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>> 68 G4int G4VAtomDeexcitation::pixeIDe = -1; >> 69 72 G4VAtomDeexcitation::G4VAtomDeexcitation(const 70 G4VAtomDeexcitation::G4VAtomDeexcitation(const G4String& modname) 73 : name(modname) << 71 : verbose(1), name(modname), isActive(false), flagAuger(false), >> 72 flagAugerCascade(false), flagPIXE(false), ignoreCuts(false), >> 73 isActiveLocked(false), isAugerLocked(false), >> 74 isAugerCascadeLocked(false), isPIXELocked(false) 74 { 75 { >> 76 theParameters = G4EmParameters::Instance(); 75 vdyn.reserve(5); 77 vdyn.reserve(5); 76 theCoupleTable = nullptr; 78 theCoupleTable = nullptr; >> 79 G4String gg = "gammaPIXE"; >> 80 G4String ee = "e-PIXE"; >> 81 if(pixeIDg < 0) { pixeIDg = G4PhysicsModelCatalog::Register(gg); } >> 82 if(pixeIDe < 0) { pixeIDe = G4PhysicsModelCatalog::Register(ee); } 77 gamma = G4Gamma::Gamma(); 83 gamma = G4Gamma::Gamma(); 78 } 84 } 79 85 80 //....oooOO0OOooo........oooOO0OOooo........oo 86 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 81 87 82 G4VAtomDeexcitation::~G4VAtomDeexcitation() = << 88 G4VAtomDeexcitation::~G4VAtomDeexcitation() >> 89 {} 83 90 84 //....oooOO0OOooo........oooOO0OOooo........oo 91 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 85 92 86 void G4VAtomDeexcitation::InitialiseAtomicDeex 93 void G4VAtomDeexcitation::InitialiseAtomicDeexcitation() 87 { 94 { 88 G4EmParameters* theParameters = G4EmParamete << 89 theParameters->DefineRegParamForDeex(this); 95 theParameters->DefineRegParamForDeex(this); 90 96 91 // Define list of couples 97 // Define list of couples 92 theCoupleTable = G4ProductionCutsTable::GetP 98 theCoupleTable = G4ProductionCutsTable::GetProductionCutsTable(); 93 nCouples = (G4int)theCoupleTable->GetTableSi << 99 G4int numOfCouples = theCoupleTable->GetTableSize(); 94 100 95 // needed for unit tests 101 // needed for unit tests 96 std::size_t nn = std::max(nCouples, 1); << 102 G4int nn = std::max(numOfCouples, 1); 97 if(activeDeexcitationMedia.size() != nn) { << 103 activeDeexcitationMedia.resize(nn, false); 98 activeDeexcitationMedia.resize(nn, false); << 104 activeAugerMedia.resize(nn, false); 99 activeAugerMedia.resize(nn, false); << 105 activePIXEMedia.resize(nn, false); 100 activePIXEMedia.resize(nn, false); << 106 activeZ.resize(93, false); 101 } << 102 if(activeZ.size() != 93) { activeZ.resize(93 << 103 107 104 // initialisation of flags and options 108 // initialisation of flags and options 105 // normally there is no locksed flags 109 // normally there is no locksed flags 106 if(!isActiveLocked) { isActive = theParamet << 110 if(!isActiveLocked) { isActive = theParameters->Fluo(); } 107 if(!isAugerLocked) { flagAuger = theParamet << 111 if(!isAugerLocked) { flagAuger = theParameters->Auger(); } 108 if(!isPIXELocked) { flagPIXE = theParamet << 112 if(!isAugerCascadeLocked) { flagAugerCascade = theParameters->AugerCascade(); } >> 113 if(!isPIXELocked) { flagPIXE = theParameters->Pixe(); } 109 ignoreCuts = theParameters->DeexcitationIgno 114 ignoreCuts = theParameters->DeexcitationIgnoreCut(); 110 115 111 // Define list of regions 116 // Define list of regions 112 std::size_t nRegions = deRegions.size(); << 117 size_t nRegions = deRegions.size(); 113 // check if deexcitation is active for the g 118 // check if deexcitation is active for the given run 114 if(!isActive && 0 == nRegions) { return; } 119 if(!isActive && 0 == nRegions) { return; } 115 120 116 // if no active regions add a world 121 // if no active regions add a world 117 if(0 == nRegions) { 122 if(0 == nRegions) { 118 SetDeexcitationActiveRegion("World",isActi 123 SetDeexcitationActiveRegion("World",isActive,flagAuger,flagPIXE); 119 nRegions = deRegions.size(); 124 nRegions = deRegions.size(); 120 } 125 } 121 126 122 if(0 < verbose) { 127 if(0 < verbose) { 123 G4cout << G4endl; 128 G4cout << G4endl; 124 G4cout << "### === Deexcitation model " < 129 G4cout << "### === Deexcitation model " << name 125 << " is activated for " << nRegions 130 << " is activated for " << nRegions; 126 if(1 == nRegions) { G4cout << " region:" < 131 if(1 == nRegions) { G4cout << " region:" << G4endl; } 127 else { G4cout << " regions:" 132 else { G4cout << " regions:" << G4endl;} 128 } 133 } 129 134 130 // Identify active media 135 // Identify active media 131 const G4RegionStore* regionStore = G4RegionS << 136 G4RegionStore* regionStore = G4RegionStore::GetInstance(); 132 for(std::size_t j=0; j<nRegions; ++j) { << 137 for(size_t j=0; j<nRegions; ++j) { 133 const G4Region* reg = regionStore->GetRegi 138 const G4Region* reg = regionStore->GetRegion(activeRegions[j], false); 134 if(nullptr != reg && 0 < nCouples) { << 139 if(reg && 0 < numOfCouples) { 135 const G4ProductionCuts* rpcuts = reg->Ge 140 const G4ProductionCuts* rpcuts = reg->GetProductionCuts(); 136 if(0 < verbose) { 141 if(0 < verbose) { 137 G4cout << " " << activeRegion 142 G4cout << " " << activeRegions[j] 138 << " " << deRegions[j] << " << 143 << " " << deRegions[j] << " " << AugerRegions[j] 139 << " " << PIXERegions[j] << G4 << 144 << " " << PIXERegions[j] << G4endl; 140 } 145 } 141 for(G4int i=0; i<nCouples; ++i) { << 146 for(G4int i=0; i<numOfCouples; ++i) { 142 const G4MaterialCutsCouple* couple = 147 const G4MaterialCutsCouple* couple = 143 theCoupleTable->GetMaterialCutsCoupl 148 theCoupleTable->GetMaterialCutsCouple(i); 144 if (couple->GetProductionCuts() == rpc 149 if (couple->GetProductionCuts() == rpcuts) { 145 activeDeexcitationMedia[i] = deRegio 150 activeDeexcitationMedia[i] = deRegions[j]; 146 activeAugerMedia[i] = AugerRegions[j 151 activeAugerMedia[i] = AugerRegions[j]; 147 activePIXEMedia[i] = PIXERegions[j]; 152 activePIXEMedia[i] = PIXERegions[j]; 148 } 153 } 149 } 154 } 150 } 155 } 151 } 156 } 152 std::size_t nelm = G4Element::GetNumberOfEle << 157 G4int nelm = G4Element::GetNumberOfElements(); 153 //G4cout << nelm << G4endl; 158 //G4cout << nelm << G4endl; 154 for(std::size_t k=0; k<nelm; ++k) { << 159 for(G4int k=0; k<nelm; ++k) { 155 G4int Z = (*(G4Element::GetElementTable()) 160 G4int Z = (*(G4Element::GetElementTable()))[k]->GetZasInt(); 156 if(Z > 5 && Z < 93) { 161 if(Z > 5 && Z < 93) { 157 activeZ[Z] = true; 162 activeZ[Z] = true; 158 //G4cout << "!!! Active de-excitation Z= 163 //G4cout << "!!! Active de-excitation Z= " << Z << G4endl; 159 } 164 } 160 } 165 } 161 166 162 // Initialise derived class 167 // Initialise derived class 163 InitialiseForNewRun(); 168 InitialiseForNewRun(); 164 169 165 if(0 < verbose && flagAuger) { 170 if(0 < verbose && flagAuger) { 166 G4cout << "### === Auger flag: " << flagA << 171 G4cout << "### === Auger cascade flag: " << flagAugerCascade 167 << G4endl; << 172 << G4endl; 168 } 173 } 169 if(0 < verbose) { 174 if(0 < verbose) { 170 G4cout << "### === Ignore cuts flag: " 175 G4cout << "### === Ignore cuts flag: " << ignoreCuts 171 << G4endl; << 176 << G4endl; 172 } 177 } 173 if(0 < verbose && flagPIXE) { 178 if(0 < verbose && flagPIXE) { 174 G4cout << "### === PIXE model for hadrons 179 G4cout << "### === PIXE model for hadrons: " 175 << theParameters->PIXECrossSectionM 180 << theParameters->PIXECrossSectionModel() 176 << G4endl; 181 << G4endl; 177 G4cout << "### === PIXE model for e+-: 182 G4cout << "### === PIXE model for e+-: " 178 << theParameters->PIXEElectronCross 183 << theParameters->PIXEElectronCrossSectionModel() 179 << G4endl; 184 << G4endl; 180 } 185 } 181 } 186 } 182 187 183 //....oooOO0OOooo........oooOO0OOooo........oo 188 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 184 189 185 void 190 void 186 G4VAtomDeexcitation::SetDeexcitationActiveRegi 191 G4VAtomDeexcitation::SetDeexcitationActiveRegion(const G4String& rname, 187 192 G4bool valDeexcitation, 188 193 G4bool valAuger, 189 194 G4bool valPIXE) 190 { 195 { 191 // no PIXE in parallel world 196 // no PIXE in parallel world 192 if(rname == "DefaultRegionForParallelWorld") 197 if(rname == "DefaultRegionForParallelWorld") { return; } 193 198 194 G4String ss = rname; 199 G4String ss = rname; 195 /* 200 /* 196 G4cout << "### G4VAtomDeexcitation::SetDeexc 201 G4cout << "### G4VAtomDeexcitation::SetDeexcitationActiveRegion " << ss 197 << " " << valDeexcitation << " " << 202 << " " << valDeexcitation << " " << valAuger 198 << " " << valPIXE << G4endl; 203 << " " << valPIXE << G4endl; 199 */ 204 */ 200 if(ss == "world" || ss == "World" || ss == " 205 if(ss == "world" || ss == "World" || ss == "WORLD") { 201 ss = "DefaultRegionForTheWorld"; 206 ss = "DefaultRegionForTheWorld"; 202 } 207 } 203 std::size_t n = deRegions.size(); << 208 size_t n = deRegions.size(); 204 for(std::size_t i=0; i<n; ++i) { << 209 for(size_t i=0; i<n; ++i) { 205 210 206 // Region already exist 211 // Region already exist 207 if(ss == activeRegions[i]) { 212 if(ss == activeRegions[i]) { 208 deRegions[i] = valDeexcitation; 213 deRegions[i] = valDeexcitation; 209 AugerRegions[i] = valAuger; 214 AugerRegions[i] = valAuger; 210 PIXERegions[i] = valPIXE; 215 PIXERegions[i] = valPIXE; 211 return; 216 return; 212 } 217 } 213 } 218 } 214 // New region 219 // New region 215 activeRegions.push_back(ss); 220 activeRegions.push_back(ss); 216 deRegions.push_back(valDeexcitation); 221 deRegions.push_back(valDeexcitation); 217 AugerRegions.push_back(valAuger); 222 AugerRegions.push_back(valAuger); 218 PIXERegions.push_back(valPIXE); 223 PIXERegions.push_back(valPIXE); 219 224 220 // if de-excitation defined for the world vo 225 // if de-excitation defined for the world volume 221 // it should be active for all G4Regions 226 // it should be active for all G4Regions 222 if(ss == "DefaultRegionForTheWorld") { 227 if(ss == "DefaultRegionForTheWorld") { 223 G4RegionStore* regions = G4RegionStore::Ge 228 G4RegionStore* regions = G4RegionStore::GetInstance(); 224 std::size_t nn = regions->size(); << 229 G4int nn = regions->size(); 225 for(std::size_t i=0; i<nn; ++i) { << 230 for(G4int i=0; i<nn; ++i) { 226 if(ss == (*regions)[i]->GetName()) { con 231 if(ss == (*regions)[i]->GetName()) { continue; } 227 SetDeexcitationActiveRegion((*regions)[i 232 SetDeexcitationActiveRegion((*regions)[i]->GetName(), valDeexcitation, 228 valAuger, va 233 valAuger, valPIXE); 229 234 230 } 235 } 231 } 236 } 232 } 237 } 233 238 234 void G4VAtomDeexcitation::GenerateParticles(st << 235 co << 236 G4 << 237 { << 238 G4double gCut = DBL_MAX; << 239 if(ignoreCuts) { << 240 gCut = 0.0; << 241 } else if (nullptr != theCoupleTable) { << 242 gCut = (*(theCoupleTable->GetEnergyCutsVec << 243 } << 244 if(gCut < as->BindingEnergy()) { << 245 G4double eCut = DBL_MAX; << 246 if(CheckAugerActiveRegion(idx)) { << 247 if(ignoreCuts) { << 248 eCut = 0.0; << 249 } else if (nullptr != theCoupleTable) { << 250 eCut = (*(theCoupleTable->GetEnergyCut << 251 } << 252 } << 253 GenerateParticles(v, as, Z, gCut, eCut); << 254 } << 255 } << 256 << 257 //....oooOO0OOooo........oooOO0OOooo........oo 239 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 258 240 259 void 241 void 260 G4VAtomDeexcitation::AlongStepDeexcitation(std 242 G4VAtomDeexcitation::AlongStepDeexcitation(std::vector<G4Track*>& tracks, 261 con 243 const G4Step& step, 262 G4d 244 G4double& eLossMax, 263 G4i 245 G4int coupleIndex) 264 { 246 { 265 G4double truelength = step.GetStepLength(); 247 G4double truelength = step.GetStepLength(); 266 if(!flagPIXE && !activePIXEMedia[coupleIndex 248 if(!flagPIXE && !activePIXEMedia[coupleIndex]) { return; } 267 if(eLossMax <= 0.0 || truelength <= 0.0) 249 if(eLossMax <= 0.0 || truelength <= 0.0) { return; } 268 250 269 // step parameters 251 // step parameters 270 const G4StepPoint* preStep = step.GetPreStep 252 const G4StepPoint* preStep = step.GetPreStepPoint(); 271 const G4ThreeVector prePos = preStep->GetPos << 253 G4ThreeVector prePos = preStep->GetPosition(); 272 const G4ThreeVector delta = step.GetPostStep << 254 G4ThreeVector delta = step.GetPostStepPoint()->GetPosition() - prePos; 273 const G4double preTime = preStep->GetGlobalT << 255 G4double preTime = preStep->GetGlobalTime(); 274 const G4double dt = step.GetPostStepPoint()- << 256 G4double dt = step.GetPostStepPoint()->GetGlobalTime() - preTime; 275 257 276 // particle parameters 258 // particle parameters 277 const G4Track* track = step.GetTrack(); 259 const G4Track* track = step.GetTrack(); 278 const G4ParticleDefinition* part = track->Ge 260 const G4ParticleDefinition* part = track->GetDefinition(); 279 G4double ekin = preStep->GetKineticEnergy(); 261 G4double ekin = preStep->GetKineticEnergy(); 280 262 281 // media parameters 263 // media parameters 282 G4double gCut = (*theCoupleTable->GetEnergyC 264 G4double gCut = (*theCoupleTable->GetEnergyCutsVector(0))[coupleIndex]; 283 if(ignoreCuts) { gCut = 0.0; } 265 if(ignoreCuts) { gCut = 0.0; } 284 G4double eCut = DBL_MAX; 266 G4double eCut = DBL_MAX; 285 if(CheckAugerActiveRegion(coupleIndex)) { 267 if(CheckAugerActiveRegion(coupleIndex)) { 286 eCut = (*theCoupleTable->GetEnergyCutsVect 268 eCut = (*theCoupleTable->GetEnergyCutsVector(1))[coupleIndex]; 287 if(ignoreCuts) { eCut = 0.0; } 269 if(ignoreCuts) { eCut = 0.0; } 288 } 270 } 289 271 290 //G4cout<<"!Sample PIXE gCut(MeV)= "<<gCut<< 272 //G4cout<<"!Sample PIXE gCut(MeV)= "<<gCut<<" eCut(MeV)= "<<eCut 291 // <<" Ekin(MeV)= " << ekin/MeV << G4 273 // <<" Ekin(MeV)= " << ekin/MeV << G4endl; 292 274 293 const G4Material* material = preStep->GetMat 275 const G4Material* material = preStep->GetMaterial(); 294 const G4ElementVector* theElementVector = ma 276 const G4ElementVector* theElementVector = material->GetElementVector(); 295 const G4double* theAtomNumDensityVector = 277 const G4double* theAtomNumDensityVector = 296 material->GetVecNbOfAtomsPerVolume(); 278 material->GetVecNbOfAtomsPerVolume(); 297 const std::size_t nelm = material->GetNumber << 279 G4int nelm = material->GetNumberOfElements(); 298 280 299 // loop over deexcitations 281 // loop over deexcitations 300 for(std::size_t i=0; i<nelm; ++i) { << 282 for(G4int i=0; i<nelm; ++i) { 301 G4int Z = (*theElementVector)[i]->GetZasIn 283 G4int Z = (*theElementVector)[i]->GetZasInt(); 302 if(activeZ[Z] && Z < 93) { 284 if(activeZ[Z] && Z < 93) { 303 G4int nshells = 285 G4int nshells = 304 std::min(9,(*theElementVector)[i]->Get 286 std::min(9,(*theElementVector)[i]->GetNbOfAtomicShells()); 305 G4double rho = truelength*theAtomNumDens 287 G4double rho = truelength*theAtomNumDensityVector[i]; 306 //G4cout<<" Z "<< Z <<" is active x(m 288 //G4cout<<" Z "<< Z <<" is active x(mm)= " << truelength/mm << G4endl; 307 for(G4int ii=0; ii<nshells; ++ii) { 289 for(G4int ii=0; ii<nshells; ++ii) { 308 auto as = (G4AtomicShellEnumerator)(ii << 290 G4AtomicShellEnumerator as = G4AtomicShellEnumerator(ii); 309 const G4AtomicShell* shell = GetAtomic 291 const G4AtomicShell* shell = GetAtomicShell(Z, as); 310 const G4double bindingEnergy = shell-> << 292 G4double bindingEnergy = shell->BindingEnergy(); 311 293 312 if(gCut > bindingEnergy) { break; } 294 if(gCut > bindingEnergy) { break; } 313 295 314 if(eLossMax > bindingEnergy) { 296 if(eLossMax > bindingEnergy) { 315 G4double sig = rho* 297 G4double sig = rho* 316 GetShellIonisationCrossSectionPerA 298 GetShellIonisationCrossSectionPerAtom(part, Z, as, ekin, material); 317 299 318 // mfp is mean free path in units of 300 // mfp is mean free path in units of step size 319 if(sig > 0.0) { 301 if(sig > 0.0) { 320 G4double mfp = 1.0/sig; 302 G4double mfp = 1.0/sig; 321 G4double stot = 0.0; 303 G4double stot = 0.0; 322 //G4cout << " Shell " << ii << " m 304 //G4cout << " Shell " << ii << " mfp(mm)= " << mfp/mm << G4endl; 323 // sample ionisation points 305 // sample ionisation points 324 do { 306 do { 325 stot -= mfp*G4Log(G4UniformRand( << 307 stot -= mfp*std::log(G4UniformRand()); 326 if( stot > 1.0 || eLossMax < bin 308 if( stot > 1.0 || eLossMax < bindingEnergy) { break; } 327 // sample deexcitation 309 // sample deexcitation 328 vdyn.clear(); 310 vdyn.clear(); 329 GenerateParticles(&vdyn, shell, 311 GenerateParticles(&vdyn, shell, Z, gCut, eCut); 330 std::size_t nsec = vdyn.size(); << 312 G4int nsec = vdyn.size(); 331 if(nsec > 0) { 313 if(nsec > 0) { 332 G4ThreeVector r = prePos + st 314 G4ThreeVector r = prePos + stot*delta; 333 G4double time = preTime + st 315 G4double time = preTime + stot*dt; 334 for(std::size_t j=0; j<nsec; + << 316 for(G4int j=0; j<nsec; ++j) { 335 G4DynamicParticle* dp = vdyn 317 G4DynamicParticle* dp = vdyn[j]; 336 G4double e = dp->GetKineticE 318 G4double e = dp->GetKineticEnergy(); 337 319 338 // save new secondary if the 320 // save new secondary if there is enough energy 339 if(eLossMax >= e) { 321 if(eLossMax >= e) { 340 eLossMax -= e; 322 eLossMax -= e; 341 G4Track* t = new G4Track(d 323 G4Track* t = new G4Track(dp, time, r); 342 324 343 // defined secondary type 325 // defined secondary type 344 if(dp->GetDefinition() == 326 if(dp->GetDefinition() == gamma) { 345 t->SetCreatorModelID(_Ga << 327 t->SetCreatorModelIndex(pixeIDg); 346 } else { 328 } else { 347 t->SetCreatorModelID(_eP << 329 t->SetCreatorModelIndex(pixeIDe); 348 } 330 } >> 331 349 tracks.push_back(t); 332 tracks.push_back(t); 350 } else { 333 } else { 351 delete dp; 334 delete dp; 352 } 335 } 353 } 336 } 354 } 337 } 355 // Loop checking, 03-Aug-2015, V 338 // Loop checking, 03-Aug-2015, Vladimir Ivanchenko 356 } while (stot < 1.0); 339 } while (stot < 1.0); 357 } 340 } 358 } 341 } 359 } 342 } 360 } 343 } 361 } 344 } 362 return; 345 return; 363 } 346 } 364 347 365 //....oooOO0OOooo........oooOO0OOooo........oo 348 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 366 349