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<< 48 SetMinEnergy( 0.0*GeV ); 63 constexpr G4double emin = 2*136.9*CLHEP::MeV << 49 SetMaxEnergy( 100.*TeV ); 64 } << 65 50 66 G4ChargeExchange::G4ChargeExchange(G4ChargeExc << 51 lowEnergyRecoilLimit = 100.*keV; 67 : G4HadronicInteraction("ChargeExchange"), << 52 lowestEnergyLimit = 1.*MeV; 68 fXSection(ptr), fXSWeightFactor(1.0) << 53 69 { << 54 theProton = G4Proton::Proton(); 70 lowEnergyLimit = 1.*CLHEP::MeV; << 55 theNeutron = G4Neutron::Neutron(); 71 secID = G4PhysicsModelCatalog::GetModelID( " << 56 theAProton = G4AntiProton::AntiProton(); 72 nist = G4NistManager::Instance(); << 57 theANeutron = G4AntiNeutron::AntiNeutron(); 73 fHandler = new G4ExcitationHandler(); << 58 thePiPlus = G4PionPlus::PionPlus(); 74 if (nullptr != fXSection) { << 59 thePiMinus = G4PionMinus::PionMinus(); 75 fXSWeightFactor = 1.0/fXSection->GetCrossS << 60 thePiZero = G4PionZero::PionZero(); 76 } << 61 theKPlus = G4KaonPlus::KaonPlus(); >> 62 theKMinus = G4KaonMinus::KaonMinus(); >> 63 theK0S = G4KaonZeroShort::KaonZeroShort(); >> 64 theK0L = G4KaonZeroLong::KaonZeroLong(); >> 65 theL = G4Lambda::Lambda(); >> 66 theAntiL = G4AntiLambda::AntiLambda(); >> 67 theSPlus = G4SigmaPlus::SigmaPlus(); >> 68 theASPlus = G4AntiSigmaPlus::AntiSigmaPlus(); >> 69 theSMinus = G4SigmaMinus::SigmaMinus(); >> 70 theASMinus = G4AntiSigmaMinus::AntiSigmaMinus(); >> 71 theS0 = G4SigmaZero::SigmaZero(); >> 72 theAS0 = G4AntiSigmaZero::AntiSigmaZero(); >> 73 theXiMinus = G4XiMinus::XiMinus(); >> 74 theXi0 = G4XiZero::XiZero(); >> 75 theAXiMinus = G4AntiXiMinus::AntiXiMinus(); >> 76 theAXi0 = G4AntiXiZero::AntiXiZero(); >> 77 theOmega = G4OmegaMinus::OmegaMinus(); >> 78 theAOmega = G4AntiOmegaMinus::AntiOmegaMinus(); >> 79 theD = G4Deuteron::Deuteron(); >> 80 theT = G4Triton::Triton(); >> 81 theA = G4Alpha::Alpha(); >> 82 theA = G4He3::He3(); 77 } 83 } 78 84 79 G4ChargeExchange::~G4ChargeExchange() 85 G4ChargeExchange::~G4ChargeExchange() 80 { << 86 {} 81 delete fHandler; << 82 } << 83 87 84 G4HadFinalState* G4ChargeExchange::ApplyYourse 88 G4HadFinalState* G4ChargeExchange::ApplyYourself( 85 const G4HadProjectile& aTrack, G4Nucleus& 89 const G4HadProjectile& aTrack, G4Nucleus& targetNucleus) 86 { 90 { 87 theParticleChange.Clear(); 91 theParticleChange.Clear(); 88 auto part = aTrack.GetDefinition(); << 92 const G4HadProjectile* aParticle = &aTrack; 89 G4double ekin = aTrack.GetKineticEnergy(); << 93 G4double ekin = aParticle->GetKineticEnergy(); >> 94 >> 95 G4double aTarget = targetNucleus.GetN(); >> 96 G4double zTarget = targetNucleus.GetZ(); 90 97 91 G4int A = targetNucleus.GetA_asInt(); << 98 G4int Z = static_cast<G4int>(zTarget+0.5); 92 G4int Z = targetNucleus.GetZ_asInt(); << 99 G4int A = static_cast<G4int>(aTarget+0.5); 93 100 94 if (ekin <= lowEnergyLimit) { << 101 if(ekin <= lowestEnergyLimit || A < 3) { >> 102 theParticleChange.SetEnergyChange(ekin); >> 103 theParticleChange.SetMomentumChange(aTrack.Get4Momentum().vect().unit()); 95 return &theParticleChange; 104 return &theParticleChange; 96 } 105 } 97 theParticleChange.SetWeightChange(fXSWeightF << 98 106 99 G4int projPDG = part->GetPDGEncoding(); << 107 G4double plab = aParticle->GetTotalMomentum(); 100 108 101 // for hydrogen targets and positive project << 102 // is not possible on proton, only on deuter << 103 if (1 == Z && (211 == projPDG || 321 == proj << 104 << 105 if (verboseLevel > 1) 109 if (verboseLevel > 1) 106 G4cout << "G4ChargeExchange for " << part- << 110 G4cout << "G4ChargeExchange::DoIt: Incident particle plab=" >> 111 << plab/GeV << " GeV/c " >> 112 << " ekin(MeV) = " << ekin/MeV << " " >> 113 << aParticle->GetDefinition()->GetParticleName() << G4endl; >> 114 >> 115 // Scattered particle referred to axis of incident particle >> 116 const G4ParticleDefinition* theParticle = aParticle->GetDefinition(); >> 117 >> 118 G4int N = A - Z; >> 119 G4int projPDG = theParticle->GetPDGEncoding(); >> 120 if (verboseLevel > 1) >> 121 G4cout << "G4ChargeExchange for " << theParticle->GetParticleName() 107 << " PDGcode= " << projPDG << " on nucleu 122 << " PDGcode= " << projPDG << " on nucleus Z= " << Z 108 << " A= " << A << " N= " << A - Z << 123 << " A= " << A << " N= " << N 109 << G4endl; 124 << G4endl; 110 125 111 G4double mass1 = G4NucleiProperties::GetNucl << 126 G4ParticleDefinition * theDef = 0; 112 G4LorentzVector lv0 = aTrack.Get4Momentum(); << 113 G4double etot = mass1 + lv0.e(); << 114 << 115 // select final state << 116 const G4ParticleDefinition* theSecondary = << 117 fXSection->SampleSecondaryType(part, Z, A) << 118 G4int pdg = theSecondary->GetPDGEncoding(); << 119 << 120 // omega(782) and f2(1270) << 121 G4bool isShortLived = (pdg == 223 || pdg == << 122 << 123 // atomic number of the recoil nucleus << 124 if (projPDG == -211) { --Z; } << 125 else if (projPDG == 211) { ++Z; } << 126 else if (projPDG == -321) { --Z; } << 127 else if (projPDG == 321) { ++Z; } << 128 else if (projPDG == 130) { << 129 if (theSecondary->GetPDGCharge() > 0.0) { << 130 else { ++Z; } << 131 } else { << 132 // not ready for other projectile << 133 return &theParticleChange; << 134 } << 135 127 136 // recoil nucleus << 128 G4double m2 = G4NucleiProperties::GetNuclearMass((G4double)A, (G4double)Z); 137 const G4ParticleDefinition* theRecoil = null << 129 G4LorentzVector lv1 = aParticle->Get4Momentum(); 138 if (Z == 0 && A == 1) { theRecoil = G4Neutro << 130 G4LorentzVector lv0(0.0,0.0,0.0,m2); 139 else if (Z == 1 && A == 1) { theRecoil = G4P << 140 else if (Z == 1 && A == 2) { theRecoil = G4D << 141 else if (Z == 1 && A == 3) { theRecoil = G4T << 142 else if (Z == 2 && A == 3) { theRecoil = G4H << 143 else if (Z == 2 && A == 4) { theRecoil = G4A << 144 else if (nist->GetIsotopeAbundance(Z, A) > 0 << 145 theRecoil = G4ParticleTable::GetParticleTa << 146 ->GetIonTable()->GetIon(Z, A, 0.0); << 147 } << 148 131 149 // check if there is enough energy for the f << 132 G4LorentzVector lv = lv0 + lv1; 150 // and sample mass of produced state << 133 G4ThreeVector bst = lv.boostVector(); 151 const G4double mass0 = theSecondary->GetPDGM << 134 lv1.boost(-bst); 152 G4double mass3 = (nullptr == theRecoil) ? << 135 lv0.boost(-bst); 153 G4NucleiProperties::GetNuclearMass(A, Z) : << 136 154 G4double mass2 = mass0; << 137 // Sample final particles 155 if (isShortLived && << 138 G4bool theHyperon = false; 156 !SampleMass(mass2, theSecondary->GetPDGW << 139 G4ParticleDefinition* theRecoil = 0; 157 return &theParticleChange; << 140 G4ParticleDefinition* theSecondary = 0; >> 141 >> 142 if(theParticle == theProton) { >> 143 theSecondary = theNeutron; >> 144 Z++; >> 145 } else if(theParticle == theNeutron) { >> 146 theSecondary = theProton; >> 147 Z--; >> 148 } else if(theParticle == thePiPlus) { >> 149 theSecondary = thePiZero; >> 150 Z++; >> 151 } else if(theParticle == thePiMinus) { >> 152 theSecondary = thePiZero; >> 153 Z--; >> 154 } else if(theParticle == theKPlus) { >> 155 if(G4UniformRand()<0.5) theSecondary = theK0S; >> 156 else theSecondary = theK0L; >> 157 Z++; >> 158 } else if(theParticle == theKMinus) { >> 159 if(G4UniformRand()<0.5) theSecondary = theK0S; >> 160 else theSecondary = theK0L; >> 161 Z--; >> 162 } else if(theParticle == theK0S || theParticle == theK0L) { >> 163 if(G4UniformRand()*aTarget < zTarget) { >> 164 theSecondary = theKPlus; >> 165 Z--; >> 166 } else { >> 167 theSecondary = theKMinus; >> 168 Z++; >> 169 } >> 170 } else if(theParticle == theANeutron) { >> 171 theSecondary = theAProton; >> 172 Z++; >> 173 } else if(theParticle == theAProton) { >> 174 theSecondary = theANeutron; >> 175 Z--; >> 176 } else if(theParticle == theL) { >> 177 G4double x = G4UniformRand(); >> 178 if(G4UniformRand()*aTarget < zTarget) { >> 179 if(x < 0.2) { >> 180 theSecondary = theS0; >> 181 } else if (x < 0.4) { >> 182 theSecondary = theSPlus; >> 183 Z--; >> 184 } else if (x < 0.6) { >> 185 theSecondary = theProton; >> 186 theRecoil = theL; >> 187 theHyperon = true; >> 188 A--; >> 189 } else if (x < 0.8) { >> 190 theSecondary = theProton; >> 191 theRecoil = theS0; >> 192 theHyperon = true; >> 193 A--; >> 194 } else { >> 195 theSecondary = theNeutron; >> 196 theRecoil = theSPlus; >> 197 theHyperon = true; >> 198 A--; >> 199 } >> 200 } else { >> 201 if(x < 0.2) { >> 202 theSecondary = theS0; >> 203 } else if (x < 0.4) { >> 204 theSecondary = theSMinus; >> 205 Z++; >> 206 } else if (x < 0.6) { >> 207 theSecondary = theNeutron; >> 208 theRecoil = theL; >> 209 A--; >> 210 theHyperon = true; >> 211 } else if (x < 0.8) { >> 212 theSecondary = theNeutron; >> 213 theRecoil = theS0; >> 214 theHyperon = true; >> 215 A--; >> 216 } else { >> 217 theSecondary = theProton; >> 218 theRecoil = theSMinus; >> 219 theHyperon = true; >> 220 A--; >> 221 } >> 222 } 158 } 223 } 159 224 160 // not possible kinematically << 225 if (Z == 1 && A == 2) theDef = theD; 161 if (etot <= mass2 + mass3) { << 226 else if (Z == 1 && A == 3) theDef = theT; >> 227 else if (Z == 2 && A == 3) theDef = theHe3; >> 228 else if (Z == 2 && A == 4) theDef = theA; >> 229 else theDef = G4ParticleTable::GetParticleTable()->FindIon(Z,A,0,Z); >> 230 >> 231 G4double m11 = theSecondary->GetPDGMass(); >> 232 G4double m21 = theDef->GetPDGMass(); >> 233 if(theRecoil) m21 += theRecoil->GetPDGMass(); >> 234 else theRecoil = theDef; >> 235 >> 236 G4double etot = lv0.e() + lv1.e(); >> 237 >> 238 // kinematiacally impossible >> 239 if(etot < m11 + m21) { >> 240 theParticleChange.SetEnergyChange(ekin); >> 241 theParticleChange.SetMomentumChange(aTrack.Get4Momentum().vect().unit()); 162 return &theParticleChange; 242 return &theParticleChange; 163 } 243 } 164 244 165 // sample kinematics << 245 G4ThreeVector p1 = lv1.vect(); 166 G4LorentzVector lv1(0.0, 0.0, 0.0, mass1); << 246 G4double e1 = 0.5*etot*(1.0 - (m21*m21 - m11*m11)/(etot*etot)); 167 G4LorentzVector lv = lv0 + lv1; << 247 // G4double e2 = etot - e1; 168 G4ThreeVector bst = lv.boostVector(); << 248 G4double ptot = std::sqrt(e1*e1 - m11*m11); 169 G4double ss = lv.mag2(); << 249 170 << 250 G4double tmax = 4.0*ptot*ptot; 171 // tmax = 4*momCMS^2 << 251 G4double g2 = GeV*GeV; 172 G4double e2 = ss + mass2*mass2 - mass3*mass3 << 252 173 G4double tmax = e2*e2/ss - 4*mass2*mass2; << 253 G4double t = g2*SampleT(tmax/g2,aTarget); >> 254 >> 255 if(verboseLevel>1) >> 256 G4cout <<"## G4ChargeExchange t= " << t << " tmax= " << tmax >> 257 << " ptot= " << ptot << G4endl; 174 258 175 G4double t = SampleT(theSecondary, A, tmax); << 259 // Sampling in CM system 176 << 260 G4double phi = G4UniformRand()*twopi; 177 G4double phi = G4UniformRand()*CLHEP::twopi << 178 G4double cost = 1. - 2.0*t/tmax; 261 G4double cost = 1. - 2.0*t/tmax; >> 262 if(std::abs(cost) > 1.0) cost = 1.0; >> 263 G4double sint = std::sqrt((1.0-cost)*(1.0+cost)); 179 264 180 if (cost > 1.0) { cost = 1.0; } << 265 //if (verboseLevel > 1) 181 else if(cost < -1.0) { cost = -1.0; } << 266 // G4cout << "cos(t)=" << cost << " std::sin(t)=" << sint << G4endl; 182 267 183 G4double sint = std::sqrt((1.0-cost)*(1.0+co << 268 G4ThreeVector v1(sint*std::cos(phi),sint*std::sin(phi),cost); >> 269 v1 *= ptot; >> 270 G4LorentzVector nlv1(v1.x(),v1.y(),v1.z(),e1); >> 271 G4LorentzVector nlv0 = lv0 + lv1 - nlv1; 184 272 185 if (verboseLevel>1) { << 273 nlv0.boost(bst); 186 G4cout << " t= " << t << " tmax(GeV^2)= " << 274 nlv1.boost(bst); 187 << " cos(t)=" << cost << " sin(t)=" << si << 188 } << 189 G4double momentumCMS = 0.5*std::sqrt(tmax); << 190 G4LorentzVector lv2(momentumCMS*sint*std::co << 191 momentumCMS*sint*std::sin(phi), << 192 momentumCMS*cost, << 193 std::sqrt(momentumCMS*momentumCMS + << 194 << 195 // kinematics in the final state, may be a w << 196 lv2.boost(bst); << 197 if (lv2.e() < mass2) { << 198 lv2.setE(mass2); << 199 } << 200 lv -= lv2; << 201 if (lv.e() < mass3) { << 202 lv.setE(mass3); << 203 } << 204 275 205 // prepare secondary particles << 206 theParticleChange.SetStatusChange(stopAndKil 276 theParticleChange.SetStatusChange(stopAndKill); 207 theParticleChange.SetEnergyChange(0.0); 277 theParticleChange.SetEnergyChange(0.0); >> 278 G4DynamicParticle * aSec = new G4DynamicParticle(theSecondary, nlv1); >> 279 theParticleChange.AddSecondary(aSec); 208 280 209 if (!isShortLived) { << 281 G4double erec = nlv0.e() - m21; 210 auto aSec = new G4DynamicParticle(theSecon << 282 211 theParticleChange.AddSecondary(aSec, secID << 283 //G4cout << "erec= " <<erec << " Esec= " << aSec->GetKineticEnergy() << G4endl; 212 } else { << 213 auto channel = theSecondary->GetDecayTable << 214 auto products = channel->DecayIt(mass2); << 215 G4ThreeVector bst1 = lv2.boostVector(); << 216 G4int N = products->entries(); << 217 for (G4int i=0; i<N; ++i) { << 218 auto p = (*products)[i]; << 219 auto lvp = p->Get4Momentum(); << 220 lvp.boost(bst1); << 221 p->Set4Momentum(lvp); << 222 theParticleChange.AddSecondary(p, secID) << 223 } << 224 delete products; << 225 } << 226 284 227 // recoil is a stable isotope << 285 if(theHyperon) { 228 if (nullptr != theRecoil) { << 286 theParticleChange.SetLocalEnergyDeposit(erec); 229 auto aRec = new G4DynamicParticle(theRecoi << 287 aSec = new G4DynamicParticle(); 230 theParticleChange.AddSecondary(aRec, secID << 288 aSec->SetDefinition(theRecoil); >> 289 aSec->SetKineticEnergy(0.0); >> 290 } else if(erec > lowEnergyRecoilLimit) { >> 291 aSec = new G4DynamicParticle(theRecoil, nlv0); >> 292 theParticleChange.AddSecondary(aSec); 231 } else { 293 } else { 232 // recoil is an unstable fragment << 294 if(erec < 0.0) erec = 0.0; 233 G4Fragment frag(A, Z, lv); << 295 theParticleChange.SetLocalEnergyDeposit(erec); 234 auto products = fHandler->BreakItUp(frag); << 235 for (auto & prod : *products) { << 236 auto dp = new G4DynamicParticle(prod->Ge << 237 theParticleChange.AddSecondary(dp, secID << 238 delete prod; << 239 } << 240 delete products; << 241 } 296 } 242 return &theParticleChange; 297 return &theParticleChange; 243 } 298 } 244 299 245 G4double G4ChargeExchange::SampleT(const G4Par << 300 G4double G4ChargeExchange::SampleT(G4double tmax, G4double A) 246 const G4int << 247 { 301 { 248 G4double aa, bb, cc, dd; 302 G4double aa, bb, cc, dd; 249 G4Pow* g4pow = G4Pow::GetInstance(); << 250 if (A <= 62.) { 303 if (A <= 62.) { 251 aa = g4pow->powZ(A, 1.63); << 304 aa = std::pow(A, 1.63); 252 bb = 14.5*g4pow->powZ(A, 0.66); << 305 bb = 14.5*std::pow(A, 0.66); 253 cc = 1.4*g4pow->powZ(A, 0.33); << 306 cc = 1.4*std::pow(A, 0.33); 254 dd = 10.; 307 dd = 10.; 255 } else { 308 } else { 256 aa = g4pow->powZ(A, 1.33); << 309 aa = std::pow(A, 1.33); 257 bb = 60.*g4pow->powZ(A, 0.33); << 310 bb = 60.*std::pow(A, 0.33); 258 cc = 0.4*g4pow->powZ(A, 0.40); << 311 cc = 0.4*std::pow(A, 0.40); 259 dd = 10.; 312 dd = 10.; 260 } 313 } 261 G4double x1 = (1.0 - G4Exp(-tmax*bb))*aa/bb; << 314 G4double x1 = (1.0 - std::exp(-tmax*bb))*aa/bb; 262 G4double x2 = (1.0 - G4Exp(-tmax*dd))*cc/dd; << 315 G4double x2 = (1.0 - std::exp(-tmax*dd))*cc/dd; 263 316 264 G4double t; 317 G4double t; 265 G4double y = bb; 318 G4double y = bb; 266 if(G4UniformRand()*(x1 + x2) < x2) y = dd; 319 if(G4UniformRand()*(x1 + x2) < x2) y = dd; 267 320 268 for (G4int i=0; i<maxN; ++i) { << 321 do {t = -std::log(G4UniformRand())/y;} while (t > tmax); 269 t = -G4Log(G4UniformRand())/y; << 270 if (t <= tmax) { return t; } << 271 } << 272 return 0.0; << 273 } << 274 322 275 G4bool G4ChargeExchange::SampleMass(G4double& << 323 return t; 276 { << 277 // +- 4 width but above 2 pion mass << 278 const G4double e1 = std::max(M - 4*G, emin); << 279 const G4double e2 = std::min(M + 4*G, elim) << 280 if (e2 <= 0.0) { return false; } << 281 const G4double M2 = M*M; << 282 const G4double MG2 = M2*G*G; << 283 << 284 // sampling Breit-Wigner function << 285 for (G4int i=0; i<maxN; ++i) { << 286 G4double e = e1 + e2*G4UniformRand(); << 287 G4double x = e*e - M2; << 288 G4double y = MG2/(x*x + MG2); << 289 if (y >= G4UniformRand()) { << 290 M = e; << 291 return true; << 292 } << 293 } << 294 return false; << 295 } 324 } >> 325 296 326