Geant4 Cross Reference |
1 // 1 // 2 // ******************************************* 2 // ******************************************************************** 3 // * License and Disclaimer 3 // * License and Disclaimer * 4 // * 4 // * * 5 // * The Geant4 software is copyright of th 5 // * The Geant4 software is copyright of the Copyright Holders of * 6 // * the Geant4 Collaboration. It is provided 6 // * the Geant4 Collaboration. It is provided under the terms and * 7 // * conditions of the Geant4 Software License 7 // * conditions of the Geant4 Software License, included in the file * 8 // * LICENSE and available at http://cern.ch/ 8 // * LICENSE and available at http://cern.ch/geant4/license . These * 9 // * include a list of copyright holders. 9 // * include a list of copyright holders. * 10 // * 10 // * * 11 // * Neither the authors of this software syst 11 // * Neither the authors of this software system, nor their employing * 12 // * institutes,nor the agencies providing fin 12 // * institutes,nor the agencies providing financial support for this * 13 // * work make any representation or warran 13 // * work make any representation or warranty, express or implied, * 14 // * regarding this software system or assum 14 // * regarding this software system or assume any liability for its * 15 // * use. Please see the license in the file 15 // * use. Please see the license in the file LICENSE and URL above * 16 // * for the full disclaimer and the limitatio 16 // * for the full disclaimer and the limitation of liability. * 17 // * 17 // * * 18 // * This code implementation is the result 18 // * This code implementation is the result of the scientific and * 19 // * technical work of the GEANT4 collaboratio 19 // * technical work of the GEANT4 collaboration. * 20 // * By using, copying, modifying or distri 20 // * By using, copying, modifying or distributing the software (or * 21 // * any work based on the software) you ag 21 // * any work based on the software) you agree to acknowledge its * 22 // * use in resulting scientific publicati 22 // * use in resulting scientific publications, and indicate your * 23 // * acceptance of all terms of the Geant4 Sof 23 // * acceptance of all terms of the Geant4 Software license. * 24 // ******************************************* 24 // ******************************************************************** 25 // 25 // 26 // 26 // 27 // 27 // 28 // 28 // 29 // ------------------------------------------- 29 // -------------------------------------------------------------- 30 // GEANT 4 class implementation file 30 // GEANT 4 class implementation file 31 // 31 // 32 // History: first implementation, based o 32 // History: first implementation, based on object model of 33 // 2nd December 1995, G.Cosmo 33 // 2nd December 1995, G.Cosmo 34 // 7 July 1996 H.Kurashige 34 // 7 July 1996 H.Kurashige 35 // ------------------------------------------- 35 // ------------------------------------------------------------ 36 // remove BuildPhysicsTable() 28 Nov. 1997 36 // remove BuildPhysicsTable() 28 Nov. 1997 H.Kurashige 37 // change DBL_EPSIRON to DBL_MIN 14 Dec. 19 37 // change DBL_EPSIRON to DBL_MIN 14 Dec. 1997 H.Kurashige 38 // modified for new ParticleChange 12 Mar. 1 38 // modified for new ParticleChange 12 Mar. 1998 H.Kurashige 39 // modified for "GoodForTrackingFlag" 19 Jun 39 // modified for "GoodForTrackingFlag" 19 June 1998 H.Kurashige 40 // rename thePhysicsTable to aPhyscisTable 2 40 // rename thePhysicsTable to aPhyscisTable 2 Aug. 1998 H.Kurashige 41 // modified IsApplicable in order to protect 41 // modified IsApplicable in order to protect the decay from registered 42 // to resonances 12 Dec. 1998 H.Kurashi 42 // to resonances 12 Dec. 1998 H.Kurashige 43 // remove G4ParticleMomentum 6 Feb. 99 H.Ku 43 // remove G4ParticleMomentum 6 Feb. 99 H.Kurashige 44 // modified IsApplicable to activate G4Deca 44 // modified IsApplicable to activate G4Decay for resonances 1 Mar. 00 H.Kurashige 45 // Add External Decayer 23 Feb. 2001 45 // Add External Decayer 23 Feb. 2001 H.Kurashige 46 // change LowestBinValue,HighestBinValue and 46 // change LowestBinValue,HighestBinValue and TotBin(200) 9 Feb. 2002 47 // 47 // 48 48 49 #include "G4Decay.hh" 49 #include "G4Decay.hh" 50 50 51 #include "G4PhysicalConstants.hh" 51 #include "G4PhysicalConstants.hh" 52 #include "G4SystemOfUnits.hh" 52 #include "G4SystemOfUnits.hh" 53 #include "G4DynamicParticle.hh" 53 #include "G4DynamicParticle.hh" 54 #include "G4DecayProducts.hh" 54 #include "G4DecayProducts.hh" 55 #include "G4DecayTable.hh" 55 #include "G4DecayTable.hh" 56 #include "G4VDecayChannel.hh" 56 #include "G4VDecayChannel.hh" 57 #include "G4PhysicsLogVector.hh" 57 #include "G4PhysicsLogVector.hh" 58 #include "G4ParticleChangeForDecay.hh" 58 #include "G4ParticleChangeForDecay.hh" 59 #include "G4VExtDecayer.hh" 59 #include "G4VExtDecayer.hh" 60 60 61 // constructor 61 // constructor 62 G4Decay::G4Decay(const G4String& processName) 62 G4Decay::G4Decay(const G4String& processName) 63 :G4VRestDiscret 63 :G4VRestDiscreteProcess(processName, fDecay), 64 verboseLevel(1), 64 verboseLevel(1), 65 HighestValue(2 65 HighestValue(20.0), 66 fRemainderLifeTime(-1.0), 66 fRemainderLifeTime(-1.0), 67 pExtDecayer(nu 67 pExtDecayer(nullptr) 68 { 68 { 69 // set Process Sub Type 69 // set Process Sub Type 70 SetProcessSubType(static_cast<int>(DECAY)); 70 SetProcessSubType(static_cast<int>(DECAY)); 71 71 72 #ifdef G4VERBOSE 72 #ifdef G4VERBOSE 73 if (GetVerboseLevel()>1) { 73 if (GetVerboseLevel()>1) { 74 G4cout << "G4Decay constructor " << " Na 74 G4cout << "G4Decay constructor " << " Name:" << processName << G4endl; 75 } 75 } 76 #endif 76 #endif 77 77 78 pParticleChange = &fParticleChangeForDecay; 78 pParticleChange = &fParticleChangeForDecay; 79 } 79 } 80 80 81 G4Decay::~G4Decay() 81 G4Decay::~G4Decay() 82 { 82 { 83 if (pExtDecayer != nullptr) { 83 if (pExtDecayer != nullptr) { 84 delete pExtDecayer; 84 delete pExtDecayer; 85 } 85 } 86 } 86 } 87 87 88 G4bool G4Decay::IsApplicable(const G4ParticleD 88 G4bool G4Decay::IsApplicable(const G4ParticleDefinition& aParticleType) 89 { 89 { 90 // check if the particle is stable? 90 // check if the particle is stable? 91 if (aParticleType.GetPDGLifeTime() <0.0) { 91 if (aParticleType.GetPDGLifeTime() <0.0) { 92 return false; 92 return false; 93 } else if (aParticleType.GetPDGMass() <= 0. 93 } else if (aParticleType.GetPDGMass() <= 0.0*MeV) { 94 return false; 94 return false; 95 } else { 95 } else { 96 return true; 96 return true; 97 } 97 } 98 } 98 } 99 99 100 G4double G4Decay::GetMeanLifeTime(const G4Trac 100 G4double G4Decay::GetMeanLifeTime(const G4Track& aTrack , 101 G4ForceCondi 101 G4ForceCondition*) 102 { 102 { 103 // returns the mean free path in GEANT4 int 103 // returns the mean free path in GEANT4 internal units 104 G4double meanlife; 104 G4double meanlife; 105 105 106 // get particle 106 // get particle 107 const G4DynamicParticle* aParticle = aTrack 107 const G4DynamicParticle* aParticle = aTrack.GetDynamicParticle(); 108 const G4ParticleDefinition* aParticleDef = 108 const G4ParticleDefinition* aParticleDef = aParticle->GetDefinition(); 109 G4double aLife = aParticleDef->GetPDGLifeTi 109 G4double aLife = aParticleDef->GetPDGLifeTime(); 110 110 111 // check if the particle is stable? 111 // check if the particle is stable? 112 if (aParticleDef->GetPDGStable()) { 112 if (aParticleDef->GetPDGStable()) { 113 //1000000 times the life time of the unive 113 //1000000 times the life time of the universe 114 meanlife = 1e24 * s; 114 meanlife = 1e24 * s; 115 115 116 } else { 116 } else { 117 meanlife = aLife; 117 meanlife = aLife; 118 } 118 } 119 119 120 #ifdef G4VERBOSE 120 #ifdef G4VERBOSE 121 if (GetVerboseLevel()>1) { 121 if (GetVerboseLevel()>1) { 122 G4cout << "mean life time: "<< meanlife/n 122 G4cout << "mean life time: "<< meanlife/ns << "[ns]" << G4endl; 123 } 123 } 124 #endif 124 #endif 125 125 126 return meanlife; 126 return meanlife; 127 } 127 } 128 128 129 G4double G4Decay::GetMeanFreePath(const G4Trac 129 G4double G4Decay::GetMeanFreePath(const G4Track& aTrack,G4double, G4ForceCondition*) 130 { 130 { 131 // get particle 131 // get particle 132 const G4DynamicParticle* aParticle = aTrack 132 const G4DynamicParticle* aParticle = aTrack.GetDynamicParticle(); 133 const G4ParticleDefinition* aParticleDef = 133 const G4ParticleDefinition* aParticleDef = aParticle->GetDefinition(); 134 G4double aMass = aParticle->GetMass(); 134 G4double aMass = aParticle->GetMass(); 135 G4double aLife = aParticleDef->GetPDGLifeTi 135 G4double aLife = aParticleDef->GetPDGLifeTime(); 136 136 137 137 138 // returns the mean free path in GEANT4 in 138 // returns the mean free path in GEANT4 internal units 139 G4double pathlength; 139 G4double pathlength; 140 G4double aCtau = c_light * aLife; 140 G4double aCtau = c_light * aLife; 141 141 142 // check if the particle is stable? 142 // check if the particle is stable? 143 if (aParticleDef->GetPDGStable()) { 143 if (aParticleDef->GetPDGStable()) { 144 pathlength = DBL_MAX; 144 pathlength = DBL_MAX; 145 145 146 //check if the particle has very short life 146 //check if the particle has very short life time ? 147 } else if (aCtau < DBL_MIN) { 147 } else if (aCtau < DBL_MIN) { 148 pathlength = DBL_MIN; 148 pathlength = DBL_MIN; 149 149 150 } else { 150 } else { 151 //calculate the mean free path 151 //calculate the mean free path 152 // by using normalized kinetic energy (= E 152 // by using normalized kinetic energy (= Ekin/mass) 153 G4double rKineticEnergy = aParticle->Ge 153 G4double rKineticEnergy = aParticle->GetKineticEnergy()/aMass; 154 if ( rKineticEnergy > HighestValue) { 154 if ( rKineticEnergy > HighestValue) { 155 // gamma >> 1 155 // gamma >> 1 156 pathlength = ( rKineticEnergy + 1.0)* a 156 pathlength = ( rKineticEnergy + 1.0)* aCtau; 157 } else if ( rKineticEnergy < DBL_MIN ) { 157 } else if ( rKineticEnergy < DBL_MIN ) { 158 // too slow particle 158 // too slow particle 159 #ifdef G4VERBOSE 159 #ifdef G4VERBOSE 160 if (GetVerboseLevel()>1) { 160 if (GetVerboseLevel()>1) { 161 G4cout << "G4Decay::GetMeanFreePath() !!p 161 G4cout << "G4Decay::GetMeanFreePath() !!particle stops!!"; 162 G4cout << aParticleDef->GetParticleNa 162 G4cout << aParticleDef->GetParticleName() << G4endl; 163 G4cout << "KineticEnergy:" << aParticle->Ge 163 G4cout << "KineticEnergy:" << aParticle->GetKineticEnergy()/GeV <<"[GeV]"; 164 } 164 } 165 #endif 165 #endif 166 pathlength = DBL_MIN; 166 pathlength = DBL_MIN; 167 } else { 167 } else { 168 // beta <1 168 // beta <1 169 pathlength = (aParticle->GetTotalMoment 169 pathlength = (aParticle->GetTotalMomentum())/aMass*aCtau ; 170 } 170 } 171 } 171 } 172 return pathlength; 172 return pathlength; 173 } 173 } 174 174 175 void G4Decay::BuildPhysicsTable(const G4Partic 175 void G4Decay::BuildPhysicsTable(const G4ParticleDefinition&) 176 { 176 { 177 return; 177 return; 178 } 178 } 179 179 180 G4VParticleChange* G4Decay::DecayIt(const G4Tr 180 G4VParticleChange* G4Decay::DecayIt(const G4Track& aTrack, const G4Step& ) 181 { 181 { 182 // The DecayIt() method returns by pointer a 182 // The DecayIt() method returns by pointer a particle-change object. 183 // Units are expressed in GEANT4 internal un 183 // Units are expressed in GEANT4 internal units. 184 184 185 // Initialize ParticleChange 185 // Initialize ParticleChange 186 // all members of G4VParticleChange are 186 // all members of G4VParticleChange are set to equal to 187 // corresponding member in G4Track 187 // corresponding member in G4Track 188 fParticleChangeForDecay.Initialize(aTrack); 188 fParticleChangeForDecay.Initialize(aTrack); 189 189 190 // get particle 190 // get particle 191 const G4DynamicParticle* aParticle = aTrack. 191 const G4DynamicParticle* aParticle = aTrack.GetDynamicParticle(); 192 const G4ParticleDefinition* aParticleDef = a 192 const G4ParticleDefinition* aParticleDef = aParticle->GetDefinition(); 193 193 194 // check if the particle is stable 194 // check if the particle is stable 195 if (aParticleDef->GetPDGStable()) return &fP 195 if (aParticleDef->GetPDGStable()) return &fParticleChangeForDecay ; 196 196 197 197 198 //check if thePreAssignedDecayProducts exist 198 //check if thePreAssignedDecayProducts exists 199 const G4DecayProducts* o_products = (aPartic 199 const G4DecayProducts* o_products = (aParticle->GetPreAssignedDecayProducts()); 200 G4bool isPreAssigned = (o_products != nullpt 200 G4bool isPreAssigned = (o_products != nullptr); 201 G4DecayProducts* products = nullptr; 201 G4DecayProducts* products = nullptr; 202 202 203 // decay table 203 // decay table 204 G4DecayTable *decaytable = aParticleDef->G 204 G4DecayTable *decaytable = aParticleDef->GetDecayTable(); 205 205 206 // check if external decayer exists 206 // check if external decayer exists 207 G4bool isExtDecayer = (decaytable == nullptr 207 G4bool isExtDecayer = (decaytable == nullptr) && (pExtDecayer != nullptr); 208 208 209 // Error due to NO Decay Table 209 // Error due to NO Decay Table 210 if ( (decaytable == nullptr) && !isExtDecaye 210 if ( (decaytable == nullptr) && !isExtDecayer && !isPreAssigned ){ 211 if (GetVerboseLevel()>0) { 211 if (GetVerboseLevel()>0) { 212 G4cout << "G4Decay::DoIt : decay table 212 G4cout << "G4Decay::DoIt : decay table not defined for "; 213 G4cout << aParticle->GetDefinition()->Ge 213 G4cout << aParticle->GetDefinition()->GetParticleName()<< G4endl; 214 } 214 } 215 G4ExceptionDescription ed; << 216 ed << "For " << aParticle->GetDefinition() << 217 << " decay probability exist but decay << 218 << "- the particle will be killed;\n" << 219 << " isExtDecayer: " << isExtDecayer << 220 << "; isPreAssigned: " << isPreAssigned << 221 G4Exception( "G4Decay::DecayIt ", 215 G4Exception( "G4Decay::DecayIt ", 222 "DECAY101",JustWarning, ed); << 216 "DECAY101",JustWarning, >> 217 "Decay table is not defined"); 223 218 224 fParticleChangeForDecay.SetNumberOfSeconda 219 fParticleChangeForDecay.SetNumberOfSecondaries(0); 225 // Kill the parent particle 220 // Kill the parent particle 226 fParticleChangeForDecay.ProposeTrackStatus 221 fParticleChangeForDecay.ProposeTrackStatus( fStopAndKill ) ; 227 fParticleChangeForDecay.ProposeLocalEnergy 222 fParticleChangeForDecay.ProposeLocalEnergyDeposit(0.0); 228 223 229 ClearNumberOfInteractionLengthLeft(); 224 ClearNumberOfInteractionLengthLeft(); 230 return &fParticleChangeForDecay ; 225 return &fParticleChangeForDecay ; 231 } 226 } 232 227 233 if (isPreAssigned) { 228 if (isPreAssigned) { 234 // copy decay products 229 // copy decay products 235 products = new G4DecayProducts(*o_products 230 products = new G4DecayProducts(*o_products); 236 } else if ( isExtDecayer ) { 231 } else if ( isExtDecayer ) { 237 // decay according to external decayer 232 // decay according to external decayer 238 products = pExtDecayer->ImportDecayProduct 233 products = pExtDecayer->ImportDecayProducts(aTrack); 239 } else { 234 } else { 240 // Decay according to decay table. 235 // Decay according to decay table. 241 // Keep trying to choose a candidate decay 236 // Keep trying to choose a candidate decay channel if the dynamic mass 242 // of the decaying particle is below the s 237 // of the decaying particle is below the sum of the PDG masses of the 243 // candidate daughter particles. 238 // candidate daughter particles. 244 // This is needed because the decay table 239 // This is needed because the decay table used in Geant4 is based on 245 // the assumption of nominal PDG masses, b 240 // the assumption of nominal PDG masses, but a wide resonance can have 246 // a dynamic masses well below its nominal 241 // a dynamic masses well below its nominal PDG masses, and therefore 247 // some of its decay channels can be below 242 // some of its decay channels can be below the kinematical threshold. 248 // Note that, for simplicity, we ignore he 243 // Note that, for simplicity, we ignore here the possibility that 249 // one or more of the candidate daughter p 244 // one or more of the candidate daughter particles can be, in turn, 250 // wide resonance. However, if this is the 245 // wide resonance. However, if this is the case, and the channel is 251 // accepted, then the masses of the resona 246 // accepted, then the masses of the resonance daughter particles will 252 // be sampled by taking into account their 247 // be sampled by taking into account their widths. 253 G4VDecayChannel* decaychannel = nullptr; 248 G4VDecayChannel* decaychannel = nullptr; 254 G4double massParent = aParticle->GetMass() 249 G4double massParent = aParticle->GetMass(); 255 decaychannel = decaytable->SelectADecayCha 250 decaychannel = decaytable->SelectADecayChannel(massParent); 256 if ( decaychannel == nullptr) { 251 if ( decaychannel == nullptr) { 257 // decay channel not found 252 // decay channel not found 258 G4ExceptionDescription ed; 253 G4ExceptionDescription ed; 259 ed << "Can not determine decay channel f 254 ed << "Can not determine decay channel for " 260 << aParticleDef->GetParticleName() << G4end 255 << aParticleDef->GetParticleName() << G4endl 261 << " mass of dynamic particle: " 256 << " mass of dynamic particle: " 262 << massParent/GeV << " (GEV)" << G4endl 257 << massParent/GeV << " (GEV)" << G4endl 263 << " dacay table has " << decaytable->entr 258 << " dacay table has " << decaytable->entries() 264 << " entries" << G4endl; 259 << " entries" << G4endl; 265 G4double checkedmass=massParent; 260 G4double checkedmass=massParent; 266 if (massParent < 0.) { 261 if (massParent < 0.) { 267 checkedmass=aParticleDef->GetPDGMass(); 262 checkedmass=aParticleDef->GetPDGMass(); 268 ed << "Using PDG mass ("<<checkedmass/GeV 263 ed << "Using PDG mass ("<<checkedmass/GeV 269 << "(GeV)) in IsOKWithParentMass" << G4en 264 << "(GeV)) in IsOKWithParentMass" << G4endl; 270 } 265 } 271 for (G4int ic =0;ic <decaytable->entries 266 for (G4int ic =0;ic <decaytable->entries();++ic) { 272 G4VDecayChannel * dc= decaytable->GetDecayCh 267 G4VDecayChannel * dc= decaytable->GetDecayChannel(ic); 273 ed << ic << ": BR " << dc->GetBR() << ", IsO 268 ed << ic << ": BR " << dc->GetBR() << ", IsOK? " 274 << dc->IsOKWithParentMass(checkedmass) 269 << dc->IsOKWithParentMass(checkedmass) 275 << ", --> "; 270 << ", --> "; 276 G4int ndaughters=dc->GetNumberOfDaughters(); 271 G4int ndaughters=dc->GetNumberOfDaughters(); 277 for (G4int id=0;id<ndaughters;++id) { 272 for (G4int id=0;id<ndaughters;++id) { 278 if (id>0) ed << " + "; // seperator, exc 273 if (id>0) ed << " + "; // seperator, except for first 279 ed << dc->GetDaughterName(id); 274 ed << dc->GetDaughterName(id); 280 } 275 } 281 ed << G4endl; 276 ed << G4endl; 282 } 277 } 283 G4Exception("G4Decay::DoIt", "DECAY003", 278 G4Exception("G4Decay::DoIt", "DECAY003", FatalException,ed); 284 } else { 279 } else { 285 // execute DecayIt() 280 // execute DecayIt() 286 #ifdef G4VERBOSE 281 #ifdef G4VERBOSE 287 G4int temp = decaychannel->GetVerboseLev 282 G4int temp = decaychannel->GetVerboseLevel(); 288 if (GetVerboseLevel()>1) { 283 if (GetVerboseLevel()>1) { 289 G4cout << "G4Decay::DoIt : selected decay c 284 G4cout << "G4Decay::DoIt : selected decay channel addr:" 290 << decaychannel <<G4endl; 285 << decaychannel <<G4endl; 291 decaychannel->SetVerboseLevel(GetVerboseLeve 286 decaychannel->SetVerboseLevel(GetVerboseLevel()); 292 } 287 } 293 #endif 288 #endif 294 products = decaychannel->DecayIt(aPartic 289 products = decaychannel->DecayIt(aParticle->GetMass()); 295 #ifdef G4VERBOSE 290 #ifdef G4VERBOSE 296 if (GetVerboseLevel()>1) { 291 if (GetVerboseLevel()>1) { 297 decaychannel->SetVerboseLevel(temp); 292 decaychannel->SetVerboseLevel(temp); 298 } 293 } 299 #endif 294 #endif 300 #ifdef G4VERBOSE 295 #ifdef G4VERBOSE 301 if (GetVerboseLevel()>2) { 296 if (GetVerboseLevel()>2) { 302 if (! products->IsChecked() ) products->Dump 297 if (! products->IsChecked() ) products->DumpInfo(); 303 } 298 } 304 #endif 299 #endif 305 } 300 } 306 } 301 } 307 302 308 // get parent particle information ......... 303 // get parent particle information ................................... 309 G4double ParentEnergy = aParticle->GetTot 304 G4double ParentEnergy = aParticle->GetTotalEnergy(); 310 G4double ParentMass = aParticle->GetMas 305 G4double ParentMass = aParticle->GetMass(); 311 if (ParentEnergy < ParentMass) { 306 if (ParentEnergy < ParentMass) { 312 G4ExceptionDescription ed; << 307 if (GetVerboseLevel()>0) { 313 ed << "Total Energy is less than its mass << 308 G4cout << "G4Decay::DoIt : Total Energy is less than its mass" << G4endl; 314 << "\n Particle: " << aParticle->GetDef << 309 G4cout << " Particle: " << aParticle->GetDefinition()->GetParticleName(); 315 << "\n Energy:" << ParentEnergy/MeV << 310 G4cout << " Energy:" << ParentEnergy/MeV << "[MeV]"; 316 << "\n Mass:" << ParentMass/MeV << << 311 G4cout << " Mass:" << ParentMass/MeV << "[MeV]"; >> 312 G4cout << G4endl; >> 313 } 317 G4Exception( "G4Decay::DecayIt ", 314 G4Exception( "G4Decay::DecayIt ", 318 "DECAY102",JustWarning, ed); << 315 "DECAY102",JustWarning, >> 316 "Total Energy is less than its mass"); 319 ParentEnergy = ParentMass; 317 ParentEnergy = ParentMass; 320 } 318 } 321 319 322 G4ThreeVector ParentDirection(aParticle->Get 320 G4ThreeVector ParentDirection(aParticle->GetMomentumDirection()); 323 321 324 //boost all decay products to laboratory fra 322 //boost all decay products to laboratory frame 325 G4double energyDeposit = 0.0; 323 G4double energyDeposit = 0.0; 326 G4double finalGlobalTime = aTrack.GetGlobalT 324 G4double finalGlobalTime = aTrack.GetGlobalTime(); 327 G4double finalLocalTime = aTrack.GetLocalTim 325 G4double finalLocalTime = aTrack.GetLocalTime(); 328 if (aTrack.GetTrackStatus() == fStopButAlive 326 if (aTrack.GetTrackStatus() == fStopButAlive ){ 329 // AtRest case 327 // AtRest case 330 finalGlobalTime += fRemainderLifeTime; 328 finalGlobalTime += fRemainderLifeTime; 331 finalLocalTime += fRemainderLifeTime; 329 finalLocalTime += fRemainderLifeTime; 332 energyDeposit += aParticle->GetKineticEner 330 energyDeposit += aParticle->GetKineticEnergy(); 333 if (isPreAssigned) products->Boost( Parent 331 if (isPreAssigned) products->Boost( ParentEnergy, ParentDirection); 334 } else { 332 } else { 335 // PostStep case 333 // PostStep case 336 if (!isExtDecayer) products->Boost( Parent 334 if (!isExtDecayer) products->Boost( ParentEnergy, ParentDirection); 337 } 335 } 338 // set polarization for daughter particles 336 // set polarization for daughter particles 339 DaughterPolarization(aTrack, products); 337 DaughterPolarization(aTrack, products); 340 338 341 339 342 //add products in fParticleChangeForDecay 340 //add products in fParticleChangeForDecay 343 G4int numberOfSecondaries = products->entrie 341 G4int numberOfSecondaries = products->entries(); 344 fParticleChangeForDecay.SetNumberOfSecondari 342 fParticleChangeForDecay.SetNumberOfSecondaries(numberOfSecondaries); 345 #ifdef G4VERBOSE 343 #ifdef G4VERBOSE 346 if (GetVerboseLevel()>1) { 344 if (GetVerboseLevel()>1) { 347 G4cout << "G4Decay::DoIt : Decay vertex : 345 G4cout << "G4Decay::DoIt : Decay vertex :"; 348 G4cout << " Time: " << finalGlobalTime/ns 346 G4cout << " Time: " << finalGlobalTime/ns << "[ns]"; 349 G4cout << " X:" << (aTrack.GetPosition()). 347 G4cout << " X:" << (aTrack.GetPosition()).x() /cm << "[cm]"; 350 G4cout << " Y:" << (aTrack.GetPosition()). 348 G4cout << " Y:" << (aTrack.GetPosition()).y() /cm << "[cm]"; 351 G4cout << " Z:" << (aTrack.GetPosition()). 349 G4cout << " Z:" << (aTrack.GetPosition()).z() /cm << "[cm]"; 352 G4cout << G4endl; 350 G4cout << G4endl; 353 G4cout << "G4Decay::DoIt : decay products 351 G4cout << "G4Decay::DoIt : decay products in Lab. Frame" << G4endl; 354 products->DumpInfo(); 352 products->DumpInfo(); 355 } 353 } 356 #endif 354 #endif 357 G4int index; 355 G4int index; 358 G4ThreeVector currentPosition; 356 G4ThreeVector currentPosition; 359 const G4TouchableHandle thand = aTrack.GetTo 357 const G4TouchableHandle thand = aTrack.GetTouchableHandle(); 360 for (index=0; index < numberOfSecondaries; i 358 for (index=0; index < numberOfSecondaries; index++){ 361 // get current position of the track 359 // get current position of the track 362 currentPosition = aTrack.GetPosition(); 360 currentPosition = aTrack.GetPosition(); 363 // create a new track object 361 // create a new track object 364 G4Track* secondary = new G4Track( products 362 G4Track* secondary = new G4Track( products->PopProducts(), 365 finalGlobalTime , 363 finalGlobalTime , 366 currentPosition ); 364 currentPosition ); 367 // switch on good for tracking flag 365 // switch on good for tracking flag 368 secondary->SetGoodForTrackingFlag(); 366 secondary->SetGoodForTrackingFlag(); 369 secondary->SetTouchableHandle(thand); 367 secondary->SetTouchableHandle(thand); 370 // add the secondary track in the List 368 // add the secondary track in the List 371 fParticleChangeForDecay.AddSecondary(secon 369 fParticleChangeForDecay.AddSecondary(secondary); 372 } 370 } 373 delete products; 371 delete products; 374 372 375 // Kill the parent particle 373 // Kill the parent particle 376 fParticleChangeForDecay.ProposeTrackStatus( 374 fParticleChangeForDecay.ProposeTrackStatus( fStopAndKill ) ; 377 fParticleChangeForDecay.ProposeLocalEnergyDe 375 fParticleChangeForDecay.ProposeLocalEnergyDeposit(energyDeposit); 378 fParticleChangeForDecay.ProposeLocalTime( fi 376 fParticleChangeForDecay.ProposeLocalTime( finalLocalTime ); 379 377 380 // Clear NumberOfInteractionLengthLeft 378 // Clear NumberOfInteractionLengthLeft 381 ClearNumberOfInteractionLengthLeft(); 379 ClearNumberOfInteractionLengthLeft(); 382 380 383 return &fParticleChangeForDecay ; 381 return &fParticleChangeForDecay ; 384 } 382 } 385 383 386 void G4Decay::DaughterPolarization(const G4Tra 384 void G4Decay::DaughterPolarization(const G4Track& , G4DecayProducts* ) 387 { 385 { 388 // empty implementation 386 // empty implementation 389 } 387 } 390 388 391 389 392 390 393 void G4Decay::StartTracking(G4Track*) 391 void G4Decay::StartTracking(G4Track*) 394 { 392 { 395 currentInteractionLength = -1.0; 393 currentInteractionLength = -1.0; 396 ResetNumberOfInteractionLengthLeft(); 394 ResetNumberOfInteractionLengthLeft(); 397 395 398 fRemainderLifeTime = -1.0; 396 fRemainderLifeTime = -1.0; 399 } 397 } 400 398 401 void G4Decay::EndTracking() 399 void G4Decay::EndTracking() 402 { 400 { 403 // Clear NumberOfInteractionLengthLeft 401 // Clear NumberOfInteractionLengthLeft 404 ClearNumberOfInteractionLengthLeft(); 402 ClearNumberOfInteractionLengthLeft(); 405 403 406 currentInteractionLength = -1.0; 404 currentInteractionLength = -1.0; 407 } 405 } 408 406 409 407 410 G4double G4Decay::PostStepGetPhysicalInteracti 408 G4double G4Decay::PostStepGetPhysicalInteractionLength( 411 const G4Track& tr 409 const G4Track& track, 412 G4double previo 410 G4double previousStepSize, 413 G4ForceCondition* 411 G4ForceCondition* condition 414 ) 412 ) 415 { 413 { 416 // condition is set to "Not Forced" 414 // condition is set to "Not Forced" 417 *condition = NotForced; 415 *condition = NotForced; 418 416 419 // pre-assigned Decay time 417 // pre-assigned Decay time 420 G4double pTime = track.GetDynamicParticle()- 418 G4double pTime = track.GetDynamicParticle()->GetPreAssignedDecayProperTime(); 421 G4double aLife = track.GetDynamicParticle()- 419 G4double aLife = track.GetDynamicParticle()->GetDefinition()->GetPDGLifeTime(); 422 420 423 if (pTime < 0.) { 421 if (pTime < 0.) { 424 // normal case 422 // normal case 425 if ( previousStepSize > 0.0){ 423 if ( previousStepSize > 0.0){ 426 // subtract NumberOfInteractionLengthLef 424 // subtract NumberOfInteractionLengthLeft 427 SubtractNumberOfInteractionLengthLeft(pr 425 SubtractNumberOfInteractionLengthLeft(previousStepSize); 428 if(theNumberOfInteractionLengthLeft<0.){ 426 if(theNumberOfInteractionLengthLeft<0.){ 429 theNumberOfInteractionLengthLeft=perMillion; 427 theNumberOfInteractionLengthLeft=perMillion; 430 } 428 } 431 fRemainderLifeTime = theNumberOfInteract 429 fRemainderLifeTime = theNumberOfInteractionLengthLeft*aLife; 432 } 430 } 433 // get mean free path 431 // get mean free path 434 currentInteractionLength = GetMeanFreePath 432 currentInteractionLength = GetMeanFreePath(track, previousStepSize, condition); 435 433 436 #ifdef G4VERBOSE 434 #ifdef G4VERBOSE 437 if ((currentInteractionLength <=0.0) || (v 435 if ((currentInteractionLength <=0.0) || (verboseLevel>2)){ 438 G4cout << "G4Decay::PostStepGetPhysicalI 436 G4cout << "G4Decay::PostStepGetPhysicalInteractionLength " << G4endl; 439 track.GetDynamicParticle()->DumpInfo(); 437 track.GetDynamicParticle()->DumpInfo(); 440 G4cout << " in Material " << track.GetM 438 G4cout << " in Material " << track.GetMaterial()->GetName() <<G4endl; 441 G4cout << "MeanFreePath = " << currentIn 439 G4cout << "MeanFreePath = " << currentInteractionLength/cm << "[cm]" <<G4endl; 442 } 440 } 443 #endif 441 #endif 444 442 445 G4double value; 443 G4double value; 446 if (currentInteractionLength <DBL_MAX) { 444 if (currentInteractionLength <DBL_MAX) { 447 value = theNumberOfInteractionLengthLeft 445 value = theNumberOfInteractionLengthLeft * currentInteractionLength; 448 //fRemainderLifeTime = theNumberOfIntera 446 //fRemainderLifeTime = theNumberOfInteractionLengthLeft*aLife; 449 } else { 447 } else { 450 value = DBL_MAX; 448 value = DBL_MAX; 451 } 449 } 452 450 453 return value; 451 return value; 454 452 455 } else { 453 } else { 456 //pre-assigned Decay time case 454 //pre-assigned Decay time case 457 // reminder proper time 455 // reminder proper time 458 fRemainderLifeTime = pTime - track.GetProp 456 fRemainderLifeTime = pTime - track.GetProperTime(); 459 if (fRemainderLifeTime <= 0.0) fRemainderL 457 if (fRemainderLifeTime <= 0.0) fRemainderLifeTime = 0.0; 460 458 461 G4double rvalue=0.0; 459 G4double rvalue=0.0; 462 // use pre-assigned Decay time to determin 460 // use pre-assigned Decay time to determine PIL 463 if (aLife>0.0) { 461 if (aLife>0.0) { 464 // ordinary particle 462 // ordinary particle 465 rvalue = (fRemainderLifeTime/aLife)*GetM 463 rvalue = (fRemainderLifeTime/aLife)*GetMeanFreePath(track, previousStepSize, condition); 466 } else { 464 } else { 467 // shortlived particle 465 // shortlived particle 468 rvalue = c_light * fRemainderLifeTime; 466 rvalue = c_light * fRemainderLifeTime; 469 // by using normalized kinetic energy (= 467 // by using normalized kinetic energy (= Ekin/mass) 470 G4double aMass = track.GetDynamicParti 468 G4double aMass = track.GetDynamicParticle()->GetMass(); 471 rvalue *= track.GetDynamicParticle()->Get 469 rvalue *= track.GetDynamicParticle()->GetTotalMomentum()/aMass; 472 } 470 } 473 return rvalue; 471 return rvalue; 474 } 472 } 475 } 473 } 476 474 477 G4double G4Decay::AtRestGetPhysicalInteraction 475 G4double G4Decay::AtRestGetPhysicalInteractionLength( 478 const G4Track& tr 476 const G4Track& track, 479 G4ForceCondition* 477 G4ForceCondition* condition 480 ) 478 ) 481 { 479 { 482 // condition is set to "Not Forced" 480 // condition is set to "Not Forced" 483 *condition = NotForced; 481 *condition = NotForced; 484 482 485 G4double pTime = track.GetDynamicParticle()- 483 G4double pTime = track.GetDynamicParticle()->GetPreAssignedDecayProperTime(); 486 if (pTime >= 0.) { 484 if (pTime >= 0.) { 487 fRemainderLifeTime = pTime - track.GetProp 485 fRemainderLifeTime = pTime - track.GetProperTime(); 488 if (fRemainderLifeTime <= 0.0) fRemainderL 486 if (fRemainderLifeTime <= 0.0) fRemainderLifeTime = DBL_MIN; 489 } else { 487 } else { 490 fRemainderLifeTime = 488 fRemainderLifeTime = 491 theNumberOfInteractionLengthLeft * GetMe 489 theNumberOfInteractionLengthLeft * GetMeanLifeTime(track, condition); 492 } 490 } 493 return fRemainderLifeTime; 491 return fRemainderLifeTime; 494 } 492 } 495 493 496 494 497 void G4Decay::SetExtDecayer(G4VExtDecayer* val 495 void G4Decay::SetExtDecayer(G4VExtDecayer* val) 498 { 496 { 499 pExtDecayer = val; 497 pExtDecayer = val; 500 498 501 // set Process Sub Type 499 // set Process Sub Type 502 if ( pExtDecayer !=0 ) { 500 if ( pExtDecayer !=0 ) { 503 SetProcessSubType(static_cast<int>(DECAY_E 501 SetProcessSubType(static_cast<int>(DECAY_External)); 504 } 502 } 505 } 503 } 506 504 507 G4VParticleChange* G4Decay::PostStepDoIt( 505 G4VParticleChange* G4Decay::PostStepDoIt( 508 const G4Track& aTrack, 506 const G4Track& aTrack, 509 const G4Step& aStep 507 const G4Step& aStep 510 ) 508 ) 511 { 509 { 512 if ( (aTrack.GetTrackStatus() == fStopButAli 510 if ( (aTrack.GetTrackStatus() == fStopButAlive ) || 513 (aTrack.GetTrackStatus() == fStopAndKil 511 (aTrack.GetTrackStatus() == fStopAndKill ) ){ 514 fParticleChangeForDecay.Initialize(aTrack) 512 fParticleChangeForDecay.Initialize(aTrack); 515 return &fParticleChangeForDecay; 513 return &fParticleChangeForDecay; 516 } else { 514 } else { 517 return DecayIt(aTrack, aStep); 515 return DecayIt(aTrack, aStep); 518 } 516 } 519 } 517 } 520 518 521 void G4Decay::ProcessDescription(std::ostream& 519 void G4Decay::ProcessDescription(std::ostream& outFile) const 522 { 520 { 523 outFile << GetProcessName() << ": Decay of p 521 outFile << GetProcessName() << ": Decay of particles. \n" 524 << "kinematics of daughters are dertermine 522 << "kinematics of daughters are dertermined by DecayChannels " 525 << " or by PreAssignedDecayProducts\ 523 << " or by PreAssignedDecayProducts\n"; 526 } 524 } 527 525