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 // $Id: G4EmCalculator.cc,v 1.33 2006/06/29 19:54:57 gunter Exp $ >> 27 // GEANT4 tag $Name: geant4-08-01-patch-01 $ 26 // 28 // 27 // ------------------------------------------- 29 // ------------------------------------------------------------------- 28 // 30 // 29 // GEANT4 Class file 31 // GEANT4 Class file 30 // 32 // 31 // 33 // 32 // File name: G4EmCalculator 34 // File name: G4EmCalculator 33 // 35 // 34 // Author: Vladimir Ivanchenko 36 // Author: Vladimir Ivanchenko 35 // 37 // 36 // Creation date: 28.06.2004 38 // Creation date: 28.06.2004 37 // 39 // >> 40 // Modifications: >> 41 // 12.09.2004 Add verbosity (V.Ivanchenko) >> 42 // 17.11.2004 Change signature of methods, add new methods (V.Ivanchenko) >> 43 // 08.04.2005 Major optimisation of internal interfaces (V.Ivantchenko) >> 44 // 08.05.2005 Use updated interfaces (V.Ivantchenko) >> 45 // 23.10.2005 Fix computations for ions (V.Ivantchenko) >> 46 // 11.01.2006 Add GetCSDARange (V.Ivantchenko) >> 47 // 26.01.2006 Rename GetRange -> GetRangeFromRestricteDEDX (V.Ivanchenko) >> 48 // 14.03.2006 correction in GetCrossSectionPerVolume (mma) >> 49 // suppress GetCrossSectionPerAtom >> 50 // elm->GetA() in ComputeCrossSectionPerAtom >> 51 // 22.03.2006 Add ComputeElectronicDEDX and ComputeTotalDEDX (V.Ivanchenko) >> 52 // 13.05.2006 Add Corrections for ion stopping (V.Ivanchenko) 38 // 53 // 39 // Class Description: V.Ivanchenko & M.Novak << 54 // Class Description: 40 // 55 // 41 // ------------------------------------------- 56 // ------------------------------------------------------------------- 42 // 57 // 43 //....oooOO0OOooo........oooOO0OOooo........oo 58 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 44 //....oooOO0OOooo........oooOO0OOooo........oo 59 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 45 60 46 #include "G4EmCalculator.hh" 61 #include "G4EmCalculator.hh" 47 #include "G4SystemOfUnits.hh" << 48 #include "G4LossTableManager.hh" 62 #include "G4LossTableManager.hh" 49 #include "G4EmParameters.hh" << 50 #include "G4NistManager.hh" << 51 #include "G4DynamicParticle.hh" << 52 #include "G4VEmProcess.hh" 63 #include "G4VEmProcess.hh" 53 #include "G4VEnergyLossProcess.hh" 64 #include "G4VEnergyLossProcess.hh" 54 #include "G4VMultipleScattering.hh" 65 #include "G4VMultipleScattering.hh" 55 #include "G4Material.hh" 66 #include "G4Material.hh" 56 #include "G4MaterialCutsCouple.hh" 67 #include "G4MaterialCutsCouple.hh" 57 #include "G4ParticleDefinition.hh" 68 #include "G4ParticleDefinition.hh" 58 #include "G4ParticleTable.hh" 69 #include "G4ParticleTable.hh" 59 #include "G4IonTable.hh" << 60 #include "G4PhysicsTable.hh" 70 #include "G4PhysicsTable.hh" 61 #include "G4ProductionCutsTable.hh" 71 #include "G4ProductionCutsTable.hh" 62 #include "G4ProcessManager.hh" 72 #include "G4ProcessManager.hh" 63 #include "G4ionEffectiveCharge.hh" 73 #include "G4ionEffectiveCharge.hh" 64 #include "G4RegionStore.hh" 74 #include "G4RegionStore.hh" 65 #include "G4Element.hh" 75 #include "G4Element.hh" 66 #include "G4EmCorrections.hh" 76 #include "G4EmCorrections.hh" 67 #include "G4GenericIon.hh" 77 #include "G4GenericIon.hh" 68 #include "G4ProcessVector.hh" << 69 #include "G4Gamma.hh" << 70 #include "G4Electron.hh" << 71 #include "G4Positron.hh" << 72 #include "G4EmUtility.hh" << 73 78 74 //....oooOO0OOooo........oooOO0OOooo........oo 79 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 75 80 76 G4EmCalculator::G4EmCalculator() 81 G4EmCalculator::G4EmCalculator() 77 { 82 { 78 manager = G4LossTableManager::Instance(); 83 manager = G4LossTableManager::Instance(); 79 nist = G4NistManager::Instance(); << 80 theParameters = G4EmParameters::Instance(); << 81 corr = manager->EmCorrections(); 84 corr = manager->EmCorrections(); 82 cutenergy[0] = cutenergy[1] = cutenergy[2] = << 85 nLocalMaterials = 0; 83 theGenericIon = G4GenericIon::GenericIon(); << 86 verbose = 0; 84 ionEffCharge = new G4ionEffectiveCharge(); << 87 currentCoupleIndex = 0; 85 dynParticle = new G4DynamicParticle(); << 88 currentCouple = 0; 86 ionTable = G4ParticleTable::GetParticle << 89 currentMaterial = 0; >> 90 currentParticle = 0; >> 91 baseParticle = 0; >> 92 currentLambda = 0; >> 93 chargeSquare = 1.0; >> 94 massRatio = 1.0; >> 95 currentParticleName= ""; >> 96 currentMaterialName= ""; >> 97 theGenericIon = G4GenericIon::GenericIon(); >> 98 ionEffCharge = new G4ionEffectiveCharge(); >> 99 isIon = false; >> 100 isApplicable = false; 87 } 101 } 88 102 89 //....oooOO0OOooo........oooOO0OOooo........oo 103 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 90 104 91 G4EmCalculator::~G4EmCalculator() 105 G4EmCalculator::~G4EmCalculator() 92 { 106 { 93 delete ionEffCharge; 107 delete ionEffCharge; 94 delete dynParticle; << 108 for (G4int i=0; i<nLocalMaterials; i++) { 95 for (G4int i=0; i<nLocalMaterials; ++i) { << 96 delete localCouples[i]; 109 delete localCouples[i]; 97 } 110 } 98 } 111 } 99 112 100 //....oooOO0OOooo........oooOO0OOooo........oo 113 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 101 114 102 G4double G4EmCalculator::GetDEDX(G4double kinE << 115 G4double G4EmCalculator::GetDEDX(G4double kinEnergy, const G4ParticleDefinition* p, 103 const G4Parti << 116 const G4Material* mat, const G4Region* region) 104 const G4Mater << 105 const G4Regio << 106 { 117 { 107 G4double res = 0.0; 118 G4double res = 0.0; 108 const G4MaterialCutsCouple* couple = FindCou 119 const G4MaterialCutsCouple* couple = FindCouple(mat, region); 109 if(nullptr != couple && UpdateParticle(p, ki << 120 if(couple && UpdateParticle(p, kinEnergy) ) { 110 res = manager->GetDEDX(p, kinEnergy, coupl 121 res = manager->GetDEDX(p, kinEnergy, couple); 111 << 112 if(isIon) { << 113 if(FindEmModel(p, currentProcessName, ki << 114 G4double length = CLHEP::nm; << 115 G4double eloss = res*length; << 116 //G4cout << "### GetDEDX: E= " << kinE << 117 // << " de= " << eloss << G4endl << 118 dynParticle->SetKineticEnergy(kinEnerg << 119 currentModel->GetChargeSquareRatio(p, << 120 currentModel->CorrectionsAlongStep(cou << 121 res = eloss/length; << 122 //G4cout << " de1= " << eloss << << 123 // << " " << p->GetParticleName( << 124 } << 125 } << 126 << 127 if(verbose>0) { 122 if(verbose>0) { 128 G4cout << "G4EmCalculator::GetDEDX: E(Me 123 G4cout << "G4EmCalculator::GetDEDX: E(MeV)= " << kinEnergy/MeV 129 << " DEDX(MeV/mm)= " << res*mm/Me << 124 << " DEDX(MeV/mm)= " << res*mm/MeV 130 << " DEDX(MeV*cm^2/g)= " << res*g << 125 << " DEDX(MeV*cm^2/g)= " << res*gram/(MeV*cm2*mat->GetDensity()) 131 << " " << p->GetParticleName() << 126 << " " << p->GetParticleName() 132 << " in " << mat->GetName() << 127 << " in " << mat->GetName() 133 << " isIon= " << isIon << 128 << G4endl; 134 << G4endl; << 135 } 129 } 136 } 130 } 137 return res; 131 return res; 138 } 132 } 139 133 140 //....oooOO0OOooo........oooOO0OOooo........oo 134 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 141 135 >> 136 G4double G4EmCalculator::GetDEDX(G4double kinEnergy, const G4String& particle, >> 137 const G4String& material, const G4String& reg) >> 138 { >> 139 return GetDEDX(kinEnergy,FindParticle(particle), >> 140 FindMaterial(material),FindRegion(reg)); >> 141 } >> 142 >> 143 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... >> 144 142 G4double G4EmCalculator::GetRangeFromRestricte 145 G4double G4EmCalculator::GetRangeFromRestricteDEDX(G4double kinEnergy, 143 << 146 const G4ParticleDefinition* p, 144 << 147 const G4Material* mat, 145 << 148 const G4Region* region) 146 { 149 { 147 G4double res = 0.0; 150 G4double res = 0.0; 148 const G4MaterialCutsCouple* couple = FindCou 151 const G4MaterialCutsCouple* couple = FindCouple(mat,region); 149 if(couple && UpdateParticle(p, kinEnergy)) { 152 if(couple && UpdateParticle(p, kinEnergy)) { 150 res = manager->GetRangeFromRestricteDEDX(p 153 res = manager->GetRangeFromRestricteDEDX(p, kinEnergy, couple); 151 if(verbose>1) { << 154 if(verbose>0) { 152 G4cout << " G4EmCalculator::GetRangeFrom << 155 G4cout << "G4EmCalculator::GetRange: E(MeV)= " << kinEnergy/MeV 153 << kinEnergy/MeV << 156 << " range(mm)= " << res/mm 154 << " range(mm)= " << res/mm << 157 << " " << p->GetParticleName() 155 << " " << p->GetParticleName() << 158 << " in " << mat->GetName() 156 << " in " << mat->GetName() << 159 << G4endl; 157 << G4endl; << 158 } 160 } 159 } 161 } 160 return res; 162 return res; 161 } 163 } 162 164 163 //....oooOO0OOooo........oooOO0OOooo........oo 165 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 164 166 165 G4double G4EmCalculator::GetCSDARange(G4double 167 G4double G4EmCalculator::GetCSDARange(G4double kinEnergy, 166 const G4 << 168 const G4ParticleDefinition* p, 167 const G4 << 169 const G4Material* mat, 168 const G4 << 170 const G4Region* region) 169 { 171 { 170 G4double res = 0.0; 172 G4double res = 0.0; 171 if(!theParameters->BuildCSDARange()) { << 172 G4ExceptionDescription ed; << 173 ed << "G4EmCalculator::GetCSDARange: CSDA << 174 << " use UI command: /process/eLoss/CSD << 175 G4Exception("G4EmCalculator::GetCSDARange" << 176 JustWarning, ed); << 177 return res; << 178 } << 179 << 180 const G4MaterialCutsCouple* couple = FindCou 173 const G4MaterialCutsCouple* couple = FindCouple(mat,region); 181 if(nullptr != couple && UpdateParticle(p, ki << 174 if(couple && UpdateParticle(p, kinEnergy)) { 182 res = manager->GetCSDARange(p, kinEnergy, 175 res = manager->GetCSDARange(p, kinEnergy, couple); 183 if(verbose>1) { << 176 if(verbose>0) { 184 G4cout << " G4EmCalculator::GetCSDARange << 177 G4cout << "G4EmCalculator::GetRange: E(MeV)= " << kinEnergy/MeV 185 << " range(mm)= " << res/mm << 178 << " range(mm)= " << res/mm 186 << " " << p->GetParticleName() << 179 << " " << p->GetParticleName() 187 << " in " << mat->GetName() << 180 << " in " << mat->GetName() 188 << G4endl; << 181 << G4endl; 189 } 182 } 190 } 183 } 191 return res; 184 return res; 192 } 185 } 193 186 194 //....oooOO0OOooo........oooOO0OOooo........oo 187 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 195 188 196 G4double G4EmCalculator::GetRange(G4double kin 189 G4double G4EmCalculator::GetRange(G4double kinEnergy, 197 const G4Part << 190 const G4ParticleDefinition* p, 198 const G4Mate << 191 const G4Material* mat, 199 const G4Regi << 192 const G4Region* region) 200 { 193 { 201 G4double res = 0.0; 194 G4double res = 0.0; 202 if(theParameters->BuildCSDARange()) { << 195 const G4MaterialCutsCouple* couple = FindCouple(mat,region); 203 res = GetCSDARange(kinEnergy, p, mat, regi << 196 if(couple && UpdateParticle(p, kinEnergy)) { 204 } else { << 197 res = manager->GetRange(p, kinEnergy, couple); 205 res = GetRangeFromRestricteDEDX(kinEnergy, << 198 if(verbose>0) { >> 199 G4cout << "G4EmCalculator::GetRange: E(MeV)= " << kinEnergy/MeV >> 200 << " range(mm)= " << res/mm >> 201 << " " << p->GetParticleName() >> 202 << " in " << mat->GetName() >> 203 << G4endl; >> 204 } 206 } 205 } 207 return res; 206 return res; 208 } 207 } 209 208 210 //....oooOO0OOooo........oooOO0OOooo........oo 209 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 211 210 >> 211 G4double G4EmCalculator::GetRangeFromRestricteDEDX(G4double kinEnergy, >> 212 const G4String& particle, >> 213 const G4String& material, >> 214 const G4String& reg) >> 215 { >> 216 return GetRangeFromRestricteDEDX(kinEnergy,FindParticle(particle), >> 217 FindMaterial(material),FindRegion(reg)); >> 218 } >> 219 >> 220 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... >> 221 >> 222 G4double G4EmCalculator::GetCSDARange(G4double kinEnergy, >> 223 const G4String& particle, >> 224 const G4String& material, >> 225 const G4String& reg) >> 226 { >> 227 return GetCSDARange(kinEnergy,FindParticle(particle), >> 228 FindMaterial(material),FindRegion(reg)); >> 229 } >> 230 >> 231 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... >> 232 >> 233 G4double G4EmCalculator::GetRange(G4double kinEnergy, >> 234 const G4String& particle, >> 235 const G4String& material, >> 236 const G4String& reg) >> 237 { >> 238 return GetRange(kinEnergy,FindParticle(particle), >> 239 FindMaterial(material),FindRegion(reg)); >> 240 } >> 241 >> 242 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... >> 243 212 G4double G4EmCalculator::GetKinEnergy(G4double 244 G4double G4EmCalculator::GetKinEnergy(G4double range, 213 const G4 << 245 const G4ParticleDefinition* p, 214 const G4 246 const G4Material* mat, 215 const G4 << 247 const G4Region* region) 216 { 248 { 217 G4double res = 0.0; 249 G4double res = 0.0; 218 const G4MaterialCutsCouple* couple = FindCou 250 const G4MaterialCutsCouple* couple = FindCouple(mat,region); 219 if(nullptr != couple && UpdateParticle(p, 1. << 251 if(couple && UpdateParticle(p, 1.0*GeV)) { 220 res = manager->GetEnergy(p, range, couple) 252 res = manager->GetEnergy(p, range, couple); 221 if(verbose>0) { 253 if(verbose>0) { 222 G4cout << "G4EmCalculator::GetKinEnergy: 254 G4cout << "G4EmCalculator::GetKinEnergy: Range(mm)= " << range/mm 223 << " KinE(MeV)= " << res/MeV << 255 << " KinE(MeV)= " << res/MeV 224 << " " << p->GetParticleName() << 256 << " " << p->GetParticleName() 225 << " in " << mat->GetName() << 257 << " in " << mat->GetName() 226 << G4endl; << 258 << G4endl; 227 } 259 } 228 } 260 } 229 return res; 261 return res; 230 } 262 } 231 263 232 //....oooOO0OOooo........oooOO0OOooo........oo 264 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 233 265 >> 266 G4double G4EmCalculator::GetKinEnergy(G4double range, const G4String& particle, >> 267 const G4String& material, const G4String& reg) >> 268 { >> 269 return GetKinEnergy(range,FindParticle(particle), >> 270 FindMaterial(material),FindRegion(reg)); >> 271 } >> 272 >> 273 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... >> 274 234 G4double G4EmCalculator::GetCrossSectionPerVol 275 G4double G4EmCalculator::GetCrossSectionPerVolume(G4double kinEnergy, 235 co 276 const G4ParticleDefinition* p, 236 co 277 const G4String& processName, 237 co << 278 const G4Material* mat, 238 co << 279 const G4Region* region) 239 { 280 { 240 G4double res = 0.0; 281 G4double res = 0.0; 241 const G4MaterialCutsCouple* couple = FindCou 282 const G4MaterialCutsCouple* couple = FindCouple(mat,region); 242 283 243 if(nullptr != couple && UpdateParticle(p, ki << 284 if(couple && UpdateParticle(p, kinEnergy)) { 244 if(FindEmModel(p, processName, kinEnergy)) << 285 G4int idx = couple->GetIndex(); 245 G4int idx = couple->GetIndex(); << 286 FindLambdaTable(p, processName); 246 G4int procType = -1; << 287 if(currentLambda) { 247 FindLambdaTable(p, processName, kinEnerg << 288 G4bool b; 248 << 289 G4double e = kinEnergy*massRatio; 249 G4VEmProcess* emproc = FindDiscreteProce << 290 res = (((*currentLambda)[idx])->GetValue(e,b))*chargeSquare; 250 if(nullptr != emproc) { << 251 res = emproc->GetCrossSection(kinEnergy, cou << 252 } else if(currentLambda) { << 253 // special tables are built for Msc mo << 254 // procType is set in FindLambdaTable << 255 if(procType==2) { << 256 auto mscM = static_cast<G4VMscModel* << 257 mscM->SetCurrentCouple(couple); << 258 G4double tr1Mfp = mscM->GetTransport << 259 if (tr1Mfp<DBL_MAX) { << 260 res = 1./tr1Mfp; << 261 } << 262 } else { << 263 G4double e = kinEnergy*massRatio; << 264 res = (((*currentLambda)[idx])->Valu << 265 } << 266 } else { << 267 res = ComputeCrossSectionPerVolume(kin << 268 } << 269 if(verbose>0) { 291 if(verbose>0) { 270 G4cout << "G4EmCalculator::GetXSPerVol << 292 G4cout << "E(MeV)= " << kinEnergy/MeV 271 << " cross(cm-1)= " << res*cm << 293 << " cross(cm-1)= " << res*cm 272 << " " << p->GetParticleName( << 294 << " " << p->GetParticleName() 273 << " in " << mat->GetName(); << 295 << " in " << mat->GetName(); 274 if(verbose>1) << 296 if(verbose>1) 275 G4cout << " idx= " << idx << " Esc << 297 G4cout << " idx= " << idx << " e(MeV)= " << e 276 << kinEnergy*massRatio << 298 << " q2= " << chargeSquare; 277 << " q2= " << chargeSquare; << 299 G4cout << G4endl; 278 G4cout << G4endl; << 300 } 279 } << 280 } 301 } 281 } 302 } 282 return res; 303 return res; 283 } 304 } 284 305 285 //....oooOO0OOooo........oooOO0OOooo........oo 306 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 286 307 287 G4double G4EmCalculator::GetShellIonisationCro << 308 G4double G4EmCalculator::GetCrossSectionPerVolume(G4double kinEnergy, 288 const << 309 const G4String& particle, 289 G4int << 310 const G4String& processName, 290 G4Ato << 311 const G4String& material, 291 G4dou << 312 const G4String& reg) 292 { 313 { 293 G4double res = 0.0; << 314 return GetCrossSectionPerVolume(kinEnergy,FindParticle(particle),processName, 294 const G4ParticleDefinition* p = FindParticle << 315 FindMaterial(material),FindRegion(reg)); 295 G4VAtomDeexcitation* ad = manager->AtomDeexc << 296 if(nullptr != p && nullptr != ad) { << 297 res = ad->GetShellIonisationCrossSectionPe << 298 } << 299 return res; << 300 } 316 } 301 317 302 //....oooOO0OOooo........oooOO0OOooo........oo 318 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 303 319 304 G4double G4EmCalculator::GetMeanFreePath(G4dou 320 G4double G4EmCalculator::GetMeanFreePath(G4double kinEnergy, 305 const 321 const G4ParticleDefinition* p, 306 const 322 const G4String& processName, 307 const << 323 const G4Material* mat, 308 const 324 const G4Region* region) 309 { 325 { 310 G4double res = DBL_MAX; 326 G4double res = DBL_MAX; 311 G4double x = GetCrossSectionPerVolume(kinEne 327 G4double x = GetCrossSectionPerVolume(kinEnergy,p, processName, mat,region); 312 if(x > 0.0) { res = 1.0/x; } << 328 if(x > 0.0) res = 1.0/x; 313 if(verbose>1) { 329 if(verbose>1) { 314 G4cout << "G4EmCalculator::GetMeanFreePath 330 G4cout << "G4EmCalculator::GetMeanFreePath: E(MeV)= " << kinEnergy/MeV 315 << " MFP(mm)= " << res/mm << 331 << " MFP(mm)= " << res/mm 316 << " " << p->GetParticleName() << 332 << " " << p->GetParticleName() 317 << " in " << mat->GetName() << 333 << " in " << mat->GetName() 318 << G4endl; << 334 << G4endl; 319 } 335 } 320 return res; 336 return res; 321 } 337 } 322 338 323 //....oooOO0OOooo........oooOO0OOooo........oo 339 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 324 340 >> 341 G4double G4EmCalculator::GetMeanFreePath(G4double kinEnergy, >> 342 const G4String& particle, >> 343 const G4String& processName, >> 344 const G4String& material, >> 345 const G4String& reg) >> 346 { >> 347 return GetMeanFreePath(kinEnergy,FindParticle(particle),processName, >> 348 FindMaterial(material),FindRegion(reg)); >> 349 } >> 350 >> 351 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... >> 352 325 void G4EmCalculator::PrintDEDXTable(const G4Pa 353 void G4EmCalculator::PrintDEDXTable(const G4ParticleDefinition* p) 326 { 354 { 327 const G4VEnergyLossProcess* elp = manager->G << 355 const G4VEnergyLossProcess* elp = FindEnergyLossProcess(p); 328 G4cout << "##### DEDX Table for " << p->GetP 356 G4cout << "##### DEDX Table for " << p->GetParticleName() << G4endl; 329 if(nullptr != elp) G4cout << *(elp->DEDXTabl << 357 if(elp) G4cout << *(elp->DEDXTable()) << G4endl; 330 } 358 } 331 359 332 //....oooOO0OOooo........oooOO0OOooo........oo 360 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 333 361 334 void G4EmCalculator::PrintRangeTable(const G4P 362 void G4EmCalculator::PrintRangeTable(const G4ParticleDefinition* p) 335 { 363 { 336 const G4VEnergyLossProcess* elp = manager->G << 364 const G4VEnergyLossProcess* elp = FindEnergyLossProcess(p); 337 G4cout << "##### Range Table for " << p->Get 365 G4cout << "##### Range Table for " << p->GetParticleName() << G4endl; 338 if(nullptr != elp) G4cout << *(elp->RangeTab << 366 if(elp) G4cout << *(elp->RangeTableForLoss()) << G4endl; 339 } 367 } 340 368 341 //....oooOO0OOooo........oooOO0OOooo........oo 369 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 342 370 343 void G4EmCalculator::PrintInverseRangeTable(co 371 void G4EmCalculator::PrintInverseRangeTable(const G4ParticleDefinition* p) 344 { 372 { 345 const G4VEnergyLossProcess* elp = manager->G << 373 const G4VEnergyLossProcess* elp = FindEnergyLossProcess(p); 346 G4cout << "### G4EmCalculator: Inverse Range 374 G4cout << "### G4EmCalculator: Inverse Range Table for " 347 << p->GetParticleName() << G4endl; << 375 << p->GetParticleName() << G4endl; 348 if(nullptr != elp) G4cout << *(elp->InverseR << 376 if(elp) G4cout << *(elp->InverseRangeTable()) << G4endl; 349 } 377 } 350 378 351 //....oooOO0OOooo........oooOO0OOooo........oo 379 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 352 380 353 G4double G4EmCalculator::ComputeDEDX(G4double 381 G4double G4EmCalculator::ComputeDEDX(G4double kinEnergy, 354 const G4P 382 const G4ParticleDefinition* p, 355 const G4S 383 const G4String& processName, 356 const G4M << 384 const G4Material* mat, 357 G4d 385 G4double cut) 358 { 386 { 359 SetupMaterial(mat); << 387 currentMaterial = mat; >> 388 currentMaterialName = mat->GetName(); 360 G4double res = 0.0; 389 G4double res = 0.0; 361 if(verbose > 1) { 390 if(verbose > 1) { 362 G4cout << "### G4EmCalculator::ComputeDEDX 391 G4cout << "### G4EmCalculator::ComputeDEDX: " << p->GetParticleName() 363 << " in " << currentMaterialName 392 << " in " << currentMaterialName 364 << " e(MeV)= " << kinEnergy/MeV << 393 << " e(MeV)= " << kinEnergy/MeV << " cut(MeV)= " << cut/MeV 365 << G4endl; << 394 << G4endl; 366 } 395 } 367 if(UpdateParticle(p, kinEnergy)) { 396 if(UpdateParticle(p, kinEnergy)) { 368 if(FindEmModel(p, processName, kinEnergy)) 397 if(FindEmModel(p, processName, kinEnergy)) { >> 398 // G4cout << "currentModel= " << currentModel << G4endl; 369 G4double escaled = kinEnergy*massRatio; 399 G4double escaled = kinEnergy*massRatio; 370 if(nullptr != baseParticle) { << 400 if(baseParticle) { 371 res = currentModel->ComputeDEDXPerVolume(mat << 401 res = currentModel->ComputeDEDXPerVolume( 372 << 402 mat, baseParticle, escaled, cut) * chargeSquare; 373 if(verbose > 1) { << 403 if(verbose > 1) 374 G4cout << "Particle: " << p->GetParticleNa << 404 G4cout << baseParticle->GetParticleName() 375 << " E(MeV)=" << kinEnergy << 405 << " Escaled(MeV)= " << escaled; 376 << " Base particle: " << baseParticle->Ge << 377 << " Escaled(MeV)= " << escaled << 378 << " q2=" << chargeSquare << G4endl; << 379 } << 380 } else { 406 } else { 381 res = currentModel->ComputeDEDXPerVolume(mat << 407 res = currentModel->ComputeDEDXPerVolume(mat, p, kinEnergy, cut); 382 if(verbose > 1) { << 408 if(verbose > 1) G4cout << " no basePart E(MeV)= " << kinEnergy; 383 G4cout << "Particle: " << p->GetParticleNa << 384 << " E(MeV)=" << kinEnergy << G4endl; << 385 } << 386 } 409 } 387 if(verbose > 1) { << 410 if(verbose > 1) 388 G4cout << currentModel->GetName() << ": DEDX << 411 G4cout << " DEDX(MeV/mm)= " << res*mm/MeV 389 << " DEDX(MeV*cm^2/g)= " 412 << " DEDX(MeV*cm^2/g)= " 390 << res*gram/(MeV*cm2*mat->GetDensity( 413 << res*gram/(MeV*cm2*mat->GetDensity()) 391 << G4endl; 414 << G4endl; >> 415 >> 416 if(isIon) { >> 417 if(currentModel->HighEnergyLimit() > 100.*MeV) >> 418 res += corr->HighOrderCorrections(p,mat,kinEnergy); >> 419 else >> 420 res *= corr->EffectiveChargeCorrection(p,mat,kinEnergy); >> 421 if(verbose > 1) >> 422 G4cout << "After Corrections: DEDX(MeV/mm)= " << res*mm/MeV >> 423 << " DEDX(MeV*cm^2/g)= " << res*gram/(MeV*cm2*mat->GetDensity()) >> 424 << G4endl; 392 } 425 } 393 // emulate smoothing procedure << 426 394 if(applySmoothing && nullptr != loweMode << 427 /* 395 G4double eth = currentModel->LowEnergyLimit( << 428 // emulate boundary region for different parameterisations 396 G4double res0 = 0.0; << 429 G4double eth = currentModel->LowEnergyLimit(); 397 G4double res1 = 0.0; << 430 if(eth > 0.05*MeV && eth < 10.*MeV && escaled > eth) { 398 if(nullptr != baseParticle) { << 431 G4double res1 = 0.0; 399 res1 = chargeSquare* << 432 if(baseParticle) { 400 currentModel->ComputeDEDXPerVolume(mat, << 433 res1 = currentModel->ComputeDEDXPerVolume(mat, baseParticle, eth, cut) 401 res0 = chargeSquare* << 434 * chargeSquare; 402 loweModel->ComputeDEDXPerVolume(mat, bas << 403 } else { 435 } else { 404 res1 = currentModel->ComputeDEDXPerVolume( 436 res1 = currentModel->ComputeDEDXPerVolume(mat, p, eth, cut); 405 res0 = loweModel->ComputeDEDXPerVolume(mat << 406 } 437 } 407 if(res1 > 0.0 && escaled > 0.0) { << 438 if(verbose > 1) 408 res *= (1.0 + (res0/res1 - 1.0)*eth/escale << 409 } << 410 if(verbose > 1) { << 411 G4cout << "At boundary energy(MeV)= " << e 439 G4cout << "At boundary energy(MeV)= " << eth/MeV 412 << " DEDX(MeV/mm)= " << res0*mm/MeV << " << 440 << " DEDX(MeV/mm)= " << res1*mm/MeV 413 << " after correction DEDX(MeV/mm)=" << r << 441 << G4endl; 414 } << 442 if(isIon) res1 += corr->HighOrderCorrections(p,mat,eth/massRatio); 415 } << 443 G4double res0 = res1; 416 // correction for ions << 444 if(FindEmModel(p, processName, eth-1.0*keV)) { 417 if(isIon) { << 445 if(baseParticle) { 418 const G4double length = CLHEP::nm; << 446 res0 = currentModel->ComputeDEDXPerVolume( 419 if(UpdateCouple(mat, cut)) { << 447 mat, baseParticle, eth, cut) * chargeSquare; 420 G4double eloss = res*length; << 448 } else { 421 dynParticle->SetKineticEnergy(kinEnergy); << 449 res0 = currentModel->ComputeDEDXPerVolume(mat, p, eth, cut); 422 currentModel->CorrectionsAlongStep(current << 450 } 423 l << 424 res = eloss/length; << 425 << 426 if(verbose > 1) { << 427 G4cout << "After Corrections: DEDX(MeV/m << 428 << " DEDX(MeV*cm^2/g)= " << 429 << res*gram/(MeV*cm2*mat->GetDensity()) << 430 } << 431 } 451 } >> 452 //G4cout << "eth= " << eth << " escaled= " << escaled >> 453 // << " res0= " << res0 << " res1= " >> 454 // << res1 << " q2= " << chargeSquare << G4endl; >> 455 res *= (1.0 + (res0/res1 - 1.0)*eth/escaled); 432 } 456 } >> 457 */ 433 if(verbose > 0) { 458 if(verbose > 0) { 434 G4cout << "## E(MeV)= " << kinEnergy/MeV << 459 G4cout << "E(MeV)= " << kinEnergy/MeV 435 << " DEDX(MeV/mm)= " << res*mm/MeV << 460 << " DEDX(MeV/mm)= " << res*mm/MeV 436 << " DEDX(MeV*cm^2/g)= " << res*gram/ << 461 << " DEDX(MeV*cm^2/g)= " << res*gram/(MeV*cm2*mat->GetDensity()) 437 << " cut(MeV)= " << cut/MeV << 462 << " cut(MeV)= " << cut/MeV 438 << " " << p->GetParticleName() << 463 << " " << p->GetParticleName() 439 << " in " << currentMaterialName << 464 << " in " << currentMaterialName 440 << " Zi^2= " << chargeSquare << 465 << " Zi^2= " << chargeSquare 441 << " isIon=" << isIon << 466 << G4endl; 442 << G4endl; << 443 } 467 } 444 } 468 } 445 } 469 } 446 return res; 470 return res; 447 } 471 } 448 472 449 //....oooOO0OOooo........oooOO0OOooo........oo 473 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 450 474 451 G4double G4EmCalculator::ComputeElectronicDEDX 475 G4double G4EmCalculator::ComputeElectronicDEDX(G4double kinEnergy, 452 << 476 const G4ParticleDefinition* part, 453 << 477 const G4Material* mat, 454 << 478 G4double cut) 455 { 479 { 456 SetupMaterial(mat); << 480 currentMaterial = mat; >> 481 currentMaterialName = mat->GetName(); 457 G4double dedx = 0.0; 482 G4double dedx = 0.0; 458 if(UpdateParticle(part, kinEnergy)) { 483 if(UpdateParticle(part, kinEnergy)) { 459 << 460 G4LossTableManager* lManager = G4LossTable 484 G4LossTableManager* lManager = G4LossTableManager::Instance(); 461 const std::vector<G4VEnergyLossProcess*> v 485 const std::vector<G4VEnergyLossProcess*> vel = 462 lManager->GetEnergyLossProcessVector(); 486 lManager->GetEnergyLossProcessVector(); 463 std::size_t n = vel.size(); << 487 G4int n = vel.size(); 464 << 488 for(G4int i=0; i<n; i++) { 465 //G4cout << "ComputeElectronicDEDX for " < << 489 const G4ParticleDefinition* p = (vel[i])->Particle(); 466 // << " n= " << n << G4endl; << 490 if((!isIon && p == part) || (isIon && p == theGenericIon)) 467 << 491 dedx += ComputeDEDX(kinEnergy,part,(vel[i])->GetProcessName(),mat,cut); 468 for(std::size_t i=0; i<n; ++i) { << 469 if(vel[i]) { << 470 auto p = static_cast<G4VProcess*>(vel[ << 471 if(ActiveForParticle(part, p)) { << 472 //G4cout << "idx= " << i << " " << ( << 473 // << " " << (vel[i])->Particle()- << 474 dedx += ComputeDEDX(kinEnergy,part,( << 475 } << 476 } << 477 } 492 } 478 } 493 } 479 return dedx; 494 return dedx; 480 } 495 } 481 496 482 //....oooOO0OOooo........oooOO0OOooo........oo 497 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 483 498 484 G4double << 499 G4double G4EmCalculator::ComputeElectronicDEDX(G4double kinEnergy, const G4String& part, 485 G4EmCalculator::ComputeDEDXForCutInRange(G4dou << 500 const G4String& mat, G4double cut) 486 const << 487 const << 488 G4dou << 489 { 501 { 490 SetupMaterial(mat); << 502 return ComputeElectronicDEDX(kinEnergy,FindParticle(part),FindMaterial(mat),cut); 491 G4double dedx = 0.0; << 503 } 492 if(UpdateParticle(part, kinEnergy)) { << 493 504 494 G4LossTableManager* lManager = G4LossTable << 505 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 495 const std::vector<G4VEnergyLossProcess*> v << 496 lManager->GetEnergyLossProcessVector(); << 497 std::size_t n = vel.size(); << 498 506 499 if(mat != cutMaterial) { << 507 G4double G4EmCalculator::ComputeTotalDEDX(G4double kinEnergy, const G4ParticleDefinition* part, 500 cutMaterial = mat; << 508 const G4Material* mat, G4double cut) 501 cutenergy[0] = << 509 { 502 ComputeEnergyCutFromRangeCut(rangecut, << 510 G4double dedx = ComputeElectronicDEDX(kinEnergy,part,mat,cut); 503 cutenergy[1] = << 511 if(mass > 700.*MeV) dedx += ComputeNuclearDEDX(kinEnergy,part,mat); 504 ComputeEnergyCutFromRangeCut(rangecut, << 512 return dedx; 505 cutenergy[2] = << 513 } 506 ComputeEnergyCutFromRangeCut(rangecut, << 507 } << 508 514 509 //G4cout << "ComputeElectronicDEDX for " < << 515 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 510 // << " n= " << n << G4endl; << 511 << 512 for(std::size_t i=0; i<n; ++i) { << 513 if(vel[i]) { << 514 auto p = static_cast<G4VProcess*>(vel[ << 515 if(ActiveForParticle(part, p)) { << 516 //G4cout << "idx= " << i << " " << ( << 517 // << " " << (vel[i])->Particle()-> << 518 const G4ParticleDefinition* sec = (v << 519 std::size_t idx = 0; << 520 if(sec == G4Electron::Electron()) { << 521 else if(sec == G4Positron::Positron( << 522 516 523 dedx += ComputeDEDX(kinEnergy,part,( << 517 G4double G4EmCalculator::ComputeTotalDEDX(G4double kinEnergy, const G4String& part, 524 mat,cutenergy[id << 518 const G4String& mat, G4double cut) 525 } << 519 { 526 } << 520 return ComputeTotalDEDX(kinEnergy,FindParticle(part),FindMaterial(mat),cut); 527 } << 528 } << 529 return dedx; << 530 } 521 } 531 522 532 //....oooOO0OOooo........oooOO0OOooo........oo 523 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 533 524 534 G4double G4EmCalculator::ComputeTotalDEDX(G4do << 525 G4double G4EmCalculator::ComputeDEDX(G4double kinEnergy, 535 cons << 526 const G4String& particle, 536 cons << 527 const G4String& processName, 537 G4do << 528 const G4String& material, >> 529 G4double cut) 538 { 530 { 539 G4double dedx = ComputeElectronicDEDX(kinEne << 531 return ComputeDEDX(kinEnergy,FindParticle(particle),processName, 540 if(mass > 700.*MeV) { dedx += ComputeNuclear << 532 FindMaterial(material),cut); 541 return dedx; << 542 } 533 } 543 534 544 //....oooOO0OOooo........oooOO0OOooo........oo 535 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 545 536 546 G4double G4EmCalculator::ComputeNuclearDEDX(G4 537 G4double G4EmCalculator::ComputeNuclearDEDX(G4double kinEnergy, 547 const G4 538 const G4ParticleDefinition* p, 548 const G4 << 539 const G4Material* mat) 549 { 540 { 550 G4double res = 0.0; << 541 551 G4VEmProcess* nucst = FindDiscreteProcess(p, << 542 G4double res = corr->NuclearDEDX(p, mat, kinEnergy, false); 552 if(nucst) { << 553 G4VEmModel* mod = nucst->EmModel(); << 554 if(mod) { << 555 mod->SetFluctuationFlag(false); << 556 res = mod->ComputeDEDXPerVolume(mat, p, << 557 } << 558 } << 559 543 560 if(verbose > 1) { 544 if(verbose > 1) { 561 G4cout << p->GetParticleName() << " E(MeV 545 G4cout << p->GetParticleName() << " E(MeV)= " << kinEnergy/MeV 562 << " NuclearDEDX(MeV/mm)= " << res* << 546 << " NuclearDEDX(MeV/mm)= " << res*mm/MeV 563 << " NuclearDEDX(MeV*cm^2/g)= " << 547 << " NuclearDEDX(MeV*cm^2/g)= " 564 << res*gram/(MeV*cm2*mat->GetDensit << 548 << res*gram/(MeV*cm2*mat->GetDensity()) 565 << G4endl; << 549 << G4endl; 566 } 550 } 567 return res; 551 return res; 568 } 552 } 569 553 570 //....oooOO0OOooo........oooOO0OOooo........oo 554 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 571 555 >> 556 G4double G4EmCalculator::ComputeNuclearDEDX(G4double kinEnergy, >> 557 const G4String& particle, >> 558 const G4String& material) >> 559 { >> 560 return ComputeNuclearDEDX(kinEnergy,FindParticle(particle), >> 561 FindMaterial(material)); >> 562 } >> 563 >> 564 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... >> 565 572 G4double G4EmCalculator::ComputeCrossSectionPe 566 G4double G4EmCalculator::ComputeCrossSectionPerVolume( 573 567 G4double kinEnergy, 574 c 568 const G4ParticleDefinition* p, 575 c 569 const G4String& processName, 576 c << 570 const G4Material* mat, 577 571 G4double cut) 578 { 572 { 579 SetupMaterial(mat); << 573 currentMaterial = mat; >> 574 currentMaterialName = mat->GetName(); 580 G4double res = 0.0; 575 G4double res = 0.0; 581 if(UpdateParticle(p, kinEnergy)) { 576 if(UpdateParticle(p, kinEnergy)) { 582 if(FindEmModel(p, processName, kinEnergy)) 577 if(FindEmModel(p, processName, kinEnergy)) { 583 G4double e = kinEnergy; 578 G4double e = kinEnergy; 584 G4double aCut = std::max(cut, theParamet << 585 if(baseParticle) { 579 if(baseParticle) { 586 e *= kinEnergy*massRatio; << 580 e *= kinEnergy*massRatio; 587 res = currentModel->CrossSectionPerVol << 581 res = currentModel->CrossSectionPerVolume( 588 mat, baseParticle, e, aCut, e) * << 582 mat, baseParticle, e, cut, e) * chargeSquare; 589 } else { 583 } else { 590 res = currentModel->CrossSectionPerVol << 584 res = currentModel->CrossSectionPerVolume(mat, p, e, cut, e); 591 } 585 } 592 if(verbose>0) { 586 if(verbose>0) { 593 G4cout << "G4EmCalculator::ComputeXSPe << 587 G4cout << "E(MeV)= " << kinEnergy/MeV 594 << kinEnergy/MeV << 588 << " cross(cm-1)= " << res*cm 595 << " cross(cm-1)= " << res*cm << 589 << " " << p->GetParticleName() 596 << " cut(keV)= " << aCut/keV << 590 << " in " << mat->GetName() 597 << " " << p->GetParticleName( << 591 << G4endl; 598 << " in " << mat->GetName() << 599 << G4endl; << 600 } 592 } 601 } 593 } 602 } 594 } 603 return res; 595 return res; 604 } 596 } 605 597 606 //....oooOO0OOooo........oooOO0OOooo........oo 598 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 607 599 608 G4double << 600 G4double G4EmCalculator::ComputeCrossSectionPerVolume( 609 G4EmCalculator::ComputeCrossSectionPerAtom(G4d << 601 G4double kinEnergy, 610 con << 602 const G4String& particle, 611 con << 603 const G4String& processName, 612 G4d << 604 const G4String& material, 613 G4d << 605 G4double cut) 614 { 606 { 615 G4double res = 0.0; << 607 return ComputeCrossSectionPerVolume(kinEnergy,FindParticle(particle), 616 if(UpdateParticle(p, kinEnergy)) { << 608 processName, 617 G4int iz = G4lrint(Z); << 609 FindMaterial(material),cut); 618 CheckMaterial(iz); << 619 if(FindEmModel(p, processName, kinEnergy)) << 620 G4double e = kinEnergy; << 621 G4double aCut = std::max(cut, theParamet << 622 if(baseParticle) { << 623 e *= kinEnergy*massRatio; << 624 currentModel->InitialiseForElement(bas << 625 res = currentModel->ComputeCrossSectio << 626 baseParticle, e, Z, A, aCut) * c << 627 } else { << 628 currentModel->InitialiseForElement(p, << 629 res = currentModel->ComputeCrossSectio << 630 } << 631 if(verbose>0) { << 632 G4cout << "E(MeV)= " << kinEnergy/MeV << 633 << " cross(barn)= " << res/barn << 634 << " " << p->GetParticleName( << 635 << " Z= " << Z << " A= " << A/ << 636 << " cut(keV)= " << aCut/keV << 637 << G4endl; << 638 } << 639 } << 640 } << 641 return res; << 642 } 610 } 643 611 644 //....oooOO0OOooo........oooOO0OOooo........oo 612 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 645 613 646 G4double << 614 G4double G4EmCalculator::ComputeCrossSectionPerAtom( 647 G4EmCalculator::ComputeCrossSectionPerShell(G4 << 615 G4double kinEnergy, 648 co << 616 const G4ParticleDefinition* p, 649 co << 617 const G4String& processName, 650 G4 << 618 G4double Z, G4double A, 651 G4 << 619 G4double cut) 652 { 620 { 653 G4double res = 0.0; 621 G4double res = 0.0; 654 if(UpdateParticle(p, kinEnergy)) { 622 if(UpdateParticle(p, kinEnergy)) { 655 CheckMaterial(Z); << 656 if(FindEmModel(p, processName, kinEnergy)) 623 if(FindEmModel(p, processName, kinEnergy)) { 657 G4double e = kinEnergy; 624 G4double e = kinEnergy; 658 G4double aCut = std::max(cut, theParamet << 625 if(baseParticle) { 659 if(nullptr != baseParticle) { << 626 e *= kinEnergy*massRatio; 660 e *= kinEnergy*massRatio; << 627 res = currentModel->ComputeCrossSectionPerAtom( 661 currentModel->InitialiseForElement(bas << 628 baseParticle, e, Z, A, cut) * chargeSquare; 662 res = << 663 currentModel->ComputeCrossSectionPer << 664 << 665 } else { 629 } else { 666 currentModel->InitialiseForElement(p, << 630 res = currentModel->ComputeCrossSectionPerAtom(p, e, Z, A, cut); 667 res = currentModel->ComputeCrossSectio << 668 } 631 } 669 if(verbose>0) { 632 if(verbose>0) { 670 G4cout << "E(MeV)= " << kinEnergy/MeV << 633 G4cout << "E(MeV)= " << kinEnergy/MeV 671 << " cross(barn)= " << res/barn << 634 << " cross(barn)= " << res/barn 672 << " " << p->GetParticleName( << 635 << " " << p->GetParticleName() 673 << " Z= " << Z << " shellIdx= << 636 << " Z= " << Z << " A= " << A/(g/mole) << " g/mole" 674 << " cut(keV)= " << aCut/keV << 675 << G4endl; 637 << G4endl; 676 } 638 } 677 } 639 } 678 } 640 } 679 return res; 641 return res; 680 } 642 } 681 643 682 //....oooOO0OOooo........oooOO0OOooo........oo 644 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 683 645 684 G4double << 646 G4double G4EmCalculator::ComputeCrossSectionPerAtom(G4double kinEnergy, 685 G4EmCalculator::ComputeGammaAttenuationLength( << 647 const G4String& particle, 686 << 648 const G4String& processName, 687 { << 649 const G4Element* elm, 688 G4double res = 0.0; << 650 G4double cut) 689 const G4ParticleDefinition* gamma = G4Gamma: << 651 { 690 res += ComputeCrossSectionPerVolume(kinEnerg << 652 return ComputeCrossSectionPerAtom(kinEnergy,FindParticle(particle), 691 res += ComputeCrossSectionPerVolume(kinEnerg << 653 processName, 692 res += ComputeCrossSectionPerVolume(kinEnerg << 654 elm->GetZ(),elm->GetA(),cut); 693 res += ComputeCrossSectionPerVolume(kinEnerg << 694 if(res > 0.0) { res = 1.0/res; } << 695 return res; << 696 } << 697 << 698 //....oooOO0OOooo........oooOO0OOooo........oo << 699 << 700 G4double G4EmCalculator::ComputeShellIonisatio << 701 const << 702 G4int << 703 G4Ato << 704 G4dou << 705 const << 706 { << 707 G4double res = 0.0; << 708 const G4ParticleDefinition* p = FindParticle << 709 G4VAtomDeexcitation* ad = manager->AtomDeexc << 710 if(p && ad) { << 711 res = ad->ComputeShellIonisationCrossSecti << 712 << 713 } << 714 return res; << 715 } 655 } 716 656 717 //....oooOO0OOooo........oooOO0OOooo........oo 657 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 718 658 719 G4double G4EmCalculator::ComputeMeanFreePath(G 659 G4double G4EmCalculator::ComputeMeanFreePath(G4double kinEnergy, 720 c 660 const G4ParticleDefinition* p, 721 c 661 const G4String& processName, 722 c << 662 const G4Material* mat, 723 G << 663 G4double cut) 724 { 664 { 725 G4double mfp = DBL_MAX; 665 G4double mfp = DBL_MAX; 726 G4double x = << 666 G4double x = ComputeCrossSectionPerVolume(kinEnergy, p, processName, mat, cut); 727 ComputeCrossSectionPerVolume(kinEnergy, p, << 667 if(x > 0.0) mfp = 1.0/x; 728 if(x > 0.0) { mfp = 1.0/x; } << 729 if(verbose>1) { 668 if(verbose>1) { 730 G4cout << "E(MeV)= " << kinEnergy/MeV 669 G4cout << "E(MeV)= " << kinEnergy/MeV 731 << " MFP(mm)= " << mfp/mm << 670 << " MFP(mm)= " << mfp/mm 732 << " " << p->GetParticleName() << 671 << " " << p->GetParticleName() 733 << " in " << mat->GetName() << 672 << " in " << mat->GetName() 734 << G4endl; << 673 << G4endl; 735 } 674 } 736 return mfp; 675 return mfp; 737 } 676 } 738 677 739 //....oooOO0OOooo........oooOO0OOooo........oo 678 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 740 679 741 G4double G4EmCalculator::ComputeEnergyCutFromR << 680 G4double G4EmCalculator::ComputeMeanFreePath(G4double kinEnergy, 742 G4double range, << 681 const G4String& particle, 743 const G4ParticleDefin << 682 const G4String& processName, 744 const G4Material* mat << 683 const G4String& material, >> 684 G4double cut) 745 { 685 { 746 return G4ProductionCutsTable::GetProductionC << 686 return ComputeMeanFreePath(kinEnergy,FindParticle(particle),processName, 747 ConvertRangeToEnergy(part, mat, range); << 687 FindMaterial(material),cut); 748 } 688 } 749 689 750 //....oooOO0OOooo........oooOO0OOooo........oo 690 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 751 691 752 G4bool G4EmCalculator::UpdateParticle(const G4 692 G4bool G4EmCalculator::UpdateParticle(const G4ParticleDefinition* p, 753 G4double << 693 G4double kinEnergy) 754 { 694 { 755 if(p != currentParticle) { 695 if(p != currentParticle) { 756 << 757 // new particle << 758 currentParticle = p; 696 currentParticle = p; 759 dynParticle->SetDefinition(const_cast<G4Pa << 697 baseParticle = 0; 760 dynParticle->SetKineticEnergy(kinEnergy); << 761 baseParticle = nullptr; << 762 currentParticleName = p->GetParticleName() 698 currentParticleName = p->GetParticleName(); 763 massRatio = 1.0; 699 massRatio = 1.0; 764 mass = p->GetPDGMass(); 700 mass = p->GetPDGMass(); 765 chargeSquare = 1.0; 701 chargeSquare = 1.0; 766 currentProcess = manager->GetEnergyLossPr << 702 currentProcess = FindEnergyLossProcess(p); 767 currentProcessName = ""; 703 currentProcessName = ""; 768 isIon = false; << 704 if(currentProcess) currentProcessName = currentProcess->GetProcessName(); 769 705 770 // ionisation process exist << 706 if(p->GetParticleType() == "nucleus" && 771 if(nullptr != currentProcess) { << 707 currentParticleName != "deuteron" && currentParticleName != "triton") { 772 currentProcessName = currentProcess->Get << 708 baseParticle = theGenericIon; 773 baseParticle = currentProcess->BaseParti << 709 massRatio = baseParticle->GetPDGMass()/p->GetPDGMass(); 774 if(currentProcessName == "ionIoni" && p- << 710 isIon = true; 775 baseParticle = theGenericIon; << 711 // G4cout << p->GetParticleName() 776 isIon = true; << 712 // << " in " << currentMaterial->GetName() >> 713 // << " e= " << kinEnergy << G4endl; >> 714 chargeSquare = >> 715 ionEffCharge->EffectiveChargeSquareRatio(p, currentMaterial, kinEnergy); >> 716 //G4cout << "q2= " << chargeSquare << G4endl; >> 717 } else { >> 718 isIon = false; >> 719 if(currentProcess) { >> 720 baseParticle = currentProcess->BaseParticle(); >> 721 >> 722 if(baseParticle) { >> 723 massRatio = baseParticle->GetPDGMass()/p->GetPDGMass(); >> 724 G4double q = baseParticle->GetPDGCharge()/eplus; >> 725 chargeSquare /= (q*q); >> 726 } 777 } 727 } 778 << 779 // base particle is used << 780 if(nullptr != baseParticle) { << 781 massRatio = baseParticle->GetPDGMass() << 782 G4double q = p->GetPDGCharge()/basePar << 783 chargeSquare = q*q; << 784 } << 785 } 728 } 786 } 729 } 787 // Effective charge for ions << 730 if(isIon) { 788 if(isIon && nullptr != currentProcess) { << 789 chargeSquare = 731 chargeSquare = 790 corr->EffectiveChargeSquareRatio(p, curr << 732 ionEffCharge->EffectiveChargeSquareRatio(p, currentMaterial, kinEnergy); 791 currentProcess->SetDynamicMassCharge(massR << 733 if(currentProcess) 792 if(verbose>1) { << 734 currentProcess->SetDynamicMassCharge(massRatio,chargeSquare); 793 G4cout <<"\n NewIon: massR= "<< massRati << 735 // G4cout << "massR= " << massRatio << " q2= " << chargeSquare << G4endl; 794 << chargeSquare << " " << currentProce << 795 } << 796 } 736 } 797 return true; 737 return true; 798 } 738 } 799 739 800 //....oooOO0OOooo........oooOO0OOooo........oo 740 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 801 741 802 const G4ParticleDefinition* G4EmCalculator::Fi 742 const G4ParticleDefinition* G4EmCalculator::FindParticle(const G4String& name) 803 { 743 { 804 const G4ParticleDefinition* p = nullptr; << 744 const G4ParticleDefinition* p = 0; 805 if(name != currentParticleName) { 745 if(name != currentParticleName) { 806 p = G4ParticleTable::GetParticleTable()->F 746 p = G4ParticleTable::GetParticleTable()->FindParticle(name); 807 if(nullptr == p) { << 747 if(!p) { 808 G4cout << "### WARNING: G4EmCalculator:: 748 G4cout << "### WARNING: G4EmCalculator::FindParticle fails to find " 809 << name << G4endl; << 749 << name << G4endl; 810 } 750 } 811 } else { 751 } else { 812 p = currentParticle; 752 p = currentParticle; 813 } 753 } 814 return p; 754 return p; 815 } 755 } 816 756 817 //....oooOO0OOooo........oooOO0OOooo........oo 757 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 818 758 819 const G4ParticleDefinition* G4EmCalculator::Fi << 820 { << 821 const G4ParticleDefinition* p = ionTable->Ge << 822 return p; << 823 } << 824 << 825 //....oooOO0OOooo........oooOO0OOooo........oo << 826 << 827 const G4Material* G4EmCalculator::FindMaterial 759 const G4Material* G4EmCalculator::FindMaterial(const G4String& name) 828 { 760 { 829 if(name != currentMaterialName) { 761 if(name != currentMaterialName) { 830 SetupMaterial(G4Material::GetMaterial(name << 762 currentMaterial = G4Material::GetMaterial(name); 831 if(nullptr == currentMaterial) { << 763 currentMaterialName = name; >> 764 if(!currentMaterial) 832 G4cout << "### WARNING: G4EmCalculator:: 765 G4cout << "### WARNING: G4EmCalculator::FindMaterial fails to find " 833 << name << G4endl; << 766 << name << G4endl; 834 } << 835 } 767 } 836 return currentMaterial; 768 return currentMaterial; 837 } 769 } 838 770 839 //....oooOO0OOooo........oooOO0OOooo........oo 771 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 840 772 841 const G4Region* G4EmCalculator::FindRegion(con 773 const G4Region* G4EmCalculator::FindRegion(const G4String& reg) 842 { 774 { 843 return G4EmUtility::FindRegion(reg); << 775 return G4RegionStore::GetInstance()->GetRegion(reg); 844 } 776 } 845 777 846 //....oooOO0OOooo........oooOO0OOooo........oo 778 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 847 779 848 const G4MaterialCutsCouple* G4EmCalculator::Fi 780 const G4MaterialCutsCouple* G4EmCalculator::FindCouple( 849 const G4Material* << 781 const G4Material* material, 850 const G4Region* re << 782 const G4Region* region) 851 { 783 { 852 const G4MaterialCutsCouple* couple = nullptr << 784 if(!material) return 0; 853 SetupMaterial(material); << 785 currentMaterial = material; 854 if(nullptr != currentMaterial) { << 786 currentMaterialName = material->GetName(); 855 // Access to materials << 787 // Access to materials 856 const G4ProductionCutsTable* theCoupleTabl << 788 const G4ProductionCutsTable* theCoupleTable= 857 G4ProductionCutsTable::GetProductionCuts << 789 G4ProductionCutsTable::GetProductionCutsTable(); 858 const G4Region* r = region; << 790 const G4Region* r = region; 859 if(nullptr != r) { << 791 if(!r) 860 couple = theCoupleTable->GetMaterialCuts << 792 r = G4RegionStore::GetInstance()->GetRegion("DefaultRegionForTheWorld"); 861 << 793 862 } else { << 794 return theCoupleTable->GetMaterialCutsCouple(material,r->GetProductionCuts()); 863 G4RegionStore* store = G4RegionStore::Ge << 795 864 std::size_t nr = store->size(); << 865 if(0 < nr) { << 866 for(std::size_t i=0; i<nr; ++i) { << 867 couple = theCoupleTable->GetMaterial << 868 material, ((*store)[i])->GetProduc << 869 if(nullptr != couple) { break; } << 870 } << 871 } << 872 } << 873 } << 874 if(nullptr == couple) { << 875 G4ExceptionDescription ed; << 876 ed << "G4EmCalculator::FindCouple: fail fo << 877 << currentMaterialName << ">"; << 878 if(region) { ed << " and region " << regio << 879 G4Exception("G4EmCalculator::FindCouple", << 880 FatalException, ed); << 881 } << 882 return couple; << 883 } 796 } 884 797 885 //....oooOO0OOooo........oooOO0OOooo........oo 798 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 886 799 887 G4bool G4EmCalculator::UpdateCouple(const G4Ma 800 G4bool G4EmCalculator::UpdateCouple(const G4Material* material, G4double cut) 888 { 801 { 889 SetupMaterial(material); << 802 if(!material) return false; 890 if(!currentMaterial) { return false; } << 803 currentMaterial = material; 891 for (G4int i=0; i<nLocalMaterials; ++i) { << 804 currentMaterialName = material->GetName(); >> 805 for (G4int i=0; i<nLocalMaterials; i++) { 892 if(material == localMaterials[i] && cut == 806 if(material == localMaterials[i] && cut == localCuts[i]) { 893 currentCouple = localCouples[i]; 807 currentCouple = localCouples[i]; 894 currentCoupleIndex = currentCouple->GetI 808 currentCoupleIndex = currentCouple->GetIndex(); 895 currentCut = cut; 809 currentCut = cut; 896 return true; 810 return true; 897 } 811 } 898 } 812 } 899 const G4MaterialCutsCouple* cc = new G4Mater 813 const G4MaterialCutsCouple* cc = new G4MaterialCutsCouple(material); 900 localMaterials.push_back(material); 814 localMaterials.push_back(material); 901 localCouples.push_back(cc); 815 localCouples.push_back(cc); 902 localCuts.push_back(cut); 816 localCuts.push_back(cut); 903 ++nLocalMaterials; << 817 nLocalMaterials++; 904 currentCouple = cc; 818 currentCouple = cc; 905 currentCoupleIndex = currentCouple->GetIndex 819 currentCoupleIndex = currentCouple->GetIndex(); 906 currentCut = cut; 820 currentCut = cut; 907 return true; 821 return true; 908 } 822 } 909 823 910 //....oooOO0OOooo........oooOO0OOooo........oo 824 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 911 825 912 void G4EmCalculator::FindLambdaTable(const G4P 826 void G4EmCalculator::FindLambdaTable(const G4ParticleDefinition* p, 913 const G4S << 827 const G4String& processName) 914 G4double << 915 { 828 { 916 // Search for the process 829 // Search for the process 917 if (!currentLambda || p != lambdaParticle || << 830 if (p != currentParticle || processName != currentName) { 918 lambdaName = processName; << 831 currentName = processName; 919 currentLambda = nullptr; << 832 currentLambda = 0; 920 lambdaParticle = p; << 833 921 isApplicable = false; << 834 G4String partname = p->GetParticleName(); 922 << 835 const G4ParticleDefinition* part = p; 923 const G4ParticleDefinition* part = (isIon) << 836 if(isIon) part = theGenericIon; 924 << 925 // Search for energy loss process << 926 currentName = processName; << 927 currentModel = nullptr; << 928 loweModel = nullptr; << 929 << 930 G4VEnergyLossProcess* elproc = FindEnLossP << 931 if(nullptr != elproc) { << 932 currentLambda = elproc->LambdaTable(); << 933 proctype = 0; << 934 if(nullptr != currentLambda) { << 935 isApplicable = true; << 936 if(verbose>1) { << 937 G4cout << "G4VEnergyLossProcess is f << 938 << G4endl; << 939 } << 940 } << 941 curProcess = elproc; << 942 return; << 943 } << 944 837 945 // Search for discrete process << 838 G4LossTableManager* lManager = G4LossTableManager::Instance(); 946 G4VEmProcess* proc = FindDiscreteProcess(p << 839 const std::vector<G4VEnergyLossProcess*> vel = 947 if(nullptr != proc) { << 840 lManager->GetEnergyLossProcessVector(); 948 currentLambda = proc->LambdaTable(); << 841 G4int n = vel.size(); 949 proctype = 1; << 842 for(G4int i=0; i<n; i++) { 950 if(nullptr != currentLambda) { << 843 if((vel[i])->GetProcessName() == currentName && 951 isApplicable = true; << 844 (vel[i])->Particle() == part) 952 if(verbose>1) { << 845 { 953 G4cout << "G4VEmProcess is found out << 846 currentLambda = (vel[i])->LambdaTable(); >> 847 isApplicable = true; >> 848 break; >> 849 } >> 850 } >> 851 if(!currentLambda) { >> 852 const std::vector<G4VEmProcess*> vem = lManager->GetEmProcessVector(); >> 853 G4int n = vem.size(); >> 854 for(G4int i=0; i<n; i++) { >> 855 if((vem[i])->GetProcessName() == currentName && >> 856 (vem[i])->Particle() == part) >> 857 { >> 858 currentLambda = (vem[i])->LambdaTable(); >> 859 isApplicable = true; >> 860 break; 954 } 861 } 955 } 862 } 956 curProcess = proc; << 957 return; << 958 } 863 } 959 << 864 if(!currentLambda) { 960 // Search for msc process << 865 const std::vector<G4VMultipleScattering*> vmsc = 961 G4VMultipleScattering* msc = FindMscProces << 866 lManager->GetMultipleScatteringVector(); 962 if(nullptr != msc) { << 867 G4int n = vmsc.size(); 963 currentModel = msc->SelectModel(kinEnerg << 868 for(G4int i=0; i<n; i++) { 964 proctype = 2; << 869 if((vmsc[i])->GetProcessName() == currentName && 965 if(nullptr != currentModel) { << 870 (vmsc[i])->Particle() == part) 966 currentLambda = currentModel->GetCross << 871 { 967 if(nullptr != currentLambda) { << 872 currentLambda = (vmsc[i])->LambdaTable(); 968 isApplicable = true; << 873 isApplicable = true; 969 if(verbose>1) { << 874 break; 970 G4cout << "G4VMultipleScattering i << 971 << G4endl; << 972 } << 973 } 875 } 974 } 876 } 975 curProcess = msc; << 976 } 877 } 977 } 878 } 978 } 879 } 979 880 980 //....oooOO0OOooo........oooOO0OOooo........oo 881 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 981 882 982 G4bool G4EmCalculator::FindEmModel(const G4Par 883 G4bool G4EmCalculator::FindEmModel(const G4ParticleDefinition* p, 983 const G4Str 884 const G4String& processName, 984 G4 << 885 G4double kinEnergy) 985 { 886 { 986 isApplicable = false; << 887 G4bool res = false; 987 if(nullptr == p || nullptr == currentMateria << 888 if(!p) { 988 G4cout << "G4EmCalculator::FindEmModel WAR << 889 G4cout << "G4EmCalculator::FindEmModel WARNING: no particle defined" 989 << " or materail defined; particle: << 890 << G4endl; 990 return isApplicable; << 891 return res; 991 } 892 } 992 G4String partname = p->GetParticleName(); 893 G4String partname = p->GetParticleName(); >> 894 const G4ParticleDefinition* part = p; 993 G4double scaledEnergy = kinEnergy*massRatio; 895 G4double scaledEnergy = kinEnergy*massRatio; 994 const G4ParticleDefinition* part = (isIon) ? << 896 if(isIon) part = theGenericIon; 995 897 996 if(verbose > 1) { 898 if(verbose > 1) { 997 G4cout << "## G4EmCalculator::FindEmModel << 899 G4cout << "G4EmCalculator::FindEmModel for " << partname 998 << " (type= " << p->GetParticleType 900 << " (type= " << p->GetParticleType() 999 << ") and " << processName << " at << 901 << ") and " << processName << " at e(MeV)= " << scaledEnergy; 1000 << G4endl; << 902 if(p != part) G4cout << " GenericIon is the base particle"; 1001 if(p != part) { G4cout << " GenericIon i << 903 G4cout << G4endl; 1002 } 904 } 1003 905 1004 // Search for energy loss process << 906 // Search for the process 1005 currentName = processName; 907 currentName = processName; 1006 currentModel = nullptr; << 908 currentModel = 0; 1007 loweModel = nullptr; << 909 size_t idx = 0; 1008 std::size_t idx = 0; << 910 G4LossTableManager* lManager = G4LossTableManager::Instance(); 1009 << 911 const std::vector<G4VEnergyLossProcess*> vel = 1010 G4VEnergyLossProcess* elproc = FindEnLossPr << 912 lManager->GetEnergyLossProcessVector(); 1011 if(nullptr != elproc) { << 913 G4int n = vel.size(); 1012 currentModel = elproc->SelectModelForMate << 914 for(G4int i=0; i<n; i++) { 1013 currentModel->InitialiseForMaterial(part, << 915 // G4cout << "i= " << i << " part= " 1014 currentModel->SetupForMaterial(part, curr << 916 // << (vel[i])->Particle()->GetParticleName() 1015 G4double eth = currentModel->LowEnergyLim << 917 // << " proc= " << (vel[i])->GetProcessName() << G4endl; 1016 if(eth > 0.0) { << 918 if((vel[i])->GetProcessName() == currentName && 1017 loweModel = elproc->SelectModelForMater << 919 (vel[i])->Particle() == part) 1018 if(loweModel == currentModel) { loweMod << 920 { 1019 else { << 921 const G4ParticleDefinition* bp = (vel[i])->BaseParticle(); 1020 loweModel->InitialiseForMaterial(part << 922 // G4cout << "i= " << i << " bp= " << bp << G4endl; 1021 loweModel->SetupForMaterial(part, cur << 923 if(!bp) { 1022 } << 924 currentModel = (vel[i])->SelectModelForMaterial(scaledEnergy, idx); 1023 } << 925 isApplicable = true; 1024 } << 1025 << 1026 // Search for discrete process << 1027 if(nullptr == currentModel) { << 1028 G4VEmProcess* proc = FindDiscreteProcess( << 1029 if(nullptr != proc) { << 1030 currentModel = proc->SelectModelForMate << 1031 currentModel->InitialiseForMaterial(par << 1032 currentModel->SetupForMaterial(part, cu << 1033 G4double eth = currentModel->LowEnergyL << 1034 if(eth > 0.0) { << 1035 loweModel = proc->SelectModelForMater << 1036 if(loweModel == currentModel) { loweM << 1037 else { << 1038 loweModel->InitialiseForMaterial(pa << 1039 loweModel->SetupForMaterial(part, c << 1040 } << 1041 } << 1042 } << 1043 } << 1044 << 1045 // Search for msc process << 1046 if(nullptr == currentModel) { << 1047 G4VMultipleScattering* proc = FindMscProc << 1048 if(nullptr != proc) { << 1049 currentModel = proc->SelectModel(kinEne << 1050 loweModel = nullptr; << 1051 } << 1052 } << 1053 if(nullptr != currentModel) { << 1054 if(loweModel == currentModel) { loweModel << 1055 isApplicable = true; << 1056 currentModel->InitialiseForMaterial(part, << 1057 if(loweModel) { << 1058 loweModel->InitialiseForMaterial(part, << 1059 } << 1060 if(verbose > 1) { << 1061 G4cout << " Model <" << currentModel- << 1062 << "> Emin(MeV)= " << currentMod << 1063 << " for " << part->GetParticleN << 1064 if(nullptr != elproc) { << 1065 G4cout << " and " << elproc->GetProce << 1066 << G4endl; << 1067 } << 1068 if(nullptr != loweModel) { << 1069 G4cout << " LowEnergy model <" << low << 1070 } << 1071 G4cout << G4endl; << 1072 } << 1073 } << 1074 return isApplicable; << 1075 } << 1076 << 1077 //....oooOO0OOooo........oooOO0OOooo........o << 1078 << 1079 G4VEnergyLossProcess* << 1080 G4EmCalculator::FindEnLossProcess(const G4Par << 1081 const G4Str << 1082 { << 1083 G4VEnergyLossProcess* proc = nullptr; << 1084 const std::vector<G4VEnergyLossProcess*> v << 1085 manager->GetEnergyLossProcessVector(); << 1086 std::size_t n = v.size(); << 1087 for(std::size_t i=0; i<n; ++i) { << 1088 if((v[i])->GetProcessName() == processNam << 1089 auto p = static_cast<G4VProcess*>(v[i]) << 1090 if(ActiveForParticle(part, p)) { << 1091 proc = v[i]; << 1092 break; 926 break; >> 927 } else { >> 928 for(G4int j=0; j<n; j++) { >> 929 if((vel[j])->Particle() == bp) { >> 930 currentModel = (vel[j])->SelectModelForMaterial(scaledEnergy, idx); >> 931 isApplicable = true; >> 932 break; >> 933 } >> 934 } 1093 } 935 } 1094 } 936 } 1095 } 937 } 1096 return proc; << 938 if(!currentModel) { 1097 } << 939 const std::vector<G4VEmProcess*> vem = lManager->GetEmProcessVector(); 1098 << 940 G4int n = vem.size(); 1099 //....oooOO0OOooo........oooOO0OOooo........o << 941 for(G4int i=0; i<n; i++) { 1100 << 942 if((vem[i])->GetProcessName() == currentName && 1101 G4VEmProcess* << 943 (vem[i])->Particle() == part) 1102 G4EmCalculator::FindDiscreteProcess(const G4P << 944 { 1103 const G4S << 945 currentModel = (vem[i])->SelectModelForMaterial(kinEnergy, idx); 1104 { << 946 isApplicable = true; 1105 G4VEmProcess* proc = nullptr; << 1106 auto v = manager->GetEmProcessVector(); << 1107 std::size_t n = v.size(); << 1108 for(std::size_t i=0; i<n; ++i) { << 1109 const G4String& pName = v[i]->GetProcessN << 1110 if(pName == "GammaGeneralProc") { << 1111 proc = v[i]->GetEmProcess(processName); << 1112 break; << 1113 } else if(pName == processName) { << 1114 const auto p = static_cast<G4VProcess*> << 1115 if(ActiveForParticle(part, p)) { << 1116 proc = v[i]; << 1117 break; 947 break; 1118 } 948 } 1119 } 949 } 1120 } 950 } 1121 return proc; << 951 if(!currentModel) { 1122 } << 952 const std::vector<G4VMultipleScattering*> vmsc = 1123 << 953 lManager->GetMultipleScatteringVector(); 1124 //....oooOO0OOooo........oooOO0OOooo........o << 954 G4int n = vmsc.size(); 1125 << 955 for(G4int i=0; i<n; i++) { 1126 G4VMultipleScattering* << 956 if((vmsc[i])->GetProcessName() == currentName && 1127 G4EmCalculator::FindMscProcess(const G4Partic << 957 (vmsc[i])->Particle() == part) 1128 const G4String << 958 { 1129 { << 959 currentModel = (vmsc[i])->SelectModelForMaterial(kinEnergy, idx); 1130 G4VMultipleScattering* proc = nullptr; << 960 isApplicable = true; 1131 const std::vector<G4VMultipleScattering*> v << 1132 manager->GetMultipleScatteringVector(); << 1133 std::size_t n = v.size(); << 1134 for(std::size_t i=0; i<n; ++i) { << 1135 if((v[i])->GetProcessName() == processNam << 1136 auto p = static_cast<G4VProcess*>(v[i]) << 1137 if(ActiveForParticle(part, p)) { << 1138 proc = v[i]; << 1139 break; 961 break; 1140 } 962 } 1141 } 963 } 1142 } 964 } 1143 return proc; << 965 if(currentModel) res = true; 1144 } << 1145 << 1146 //....oooOO0OOooo........oooOO0OOooo........o << 1147 << 1148 G4VProcess* G4EmCalculator::FindProcess(const << 1149 const << 1150 { << 1151 G4VProcess* proc = nullptr; << 1152 const G4ProcessManager* procman = part->Get << 1153 G4ProcessVector* pv = procman->GetProcessLi << 1154 G4int nproc = (G4int)pv->size(); << 1155 for(G4int i=0; i<nproc; ++i) { << 1156 if(processName == (*pv)[i]->GetProcessNam << 1157 proc = (*pv)[i]; << 1158 break; << 1159 } << 1160 } << 1161 return proc; << 1162 } << 1163 << 1164 //....oooOO0OOooo........oooOO0OOooo........o << 1165 << 1166 G4bool G4EmCalculator::ActiveForParticle(cons << 1167 G4VP << 1168 { << 1169 G4ProcessManager* pm = part->GetProcessMana << 1170 G4ProcessVector* pv = pm->GetProcessList(); << 1171 G4int n = (G4int)pv->size(); << 1172 G4bool res = false; << 1173 for(G4int i=0; i<n; ++i) { << 1174 if((*pv)[i] == proc) { << 1175 if(pm->GetProcessActivation(i)) { res = << 1176 break; << 1177 } << 1178 } << 1179 return res; 966 return res; 1180 } 967 } 1181 968 1182 //....oooOO0OOooo........oooOO0OOooo........o 969 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 1183 970 1184 void G4EmCalculator::SetupMaterial(const G4Ma << 971 G4VEnergyLossProcess* G4EmCalculator::FindEnergyLossProcess( >> 972 const G4ParticleDefinition* p) 1185 { 973 { 1186 if(mat) { << 974 G4VEnergyLossProcess* elp = 0; 1187 currentMaterial = mat; << 975 G4String partname = p->GetParticleName(); 1188 currentMaterialName = mat->GetName(); << 976 const G4ParticleDefinition* part = p; 1189 } else { << 977 if(p->GetParticleType() == "nucleus" && 1190 currentMaterial = nullptr; << 978 partname != "deuteron" && 1191 currentMaterialName = ""; << 979 partname != "triton") part = G4GenericIon::GenericIon(); 1192 } << 980 1193 } << 981 G4LossTableManager* lManager = G4LossTableManager::Instance(); 1194 << 982 const std::vector<G4VEnergyLossProcess*> vel = 1195 //....oooOO0OOooo........oooOO0OOooo........o << 983 lManager->GetEnergyLossProcessVector(); 1196 << 984 G4int n = vel.size(); 1197 void G4EmCalculator::SetupMaterial(const G4St << 985 for(G4int i=0; i<n; i++) { 1198 { << 986 if((vel[i])->Particle() == part) { 1199 SetupMaterial(nist->FindOrBuildMaterial(mna << 987 elp = vel[i]; 1200 } << 988 break; 1201 << 1202 //....oooOO0OOooo........oooOO0OOooo........o << 1203 << 1204 void G4EmCalculator::CheckMaterial(G4int Z) << 1205 { << 1206 G4bool isFound = false; << 1207 if(nullptr != currentMaterial) { << 1208 G4int nn = (G4int)currentMaterial->GetNum << 1209 for(G4int i=0; i<nn; ++i) { << 1210 if(Z == currentMaterial->GetElement(i)- << 1211 isFound = true; << 1212 break; << 1213 } << 1214 } 989 } 1215 } 990 } 1216 if(!isFound) { << 991 return elp; 1217 SetupMaterial(nist->FindOrBuildSimpleMate << 1218 } << 1219 } 992 } 1220 993 1221 //....oooOO0OOooo........oooOO0OOooo........o 994 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 1222 995 1223 void G4EmCalculator::SetVerbose(G4int verb) 996 void G4EmCalculator::SetVerbose(G4int verb) 1224 { 997 { 1225 verbose = verb; 998 verbose = verb; 1226 } 999 } 1227 1000 1228 //....oooOO0OOooo........oooOO0OOooo........o 1001 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo.... 1229 1002 1230 1003