// // ******************************************************************** // * License and Disclaimer * // * * // * The Geant4 software is copyright of the Copyright Holders of * // * the Geant4 Collaboration. It is provided under the terms and * // * conditions of the Geant4 Software License, included in the file * // * LICENSE and available at http://cern.ch/geant4/license . These * // * include a list of copyright holders. * // * * // * Neither the authors of this software system, nor their employing * // * institutes,nor the agencies providing financial support for this * // * work make any representation or warranty, express or implied, * // * regarding this software system or assume any liability for its * // * use. Please see the license in the file LICENSE and URL above * // * for the full disclaimer and the limitation of liability. * // * * // * This code implementation is the result of the scientific and * // * technical work of the GEANT4 collaboration. * // * By using, copying, modifying or distributing the software (or * // * any work based on the software) you agree to acknowledge its * // * use in resulting scientific publications, and indicate your * // * acceptance of all terms of the Geant4 Software license. * // ******************************************************************** // // // $Id: G4IonTable.cc,v 1.60 2009/09/23 12:13:48 kurasige Exp $ // GEANT4 tag $Name: geant4-09-03-cand-01 $ // // // -------------------------------------------------------------- // GEANT 4 class implementation file // // History: first implementation, based on object model of // 27 June 1998 H.Kurashige // --------------------------------------------------------------- // modified GetIon 02 Aug., 98 H.Kurashige // added Remove() 06 Nov.,98 H.Kurashige // use G4NucleiPropoerties to get nuceli Mass 17 Nov.,98 H.Kurashige // use G4GenericIon for process List // modify fomula of Ion mass 09 Dec., 98 H.Kurashige // ----- // Modified GetIon methods 17 Aug. 99 H.Kurashige // New design using G4VIsotopeTable 5 Oct. 99 H.Kurashige // Modified Element Name for Z>103 06 Apr. 01 H.Kurashige // Remove test of cuts in SetCuts 16 Jan 03 V.Ivanchenko #include "G4IonTable.hh" #include "G4ParticleTable.hh" #include "G4StateManager.hh" #include "G4Ions.hh" #include "G4UImanager.hh" #include "G4NucleiProperties.hh" #include "G4HyperNucleiProperties.hh" #include "G4IsotopeProperty.hh" #include "G4VIsotopeTable.hh" #include "G4ios.hh" #include #include #include //////////////////// G4IonTable::G4IonTable() { fIonList = new G4IonList(); fIsotopeTableList = new std::vector; } //////////////////// G4IonTable::~G4IonTable() { // delete IsotopeTable if exists if (fIsotopeTableList != 0) { for (size_t i = 0; i< fIsotopeTableList->size(); ++i) { G4VIsotopeTable* fIsotopeTable= (*fIsotopeTableList)[i]; delete fIsotopeTable; } fIsotopeTableList->clear(); delete fIsotopeTableList; } fIsotopeTableList =0; if (fIonList ==0) return; // remove all contents in the Ion List // No need to delete here because all particles are dynamic objects fIonList->clear(); delete fIonList; fIonList =0; } //////////////////// // -- CreateIon method ------ //////////////////// G4ParticleDefinition* G4IonTable::CreateIon(G4int Z, G4int A, G4double E, G4int J) { G4ParticleDefinition* ion=0; // check whether the cuurent state is not "PreInit" // to make sure that GenericIon has processes G4ApplicationState currentState = G4StateManager::GetStateManager()->GetCurrentState(); if (currentState == G4State_PreInit){ #ifdef G4VERBOSE if (GetVerboseLevel()>1) { G4cout << "G4IonTable::CreateIon() : can not create ion of "; G4cout << " Z =" << Z << " A = " << A << G4endl; G4cout << " because the current state is PreInit !!" << G4endl; } #endif G4Exception( "G4IonTable::CreateIon()","Illegal operation", JustWarning, "Can not create ions in PreInit state"); return 0; } // get ion name G4String name = GetIonName(Z, A, E); if ( name(0) == '?') { #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::CreateIon() : can not create ions " << G4endl; G4cout << " Z =" << Z << " A = " << A << G4endl; } #endif return 0; } G4double life = -1.0; G4DecayTable* decayTable =0; G4bool stable = true; G4double mu = 0.0; const G4IsotopeProperty* fProperty = FindIsotope(Z, A, E, J); if (fProperty !=0 ){ E = fProperty->GetEnergy(); J = fProperty->GetiSpin(); life = fProperty->GetLifeTime(); mu = fProperty->GetMagneticMoment(); decayTable = fProperty->GetDecayTable(); } stable = life <= 0.; G4double mass = GetNucleusMass(Z, A)+ E; G4double charge = G4double(Z)*eplus; G4int encoding = GetNucleusEncoding(Z,A,E,J); // create an ion // spin, parity, isospin values are fixed // ion = new G4Ions( name, mass, 0.0*MeV, charge, J, +1, 0, 0, 0, 0, "nucleus", 0, A, encoding, stable, life, decayTable, false, "generic", 0, E ); ion->SetPDGMagneticMoment(mu); //No Anti particle registered ion->SetAntiPDGEncoding(0); #ifdef G4VERBOSE if (GetVerboseLevel()>1) { G4cout << "G4IonTable::CreateIon() : create ion of " << name << " " << Z << ", " << A << " encoding=" << encoding << G4endl; } #endif // Add process manager to the ion AddProcessManager(name); return ion; } //////////////////// G4ParticleDefinition* G4IonTable::CreateIon(G4int Z, G4int A, G4int L, G4double E, G4int J) { if (L==0) return CreateIon(A,Z,E,J); // create hyper nucleus G4ParticleDefinition* ion=0; // check whether the cuurent state is not "PreInit" // to make sure that GenericIon has processes G4ApplicationState currentState = G4StateManager::GetStateManager()->GetCurrentState(); if (currentState == G4State_PreInit){ #ifdef G4VERBOSE if (GetVerboseLevel()>1) { G4cout << "G4IonTable::CreateIon() : can not create ion of "; G4cout << " Z =" << Z << " A = " << A << " L = " <0) { G4cout << "G4IonTable::CreateIon() : can not create ions " << G4endl; G4cout << " Z =" << Z << " A = " << A << " L = " << L << G4endl; } #endif return 0; } G4double life = -1.0; G4DecayTable* decayTable =0; G4bool stable = true; G4double mu = 0.0; G4double mass = GetNucleusMass(Z, A, L)+ E; G4double charge = G4double(Z)*eplus; G4int encoding = GetNucleusEncoding(Z,A,L,E,J); // create an ion // spin, parity, isospin values are fixed // ion = new G4Ions( name, mass, 0.0*MeV, charge, J, +1, 0, 0, 0, 0, "nucleus", 0, A, encoding, stable, life, decayTable, false, "generic", 0, E ); ion->SetPDGMagneticMoment(mu); //No Anti particle registered ion->SetAntiPDGEncoding(0); #ifdef G4VERBOSE if (GetVerboseLevel()>1) { G4cout << "G4IonTable::CreateIon() : create hyper ion of " << name << " encoding=" << encoding << G4endl; } #endif // Add process manager to the ion AddProcessManager(name); return ion; } //////////////////// // -- GetIon methods ------ //////////////////// G4ParticleDefinition* G4IonTable::GetIon(G4int Z, G4int A, G4int , G4int ) { return GetIon(Z, A); } //////////////////// G4ParticleDefinition* G4IonTable::GetIon(G4int Z, G4int A, G4int J) { return GetIon( Z, A, 0.0, J); } //////////////////// G4ParticleDefinition* G4IonTable::GetIon(G4int encoding) { G4int Z, A, L, J; G4double E; if (!GetNucleusByEncoding(encoding,Z,A,L,E,J) ){ #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::GetIon() : illegal encoding" << G4endl; G4cout << " CODE:" << encoding << G4endl; } #endif G4Exception( "G4IonTable::GetIon()","Illegal operation", JustWarning, "illegal encoding"); return 0; } // Only ground state is supported return GetIon( Z, A, L, 0.0, J); } //////////////////// G4ParticleDefinition* G4IonTable::GetIon(G4int Z, G4int A, G4double E, G4int J) { if ( (A<1) || (Z<=0) || (J<0) || (E<0.0) || (A>999) ) { #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::GetIon() : illegal atomic number/mass" << G4endl; G4cout << " Z =" << Z << " A = " << A << " E = " << E/keV << G4endl; } #endif return 0; } // Search ions with A, Z G4ParticleDefinition* ion = FindIon(Z,A,E,J); // create ion if (ion == 0) { ion = CreateIon(Z, A, E, J); } return ion; } //////////////////// G4ParticleDefinition* G4IonTable::GetIon(G4int Z, G4int A, G4int L, G4double E, G4int J) { if (L==0) return GetIon(Z,A,E,J); if (A < 2 || Z < 0 || Z > A-L || L>A || A>999 ) { #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::GetIon() : illegal atomic number/mass" << G4endl; G4cout << " Z =" << Z << " A = " << A << " L = " << L <<" E = " << E/keV << G4endl; } #endif return 0; } else if( A==2 ) { #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::GetIon() : No boud state for " << G4endl; G4cout << " Z =" << Z << " A = " << A << " L = " << L << " E = " << E/keV << G4endl; } #endif return 0; } // Search ions with A, Z G4ParticleDefinition* ion = FindIon(Z,A,L,E,J); // create ion if (ion == 0) { ion = CreateIon(Z, A, L, E, J); } return ion; } //////////////////// G4ParticleDefinition* G4IonTable::FindIon(G4int Z, G4int A, G4double E, G4int J) { const G4double EnergyTorelance = 0.1 * keV; if ( (A<1) || (Z<=0) || (J<0) || (E<0.0) || (A>999) ) { #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::FindIon() : illegal atomic number/mass or excitation level " << G4endl; G4cout << " Z =" << Z << " A = " << A << " E = " << E/keV << G4endl; } #endif G4Exception( "G4IonTable::FindIon()","Illegal operation", JustWarning, "illegal atomic number/mass"); return 0; } // Search ions with A, Z ,E // !! J is omitted now !! G4ParticleDefinition* ion=0; G4bool isFound = false; // -- loop over all particles in Ion table G4int encoding=GetNucleusEncoding(Z, A, 0); G4IonList::iterator i = fIonList->find(encoding); for( ;i != fIonList->end() ; i++) { ion = i->second; if ( ( ion->GetAtomicNumber() != Z) || (ion->GetAtomicMass()!=A) ) break; // excitation level G4double anExcitaionEnergy = ((const G4Ions*)(ion))->GetExcitationEnergy(); if ( ( std::fabs(E - anExcitaionEnergy ) < EnergyTorelance ) ) { isFound = true; break; } } if ( isFound ){ return ion; } else { return 0; } } //////////////////// G4ParticleDefinition* G4IonTable::FindIon(G4int Z, G4int A, G4int L, G4double E, G4int J) { if (L==0) return FindIon(Z,A,E,J); const G4double EnergyTorelance = 0.1 * keV; if (A < 2 || Z < 0 || Z > A-L || L>A || A>999 ) { #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::FindIon() : illegal atomic number/mass or excitation level " << G4endl; G4cout << " Z =" << Z << " A = " << A << " L = " << L <<" E = " << E/keV << G4endl; } #endif G4Exception( "G4IonTable::FindIon()","Illegal operation", JustWarning, "illegal atomic number/mass"); return 0; } // Search ions with A, Z ,E // !! J is omitted now !! G4ParticleDefinition* ion=0; G4bool isFound = false; // -- loop over all particles in Ion table G4int encoding=GetNucleusEncoding(Z, A, L); G4IonList::iterator i = fIonList->find(encoding); for( ;i != fIonList->end() ; i++) { ion = i->second; if ( ( ion->GetAtomicNumber() != Z) || (ion->GetAtomicMass()!=A) ) break; if( ion->GetQuarkContent(3) != L) break; // excitation level G4double anExcitaionEnergy = ((const G4Ions*)(ion))->GetExcitationEnergy(); if ( ( std::fabs(E - anExcitaionEnergy ) < EnergyTorelance ) ) { isFound = true; break; } } if ( isFound ){ return ion; } else { return 0; } } ///////////////// G4int G4IonTable::GetNucleusEncoding(G4int Z, G4int A, G4double E, G4int ) { // PDG code for Ions // Nuclear codes are given as 10-digit numbers +-100ZZZAAAI. //For a nucleus consisting of np protons and nn neutrons // A = np + nn and Z = np. // I gives the isomer level, with I = 0 corresponding // to the ground state and I >0 to excitations //!!! I = 1 is assigned fo all excitation states !!! const G4double EnergyTorelance = 0.1 * keV; if ( Z==1 && A==1 && E< EnergyTorelance ) { //proton return 2212; } G4int encoding = 1000000000; encoding += Z * 10000; encoding += A *10; if (E>0.0) encoding += 1; return encoding; } ///////////////// G4int G4IonTable::GetNucleusEncoding(G4int Z, G4int A, G4int L, G4double E, G4int ) { // get PDG code for Hyper-Nucleus Ions // Nuclear codes are given as 10-digit numbers +-10LZZZAAAI. //For a nucleus consisting of np protons and nn neutrons // A = np + nn +nlambda and Z = np. // L = nlambda // I gives the isomer level, with I = 0 corresponding // to the ground state and I >0 to excitations // //!!! I = 1 is assigned fo all excitation states in Geant4 G4int encoding = 1000000000; encoding += L* 10000000; encoding += Z * 10000; encoding += A *10; if (E>0.0) encoding += 1; return encoding; } /////////////// G4bool G4IonTable::GetNucleusByEncoding(G4int encoding, G4int &Z, G4int &A, G4double &E, G4int &J) { if (encoding <= 0) { // anti particle return false; } if (encoding == 2212) { // proton Z = 1; A = 1; E=0.0; J=0; return true; } if (encoding % 10 != 0) { //!!!not supported for excitation states !!! return false; } encoding -= 1000000000; Z = encoding/10000; encoding -= 10000*Z; A = encoding/10; E=0.0; J=0; return true; } /////////////// G4bool G4IonTable::GetNucleusByEncoding(G4int encoding, G4int &Z, G4int &A, G4int &L, G4double &E, G4int &J) { if (encoding <= 0) { // anti particle return false; } if (encoding % 10 != 0) { //!!!not supported for excitation states !!! return false; } if (encoding < 1000000000) { // anti particle return false; } encoding -= 1000000000; L = encoding/10000000; encoding -= 10000000*L; Z = encoding/10000; encoding -= 10000*Z; A = encoding/10; E=0.0; J=0; return true; } ///////////////// const G4String& G4IonTable::GetIonName(G4int Z, G4int A, G4double E) const { static G4String name; name =""; if ( (0< Z) && (Z <=numberOfElements) ) { name = elementName[Z-1]; } else if (Z > numberOfElements) { std::ostringstream os1; os1.setf(std::ios::fixed); os1 << Z ; name = "E" + os1.str() + "-"; } else { name = "?"; return name; } std::ostringstream os; os.setf(std::ios::fixed); os << A << '[' << std::setprecision(1) << E/keV << ']'; name += os.str(); return name; } ///////////////// const G4String& G4IonTable::GetIonName(G4int Z, G4int A, G4int L, G4double E) const { if (L==0) return GetIonName(Z, A, E); static G4String name; name =""; for (int i =0; iGetAtomicMass() >0) && (particle->GetAtomicNumber()>0)) return true; // particles derived from G4VIon and G4Ions if (particle->GetParticleType() == nucleus) return true; // proton (Hydrogen nucleus) if (particle->GetParticleName() == proton) return true; return false; } ///////////////// #include G4bool G4IonTable::IsLightIon(G4ParticleDefinition* particle) const { static const std::string names[] = { "proton", "neutron", "alpha", "deuteron", "triton", "He3", "GenericIon"}; // return true if the particle is pre-defined ion return std::find(names, names+7, particle->GetParticleName())!=names+7; } ///////////////// G4ParticleDefinition* G4IonTable::GetLightIon(G4int Z, G4int A) const { // returns pointer to pre-defined ions static G4bool isInitialized = false; static G4ParticleDefinition* p_proton=0; static G4ParticleDefinition* p_neutron=0; static G4ParticleDefinition* p_deuteron=0; static G4ParticleDefinition* p_triton=0; static G4ParticleDefinition* p_alpha=0; static G4ParticleDefinition* p_He3=0; if (!isInitialized) { p_proton = G4ParticleTable::GetParticleTable()->FindParticle("proton"); // proton p_neutron = G4ParticleTable::GetParticleTable()->FindParticle("neutron"); // neutron p_deuteron = G4ParticleTable::GetParticleTable()->FindParticle("deuteron"); // deuteron p_triton = G4ParticleTable::GetParticleTable()->FindParticle("triton"); // tritoon p_alpha = G4ParticleTable::GetParticleTable()->FindParticle("alpha"); // alpha p_He3 = G4ParticleTable::GetParticleTable()->FindParticle("He3"); // He3 isInitialized = true; } G4ParticleDefinition* ion=0; if ( (Z<=2) ) { if ( (Z==1)&&(A==1) ) { ion = p_proton; } else if ( (Z==0)&&(A==1) ) { ion = p_neutron; } else if ( (Z==1)&&(A==2) ) { ion = p_deuteron; } else if ( (Z==1)&&(A==3) ) { ion = p_triton; } else if ( (Z==2)&&(A==4) ) { ion = p_alpha; } else if ( (Z==2)&&(A==3) ) { ion = p_He3; } } return ion; } ///////////////// // -- GetNucleusMass/GetIonMass --- ///////////////// G4double G4IonTable::GetNucleusMass(G4int Z, G4int A, G4int L) const { if ( (A<1) || (Z<0) || (L<0) ){ #ifdef G4VERBOSE if (GetVerboseLevel()>0) { G4cout << "G4IonTable::GetNucleusMass() : illegal atomic number/mass " << G4endl; G4cout << " Z =" << Z << " A = " << A << G4endl; } #endif G4Exception( "G4IonTable::GetNucleusMass()","Illegal operation", EventMustBeAborted, "illegal atomic number/mass"); return -1.0; } G4double mass; if (L == 0) { // calculate nucleus mass G4ParticleDefinition* ion=GetLightIon(Z, A); if (ion!=0) { mass = ion->GetPDGMass(); } else { // use G4NucleiProperties::GetNuclearMass mass = G4NucleiProperties::GetNuclearMass(A, Z); } } else { mass = G4HyperNucleiProperties::GetNuclearMass(A, Z, L); } return mass; } ////////////////// G4double G4IonTable::GetIonMass(G4int Z, G4int A, G4int L) const { return GetNucleusMass(Z,A,L); } ///////////////// // -- Methods for handling conatiner --- ///////////////// void G4IonTable::Insert(G4ParticleDefinition* particle) { if (!IsIon(particle)) return; if (Contains(particle)) return; G4int Z = particle->GetAtomicNumber(); G4int A = particle->GetAtomicMass(); G4int L = particle->GetQuarkContent(3); //strangeness G4int encoding=GetNucleusEncoding(Z, A, L); fIonList->insert( std::pair(encoding, particle) ); } ///////////////// void G4IonTable::Remove(G4ParticleDefinition* particle) { if (IsIon(particle)) { G4int Z = particle->GetAtomicNumber(); G4int A = particle->GetAtomicMass(); G4int L = particle->GetQuarkContent(3); //strangeness G4int encoding=GetNucleusEncoding(Z, A, L); if (encoding !=0 ) { G4IonList::iterator i = fIonList->find(encoding); for( ;i != fIonList->end() ; i++) { if (particle == i->second) { fIonList->erase(i); break; } } } } else { #ifdef G4VERBOSE if (GetVerboseLevel()>1) { G4cout << "G4IonTable::Remove :" << particle->GetParticleName() ; G4cout << " is not ions" << G4endl; } #endif } } ///////////////// // -- Dump Information ///////////////// void G4IonTable::DumpTable(const G4String &particle_name) const { G4ParticleDefinition* ion; G4IonList::iterator idx; for (idx = fIonList->begin(); idx!= fIonList->end(); ++idx) { ion = idx->second; if (( particle_name == "ALL" ) || (particle_name == "all")){ ion->DumpTable(); } else if ( particle_name == ion->GetParticleName() ) { ion->DumpTable(); } } } ///////////////// const G4String G4IonTable::elementName[] = { "H", "He", "Li", "Be", "B", "C", "N", "O", "F", "Ne", "Na", "Mg", "Al", "Si", "P", "S", "Cl", "Ar", "K", "Ca", "Sc", "Ti", "V", "Cr", "Mn", "Fe", "Co", "Ni", "Cu", "Zn", "Ga", "Ge", "As", "Se", "Br", "Kr", "Rb", "Sr", "Y", "Zr", "Nb", "Mo","Tc", "Ru", "Rh", "Pd", "Ag", "Cd", "In", "Sn", "Sb", "Te", "I", "Xe", "Cs", "Ba", "La", "Ce", "Pr", "Nd", "Pm", "Sm", "Eu", "Gd", "Tb", "Dy", "Ho", "Er", "Tm", "Yb", "Lu", "Hf", "Ta", "W", "Re", "Os", "Ir", "Pt", "Au", "Hg", "Tl", "Pb", "Bi", "Po", "At", "Rn", "Fr", "Ra", "Ac", "Th", "Pa", "U", "Np", "Pu", "Am", "Cm", "Bk", "Cf", "Es", "Fm", "Md", "No", "Lr", "Rf", "Db", "Sg", "Bh", "Hs", "Mt", "Ds", "Rg", "Uub", "Uut", "Uuq","Uup","Uuh","Uus","Uuo" }; ///////////////// G4int G4IonTable::GetVerboseLevel() const { return G4ParticleTable::GetParticleTable()->GetVerboseLevel(); } ///////////////// void G4IonTable::AddProcessManager(const G4String& name) { // create command string for addProcManager std::ostringstream osAdd; osAdd << "/run/particle/addProcManager "<< name; G4String cmdAdd = osAdd.str(); // set /control/verbose 0 G4int tempVerboseLevel = G4UImanager::GetUIpointer()->GetVerboseLevel(); G4UImanager::GetUIpointer()->SetVerboseLevel(0); // issue /run/particle/addProcManage G4UImanager::GetUIpointer()->ApplyCommand(cmdAdd); // retreive /control/verbose G4UImanager::GetUIpointer()->SetVerboseLevel(tempVerboseLevel); } #include //////////////////// void G4IonTable::RegisterIsotopeTable(G4VIsotopeTable* table) { fIsotopeTableList->push_back(table); } //////////////////// G4VIsotopeTable* G4IonTable::GetIsotopeTable(size_t index) const { G4VIsotopeTable* fIsotopeTable=0; if ( index < fIsotopeTableList->size() ) { fIsotopeTable = (*fIsotopeTableList)[index]; } return fIsotopeTable; } //////////////////// G4IsotopeProperty* G4IonTable::FindIsotope(G4int Z, G4int A, G4double E, G4int ) { if (fIsotopeTableList ==0) return 0; if (fIsotopeTableList->size()==0) return 0; // ask IsotopeTable G4IsotopeProperty* property =0; // iterate for (size_t i = 0; i< fIsotopeTableList->size(); ++i) { G4VIsotopeTable* fIsotopeTable= (*fIsotopeTableList)[i]; G4IsotopeProperty* tmp = fIsotopeTable->GetIsotope(Z,A,E); if ( tmp !=0) { #ifdef G4VERBOSE if (GetVerboseLevel()>1) { G4cout << "G4IonTable::FindIsotope:"; G4cout << " Z: " << Z; G4cout << " A: " << A; G4cout << " E: " << E; G4cout << G4endl; tmp->DumpInfo(); } #endif if (property !=0) { // overwrite spin/magnetic moment/decay table if not defined if( property->GetiSpin() ==0) { property->SetiSpin( tmp->GetiSpin() ); } if( property->GetMagneticMoment() <= 0.0) { property->SetMagneticMoment( tmp->GetMagneticMoment() ); } if( property->GetLifeTime() <= 0.0) { property->SetLifeTime( tmp->GetLifeTime() ); if ( (property->GetLifeTime() > 0.0) && (property->GetDecayTable() ==0 ) ) { property->SetDecayTable( tmp->GetDecayTable() ); tmp->SetDecayTable( 0 ); } } } else { property = tmp; } } } return property; } //////////////////// void G4IonTable::CreateAllIon() { G4int Z; G4int A; G4double E=0.0; G4int J=0; for (Z=1; Z<=120; Z++) { for (A=Z;A<999 && A=0) && (index < Entries()) ) { G4IonList::iterator idx = fIonList->begin(); G4int counter = 0; while( idx != fIonList->end() ){ if ( counter == index ) return idx->second; counter++; idx++; } } #ifdef G4VERBOSE if (GetVerboseLevel()>1){ G4cout << " G4IonTable::GetParticle"; G4cout << " invalid index (=" << index << ")" << " entries = " << Entries() << G4endl; } #endif return 0; }