProcess::PostStepDoIt(aT << 184      CrossSectionPerVolume(Epos, aTrack.GetMaterial())) 
                                                   >> 185     {
                                                   >> 186       return G4VDiscreteProcess::PostStepDoIt(aTrack,aStep);
                                                   >> 187     }
                                                   >> 188 
                                                   >> 189   if (Epos < LowestEnergyLimit) {
                                                   >> 190      return G4VDiscreteProcess::PostStepDoIt(aTrack,aStep);
200   }                                               191   }
201                                                   192 
202   const G4ThreeVector PosiDirection = aDynamic << 193   G4ParticleMomentum PositronDirection = 
203   G4double xi = fLowEnergyLimit/Epos; // xi is << 194                                        aDynamicPositron->GetMomentumDirection();
204                                       // goes  << 195   G4double xi = LowestEnergyLimit/Epos; // xi is always less than 1,
                                                   >> 196                                         // goes to 0 at high Epos
205                                                   197 
206   // generate cost; probability function 1+cos << 198   // generate cost
207   //                                              199   //
208   G4double cost;                                  200   G4double cost;
209   do { cost = 2.*G4UniformRand()-1.; }         << 201   do cost = 2.*G4UniformRand()-1.;
210   // Loop checking, 07-Aug-2015, Vladimir Ivan << 
211   while (2.*G4UniformRand() > 1.+xi+cost*cost*    202   while (2.*G4UniformRand() > 1.+xi+cost*cost*(1.-xi) ); 
212   G4double sint = std::sqrt(1.-cost*cost);     << 203                                                        //1+cost**2 at high Epos
                                                   >> 204   G4double sint = sqrt(1.-cost*cost);
213                                                   205 
214   // generate phi                                 206   // generate phi
215   //                                              207   //
216   G4double phi = 2.*CLHEP::pi*G4UniformRand(); << 208   G4double phi=2.*pi*G4UniformRand();
217                                                   209 
218   G4double Ecm   = std::sqrt(0.5*Mele*(Epos+Me << 210   G4double Ecm   = sqrt(0.5*Mele*(Epos+Mele));
219   G4double Pcm   = std::sqrt(Ecm*Ecm - fMass*f << 211   G4double Pcm   = sqrt(Ecm*Ecm-Mmuon*Mmuon);
220   G4double beta  = std::sqrt((Epos-Mele)/(Epos << 212   G4double beta  = sqrt((Epos-Mele)/(Epos+Mele));
221   G4double gamma = Ecm/Mele;                   << 213   G4double gamma = Ecm/Mele;                    // =sqrt((Epos+Mele)/(2.*Mele));
222   G4double Pt    = Pcm*sint;                      214   G4double Pt    = Pcm*sint;
223                                                   215   
224   // energy and momentum of the muons in the L    216   // energy and momentum of the muons in the Lab
225   //                                              217   //
226   G4double EmuPlus   = gamma*(Ecm + cost*beta* << 218   G4double EmuPlus   = gamma*(     Ecm+cost*beta*Pcm);
227   G4double EmuMinus  = gamma*(Ecm - cost*beta* << 219   G4double EmuMinus  = gamma*(     Ecm-cost*beta*Pcm);
228   G4double PmuPlusZ  = gamma*(beta*Ecm + cost* << 220   G4double PmuPlusZ  = gamma*(beta*Ecm+cost*     Pcm);
229   G4double PmuMinusZ = gamma*(beta*Ecm - cost* << 221   G4double PmuMinusZ = gamma*(beta*Ecm-cost*     Pcm);
230   G4double PmuPlusX  = Pt*std::cos(phi);       << 222   G4double PmuPlusX  = Pt*cos(phi);
231   G4double PmuPlusY  = Pt*std::sin(phi);       << 223   G4double PmuPlusY  = Pt*sin(phi);
232   G4double PmuMinusX =-PmuPlusX;               << 224   G4double PmuMinusX =-Pt*cos(phi);
233   G4double PmuMinusY =-PmuPlusY;               << 225   G4double PmuMinusY =-Pt*sin(phi);
234   // absolute momenta                             226   // absolute momenta
235   G4double PmuPlus  = std::sqrt(Pt*Pt+PmuPlusZ << 227   G4double PmuPlus  = sqrt(Pt*Pt+PmuPlusZ *PmuPlusZ );
236   G4double PmuMinus = std::sqrt(Pt*Pt+PmuMinus << 228   G4double PmuMinus = sqrt(Pt*Pt+PmuMinusZ*PmuMinusZ);
237                                                   229 
238   // mu+ mu- directions for Positron in z-dire    230   // mu+ mu- directions for Positron in z-direction
239   //                                              231   //
240   G4ThreeVector MuPlusDirection(PmuPlusX / Pmu << 232   G4ThreeVector
241   G4ThreeVector MuMinusDirection(PmuMinusX / P << 233     MuPlusDirection ( PmuPlusX/PmuPlus, PmuPlusY/PmuPlus,  PmuPlusZ/PmuPlus  );
                                                   >> 234   G4ThreeVector
                                                   >> 235     MuMinusDirection(PmuMinusX/PmuMinus,PmuMinusY/PmuMinus,PmuMinusZ/PmuMinus);
242                                                   236 
243   // rotate to actual Positron direction          237   // rotate to actual Positron direction
244   //                                              238   //
245   MuPlusDirection.rotateUz(PosiDirection);     << 239   MuPlusDirection.rotateUz(PositronDirection);
246   MuMinusDirection.rotateUz(PosiDirection);    << 240   MuMinusDirection.rotateUz(PositronDirection);
247                                                   241 
248   aParticleChange.SetNumberOfSecondaries(2);      242   aParticleChange.SetNumberOfSecondaries(2);
249                                                << 
250   // create G4DynamicParticle object for the p    243   // create G4DynamicParticle object for the particle1
251   auto aParticle1 = new G4DynamicParticle(part << 244   G4DynamicParticle* aParticle1= new G4DynamicParticle(
                                                   >> 245                          G4MuonPlus::MuonPlus(),MuPlusDirection,EmuPlus-Mmuon);
252   aParticleChange.AddSecondary(aParticle1);       246   aParticleChange.AddSecondary(aParticle1);
253   // create G4DynamicParticle object for the p    247   // create G4DynamicParticle object for the particle2
254   auto aParticle2 = new G4DynamicParticle(part << 248   G4DynamicParticle* aParticle2= new G4DynamicParticle(
                                                   >> 249                      G4MuonMinus::MuonMinus(),MuMinusDirection,EmuMinus-Mmuon);
255   aParticleChange.AddSecondary(aParticle2);       250   aParticleChange.AddSecondary(aParticle2);
256                                                   251 
257   // Kill the incident positron                   252   // Kill the incident positron 
258   //                                              253   //
259   aParticleChange.ProposeEnergy(0.);              254   aParticleChange.ProposeEnergy(0.); 
260   aParticleChange.ProposeTrackStatus(fStopAndK    255   aParticleChange.ProposeTrackStatus(fStopAndKill);
261                                                   256 
262   return &aParticleChange;                        257   return &aParticleChange;
263 }                                                 258 }
264                                                   259 
265 //....oooOO0OOooo........oooOO0OOooo........oo    260 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
266                                                   261 
267 void G4AnnihiToMuPair::PrintInfoDefinition()      262 void G4AnnihiToMuPair::PrintInfoDefinition()
268 {                                                 263 {
269   G4String comments = fInfo + " annihilation,  << 264   G4String comments ="e+e->mu+mu- annihilation, atomic e- at rest, SubType=.";
270   G4cout << G4endl << GetProcessName() << ":   << 265   G4cout << G4endl << GetProcessName() << ":  " << comments 
271   G4cout << "        threshold at " << fLowEne << 266    << GetProcessSubType() << G4endl;
272          << " good description up to " << fHig << 267   G4cout << "        threshold at " << LowestEnergyLimit/GeV << " GeV"
273          << G4endl;                            << 268          << " good description up to "
                                                   >> 269          << HighestEnergyLimit/TeV << " TeV for all Z." << G4endl;
274 }                                                 270 }
275                                                   271 
276 //....oooOO0OOooo........oooOO0OOooo........oo    272 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
277                                                   273