Geant4 Cross Reference

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Geant4/materials/include/G4Material.hh

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Differences between /materials/include/G4Material.hh (Version 11.3.0) and /materials/include/G4Material.hh (Version 11.0.p4)


  1 //                                                  1 //
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 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 *
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 23 // * acceptance of all terms of the Geant4 Sof     23 // * acceptance of all terms of the Geant4 Software license.          *
 24 // *******************************************     24 // ********************************************************************
 25                                                <<  25 //
 26 //--------------------------------------------     26 //---------------------------------------------------------------------------
 27 //                                                 27 //
 28 // ClassName:   G4Material                         28 // ClassName:   G4Material
 29 //                                                 29 //
 30 // Description: Contains material properties       30 // Description: Contains material properties
 31 //                                                 31 //
 32 // Class description:                              32 // Class description:
 33 //                                                 33 //
 34 // Is used to define the material composition      34 // Is used to define the material composition of Geant4 volumes.
 35 // A G4Material is always made of G4Elements.  <<  35 // A G4Material is always made of G4Elements. It should has the name, 
 36 // the list of G4Elements, material density, m <<  36 // the list of G4Elements, material density, material state, temperature, 
 37 // pressure. Other parameters are optional and <<  37 // pressure. Other parameters are optional and may be set by the user code 
 38 // or computed at initialisation.              <<  38 // or computed at initialisation. 
 39 //                                             <<  39 // 
 40 // There is several ways to construct G4Materi     40 // There is several ways to construct G4Material:
 41 //   - from single element;                        41 //   - from single element;
 42 //   - from a list of components (elements or      42 //   - from a list of components (elements or other materials);
 43 //   - from internal Geant4 database of materi     43 //   - from internal Geant4 database of materials
 44 //                                                 44 //
 45 // A collection of constituent Elements/Materi <<  45 // A collection of constituent Elements/Materials should be defined 
 46 // with specified weights by fractional mass o     46 // with specified weights by fractional mass or atom counts (only for Elements).
 47 //                                                 47 //
 48 // Quantities, with physical meaning or not, w <<  48 // Quantities, with physical meaning or not, which are constant in a given 
 49 // material are computed and stored here as De     49 // material are computed and stored here as Derived data members.
 50 //                                                 50 //
 51 // The class contains as a private static memb     51 // The class contains as a private static member the Table of defined
 52 // materials (an ordered vector of materials).     52 // materials (an ordered vector of materials).
 53 //                                                 53 //
 54 // It is strongly not recommended to delete ma     54 // It is strongly not recommended to delete materials in user code.
 55 // All materials will be deleted automatically     55 // All materials will be deleted automatically at the end of Geant4 session.
 56 //                                                 56 //
                                                   >>  57 
                                                   >>  58 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
                                                   >>  59 
 57 // 10-07-96, new data members added by L.Urban     60 // 10-07-96, new data members added by L.Urban
 58 // 12-12-96, new data members added by L.Urban     61 // 12-12-96, new data members added by L.Urban
 59 // 20-01-97, aesthetic rearrangement. RadLengt     62 // 20-01-97, aesthetic rearrangement. RadLength calculation modified
 60 //           Data members Zeff and Aeff REMOVE     63 //           Data members Zeff and Aeff REMOVED (i.e. passed to the Elements).
 61 //           (local definition of Zeff in Dens     64 //           (local definition of Zeff in DensityEffect and FluctModel...)
 62 //           Vacuum defined as a G4State. Mixt <<  65 //           Vacuum defined as a G4State. Mixture flag removed, M.Maire  
 63 // 29-01-97, State=Vacuum automatically set de     66 // 29-01-97, State=Vacuum automatically set density=0 in the contructors.
 64 //           Subsequent protections have been  <<  67 //           Subsequent protections have been put in the calculation of 
 65 //           MeanExcEnergy, ShellCorrectionVec     68 //           MeanExcEnergy, ShellCorrectionVector, DensityEffect, M.Maire
 66 // 20-03-97, corrected initialization of point     69 // 20-03-97, corrected initialization of pointers, M.Maire
 67 // 10-06-97, new data member added by V.Grichi     70 // 10-06-97, new data member added by V.Grichine (fSandiaPhotoAbsCof)
 68 // 27-06-97, new function GetElement(int), M.M     71 // 27-06-97, new function GetElement(int), M.Maire
 69 // 24-02-98, fFractionVector become fMassFract     72 // 24-02-98, fFractionVector become fMassFractionVector
 70 // 28-05-98, kState=kVacuum removed:           <<  73 // 28-05-98, kState=kVacuum removed: 
 71 //           The vacuum is an ordinary gas vit     74 //           The vacuum is an ordinary gas vith very low density, M.Maire
 72 // 12-06-98, new method AddMaterial() allowing     75 // 12-06-98, new method AddMaterial() allowing mixture of materials, M.Maire
 73 // 09-07-98, Ionisation parameters removed fro     76 // 09-07-98, Ionisation parameters removed from the class, M.Maire
 74 // 04-08-98, new method GetMaterial(materialNa     77 // 04-08-98, new method GetMaterial(materialName), M.Maire
 75 // 05-10-98, change name: NumDensity -> NbOfAt     78 // 05-10-98, change name: NumDensity -> NbOfAtomsPerVolume
 76 // 18-11-98, SandiaTable interface modified.       79 // 18-11-98, SandiaTable interface modified.
 77 // 19-07-99, new data member (chemicalFormula)     80 // 19-07-99, new data member (chemicalFormula) added by V.Ivanchenko
 78 // 12-03-01, G4bool fImplicitElement (mma)         81 // 12-03-01, G4bool fImplicitElement (mma)
 79 // 30-03-01, suppression of the warning messag     82 // 30-03-01, suppression of the warning message in GetMaterial
 80 // 17-07-01, migration to STL. M. Verderi.         83 // 17-07-01, migration to STL. M. Verderi.
 81 // 14-09-01, Suppression of the data member fI     84 // 14-09-01, Suppression of the data member fIndexInTable
 82 // 31-10-01, new function SetChemicalFormula()     85 // 31-10-01, new function SetChemicalFormula() (mma)
 83 // 26-02-02, fIndexInTable renewed                 86 // 26-02-02, fIndexInTable renewed
 84 // 06-08-02, remove constructors with Chemical     87 // 06-08-02, remove constructors with ChemicalFormula (mma)
 85 // 15-11-05, GetMaterial(materialName, G4bool      88 // 15-11-05, GetMaterial(materialName, G4bool warning=true)
 86 // 13-04-12, std::map<G4Material*,G4double> fM     89 // 13-04-12, std::map<G4Material*,G4double> fMatComponents (mma)
 87 // 21-04-12, fMassOfMolecule (mma)                 90 // 21-04-12, fMassOfMolecule (mma)
 88                                                    91 
                                                   >>  92 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
                                                   >>  93 
 89 #ifndef G4MATERIAL_HH                              94 #ifndef G4MATERIAL_HH
 90 #define G4MATERIAL_HH 1                            95 #define G4MATERIAL_HH 1
 91                                                    96 
                                                   >>  97 #include <vector>
                                                   >>  98 #include <map>
                                                   >>  99 #include <CLHEP/Units/PhysicalConstants.h>
                                                   >> 100 
                                                   >> 101 #include "globals.hh"
                                                   >> 102 #include "G4ios.hh"
 92 #include "G4Element.hh"                           103 #include "G4Element.hh"
 93 #include "G4ElementVector.hh"                  << 
 94 #include "G4IonisParamMat.hh"                  << 
 95 #include "G4MaterialPropertiesTable.hh"           104 #include "G4MaterialPropertiesTable.hh"
 96 #include "G4MaterialTable.hh"                  << 105 #include "G4IonisParamMat.hh"
 97 #include "G4SandiaTable.hh"                       106 #include "G4SandiaTable.hh"
 98 #include "G4ios.hh"                            << 107 #include "G4ElementVector.hh"
 99 #include "globals.hh"                          << 108 #include "G4MaterialTable.hh"
                                                   >> 109 #include "G4Threading.hh"
100                                                   110 
101 #include <CLHEP/Units/PhysicalConstants.h>     << 111 enum G4State { kStateUndefined = 0, kStateSolid, kStateLiquid, kStateGas };
102                                                   112 
103 #include <map>                                 << 113 static const G4double NTP_Temperature = 293.15*CLHEP::kelvin;
104 #include <vector>                              << 
105                                                << 
106 enum G4State                                   << 
107 {                                              << 
108   kStateUndefined = 0,                         << 
109   kStateSolid,                                 << 
110   kStateLiquid,                                << 
111   kStateGas                                    << 
112 };                                             << 
113                                                   114 
114 static const G4double NTP_Temperature = 293.15 << 115 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
115                                                   116 
116 class G4Material                                  117 class G4Material
117 {                                                 118 {
118  public:  // with description                  << 119 public:  // with description
                                                   >> 120   //
119   // Constructor to create a material from sin    121   // Constructor to create a material from single element
120   G4Material(const G4String& name,  // its nam << 122   //
121     G4double z,  // atomic number              << 123   G4Material(const G4String& name,        //its name
122     G4double a,  // mass of mole               << 124                    G4double  z,         //atomic number
123     G4double density,  // density              << 125                    G4double  a,         //mass of mole
124     G4State state = kStateUndefined,  // solid << 126                    G4double  density,         //density
125     G4double temp = NTP_Temperature,  // tempe << 127                    G4State   state    = kStateUndefined,  //solid,gas
126     G4double pressure = CLHEP::STP_Pressure);  << 128                    G4double  temp     = NTP_Temperature,  //temperature
                                                   >> 129                    G4double  pressure = CLHEP::STP_Pressure); //pressure
127                                                   130 
                                                   >> 131   //
128   // Constructor to create a material from a c    132   // Constructor to create a material from a combination of elements
129   // and/or materials subsequently added via A    133   // and/or materials subsequently added via AddElement and/or AddMaterial
130   G4Material(const G4String& name,  // its nam << 134   //
131     G4double density,  // density              << 135   G4Material(const G4String& name,        //its name
132     G4int nComponents,  // nbOfComponents      << 136                    G4double  density,         //density
133     G4State state = kStateUndefined,  // solid << 137                    G4int     nComponents,     //nbOfComponents
134     G4double temp = NTP_Temperature,  // tempe << 138                    G4State   state    = kStateUndefined,  //solid,gas
135     G4double pressure = CLHEP::STP_Pressure);  << 139                    G4double  temp     = NTP_Temperature,  //temperature
                                                   >> 140                    G4double  pressure = CLHEP::STP_Pressure); //pressure
136                                                   141 
                                                   >> 142   //
137   // Constructor to create a material from the    143   // Constructor to create a material from the base material
138   G4Material(const G4String& name,  // its nam << 144   //
139     G4double density,  // density              << 145   G4Material(const G4String& name,        //its name
140     const G4Material* baseMaterial,  // base m << 146                    G4double  density,         //density
141     G4State state = kStateUndefined,  // solid << 147              const G4Material* baseMaterial,      //base material
142     G4double temp = NTP_Temperature,  // tempe << 148                    G4State   state    = kStateUndefined,  //solid,gas
143     G4double pressure = CLHEP::STP_Pressure);  << 149                    G4double  temp     = NTP_Temperature,  //temperature
144                                                << 150                    G4double  pressure = CLHEP::STP_Pressure); //pressure
145   virtual ~G4Material();                       << 
146                                                << 
147   // These methods allow customisation of corr << 
148   // computations. Free electron density above << 
149   // is a conductor. Computation of density ef << 
150   // may be more accurate but require extra co << 
151   void SetChemicalFormula(const G4String& chF) << 
152   void SetFreeElectronDensity(G4double val);   << 
153   void ComputeDensityEffectOnFly(G4bool val);  << 
154                                                << 
155   G4Material(const G4Material&) = delete;      << 
156   const G4Material& operator=(const G4Material << 
157                                                   151 
                                                   >> 152   //
158   // Add an element, giving number of atoms       153   // Add an element, giving number of atoms
159   void AddElementByNumberOfAtoms(const G4Eleme << 154   //
160   inline void AddElement(G4Element* elm, G4int << 155   void AddElementByNumberOfAtoms(const G4Element* elm, G4int nAtoms); 
                                                   >> 156   inline 
                                                   >> 157   void AddElement(G4Element* elm, G4int nAtoms)
                                                   >> 158   { AddElementByNumberOfAtoms(elm, nAtoms); }
161                                                   159 
                                                   >> 160   //
162   // Add an element or material, giving fracti    161   // Add an element or material, giving fraction of mass
163   void AddElementByMassFraction(const G4Elemen << 162   //
164   inline void AddElement(G4Element* elm, G4dou << 163   void AddElementByMassFraction(const G4Element* elm, G4double fraction);  
                                                   >> 164   inline void AddElement (G4Element* elm, G4double frac)
                                                   >> 165   { AddElementByMassFraction(elm, frac); }
165                                                   166 
166   void AddMaterial(G4Material* material, G4dou    167   void AddMaterial(G4Material* material, G4double fraction);
167                                                << 168                      
                                                   >> 169   virtual ~G4Material();  
168   //                                              170   //
169   // retrieval methods                            171   // retrieval methods
170   //                                           << 172   // 
171   inline const G4String& GetName() const { ret << 173   inline const G4String& GetName()            const {return fName;}
172   inline const G4String& GetChemicalFormula()  << 174   inline const G4String& GetChemicalFormula() const {return fChemicalFormula;}
173   inline G4double GetFreeElectronDensity() con << 175   inline G4double GetFreeElectronDensity()    const {return fFreeElecDensity;}
174   inline G4double GetDensity() const { return  << 176   inline G4double GetDensity()     const {return fDensity;}
175   inline G4State GetState() const { return fSt << 177   inline G4State  GetState()       const {return fState;}
176   inline G4double GetTemperature() const { ret << 178   inline G4double GetTemperature() const {return fTemp;}
177   inline G4double GetPressure() const { return << 179   inline G4double GetPressure()    const {return fPressure;}
178                                                << 180     
179   // number of elements constituing this mater << 181   //number of elements constituing this material:    
180   inline std::size_t GetNumberOfElements() con << 182   inline size_t GetNumberOfElements()  const {return fNumberOfElements;}
181                                                << 183     
182   // vector of pointers to elements constituin << 184   //vector of pointers to elements constituing this material:          
183   inline const G4ElementVector* GetElementVect << 185   inline const
184                                                << 186   G4ElementVector* GetElementVector()  const {return theElementVector;}
185   // vector of fractional mass of each element << 187   
186   inline const G4double* GetFractionVector() c << 188   //vector of fractional mass of each element:
187                                                << 189   inline const  
188   // vector of atom count of each element:     << 190   G4double* GetFractionVector() const {return fMassFractionVector;}
189   inline const G4int* GetAtomsVector() const { << 191     
190                                                << 192   //vector of atom count of each element:
191   // return a pointer to an element, given its << 193   inline const  
192   inline const G4Element* GetElement(G4int iel << 194   G4int*    GetAtomsVector()    const {return fAtomsVector;}
193                                                << 195 
194   // vector of nb of atoms per volume of each  << 196   //return a pointer to an element, given its index in the material:
195   inline const G4double* GetVecNbOfAtomsPerVol << 197   inline const 
196   // total number of atoms per volume:         << 198   G4Element* GetElement(G4int iel) const {return (*theElementVector)[iel];}
197   inline G4double GetTotNbOfAtomsPerVolume() c << 199   
198   // total number of electrons per volume:     << 200   //vector of nb of atoms per volume of each element in this material:
199   inline G4double GetTotNbOfElectPerVolume() c << 201   inline const
200                                                << 202   G4double* GetVecNbOfAtomsPerVolume() const {return fVecNbOfAtomsPerVolume;}
201   // obsolete names (5-10-98) see the 2 functi << 203   //total number of atoms per volume:
202   inline const G4double* GetAtomicNumDensityVe << 204   inline
203   inline G4double GetElectronDensity() const { << 205   G4double  GetTotNbOfAtomsPerVolume() const {return fTotNbOfAtomsPerVolume;}
204                                                << 206   //total number of electrons per volume:
205   // Radiation length:                         << 207   inline
206   inline G4double GetRadlen() const { return f << 208   G4double  GetTotNbOfElectPerVolume() const {return fTotNbOfElectPerVolume;}
207                                                << 209 
208   // Nuclear interaction length                << 210   //obsolete names (5-10-98) see the 2 functions above
209   inline G4double GetNuclearInterLength() cons << 211   inline const
210                                                << 212   G4double* GetAtomicNumDensityVector() const {return fVecNbOfAtomsPerVolume;}
                                                   >> 213   inline G4double  GetElectronDensity() const {return fTotNbOfElectPerVolume;}
                                                   >> 214     
                                                   >> 215   // Radiation length:     
                                                   >> 216   inline G4double  GetRadlen()            const {return fRadlen;}
                                                   >> 217     
                                                   >> 218   // Nuclear interaction length     
                                                   >> 219   inline G4double GetNuclearInterLength() const {return fNuclInterLen;}
                                                   >> 220         
211   // ionisation parameters:                       221   // ionisation parameters:
212   inline G4IonisParamMat* GetIonisation() cons << 222   inline G4IonisParamMat* GetIonisation() const {return fIonisation;}
213                                                   223 
214   // Sandia table:                                224   // Sandia table:
215   inline G4SandiaTable* GetSandiaTable() const << 225   inline G4SandiaTable* GetSandiaTable()  const {return fSandiaTable; }
216                                                << 226   
217   // Base material:                               227   // Base material:
218   inline const G4Material* GetBaseMaterial() c << 228   inline 
219                                                << 229   const G4Material* GetBaseMaterial()     const {return fBaseMaterial;}
                                                   >> 230   
220   // material components:                         231   // material components:
221   inline const std::map<G4Material*, G4double> << 232   inline
222                                                << 233   const std::map<G4Material*,G4double>& GetMatComponents() const 
                                                   >> 234                                                 {return fMatComponents;}
                                                   >> 235                  
223   // for chemical compound                        236   // for chemical compound
224   inline G4double GetMassOfMolecule() const {  << 237   inline G4double GetMassOfMolecule() const     {return fMassOfMolecule;}
                                                   >> 238 
                                                   >> 239   void SetChemicalFormula(const G4String& chF);
                                                   >> 240 
                                                   >> 241   void SetFreeElectronDensity(G4double);
225                                                   242 
                                                   >> 243   void ComputeDensityEffectOnFly(G4bool);
                                                   >> 244       
226   // meaningful only for single material:         245   // meaningful only for single material:
227   G4double GetZ() const;                          246   G4double GetZ() const;
228   G4double GetA() const;                          247   G4double GetA() const;
229                                                   248 
230   // the MaterialPropertiesTable (if any) atta << 249   //the MaterialPropertiesTable (if any) attached to this material:
231   void SetMaterialPropertiesTable(G4MaterialPr    250   void SetMaterialPropertiesTable(G4MaterialPropertiesTable* anMPT);
232                                                << 251                  
233   inline G4MaterialPropertiesTable* GetMateria    252   inline G4MaterialPropertiesTable* GetMaterialPropertiesTable() const
234   {                                            << 253   {return fMaterialPropertiesTable;}
235     return fMaterialPropertiesTable;           << 
236   }                                            << 
237                                                   254 
238   // the index of this material in the Table:  << 255   //the index of this material in the Table:    
239   inline std::size_t GetIndex() const { return << 256   inline size_t GetIndex() const {return fIndexInTable;}
240                                                   257 
241   // the static Table of Materials:               258   // the static Table of Materials:
                                                   >> 259   //
242   static G4MaterialTable* GetMaterialTable();     260   static G4MaterialTable* GetMaterialTable();
                                                   >> 261       
                                                   >> 262   static size_t GetNumberOfMaterials();
                                                   >> 263       
                                                   >> 264   //return  pointer to a material, given its name:    
                                                   >> 265   static G4Material* GetMaterial(const G4String& name, G4bool warning=true);
243                                                   266 
244   static std::size_t GetNumberOfMaterials();   << 267   //return  pointer to a simple material, given its propeties:
245                                                << 
246   // return  pointer to a material, given its  << 
247   static G4Material* GetMaterial(const G4Strin << 
248                                                << 
249   // return  pointer to a simple material, giv << 
250   static G4Material* GetMaterial(G4double z, G    268   static G4Material* GetMaterial(G4double z, G4double a, G4double dens);
251                                                   269 
252   // return  pointer to a composit material, g << 270   //return  pointer to a composit material, given its propeties:
253   static G4Material* GetMaterial(std::size_t n << 271   static G4Material* GetMaterial(size_t nComp, G4double dens);
254                                                << 272   
255   // printing methods                          << 273   //
256   friend std::ostream& operator<<(std::ostream << 274   //printing methods
257   friend std::ostream& operator<<(std::ostream << 275   //
                                                   >> 276   friend std::ostream& operator<<(std::ostream&, const G4Material*);    
                                                   >> 277   friend std::ostream& operator<<(std::ostream&, const G4Material&);    
258   friend std::ostream& operator<<(std::ostream    278   friend std::ostream& operator<<(std::ostream&, const G4MaterialTable&);
                                                   >> 279     
                                                   >> 280   G4Material(__void__&);
                                                   >> 281     // Fake default constructor for usage restricted to direct object
                                                   >> 282     // persistency for clients requiring preallocation of memory for
                                                   >> 283     // persistifiable objects.
259                                                   284 
260   inline void SetName(const G4String& name) {  << 285   inline void SetName (const G4String& name) {fName=name;}
261                                                   286 
262   virtual G4bool IsExtended() const;              287   virtual G4bool IsExtended() const;
263                                                   288 
264   // operators                                    289   // operators
265   G4bool operator==(const G4Material&) const =    290   G4bool operator==(const G4Material&) const = delete;
266   G4bool operator!=(const G4Material&) const =    291   G4bool operator!=(const G4Material&) const = delete;
                                                   >> 292   G4Material(const G4Material&) = delete;
                                                   >> 293   const G4Material& operator=(const G4Material&) = delete;
267                                                   294 
268  private:                                      << 295 private:
269   void InitializePointers();                   << 
270                                                   296 
                                                   >> 297   void InitializePointers();
                                                   >> 298    
271   // Header routine for all derived quantities    299   // Header routine for all derived quantities
272   void ComputeDerivedQuantities();                300   void ComputeDerivedQuantities();
273                                                   301 
274   // Compute Radiation length                     302   // Compute Radiation length
275   void ComputeRadiationLength();                  303   void ComputeRadiationLength();
276                                                << 304   
277   // Compute Nuclear interaction length           305   // Compute Nuclear interaction length
278   void ComputeNuclearInterLength();               306   void ComputeNuclearInterLength();
279                                                   307 
280   // Copy pointers of base material               308   // Copy pointers of base material
281   void CopyPointersOfBaseMaterial();              309   void CopyPointersOfBaseMaterial();
                                                   >> 310     
                                                   >> 311 private:
282                                                   312 
283   void FillVectors();                             313   void FillVectors();
284                                                   314 
285   G4bool IsLocked();                           << 315   static
                                                   >> 316   G4MaterialTable theMaterialTable;  // the material table
286                                                   317 
287   const G4Material* fBaseMaterial;  // Pointer << 318   const G4Material* fBaseMaterial;   // Pointer to the base material
288   G4MaterialPropertiesTable* fMaterialProperti    319   G4MaterialPropertiesTable* fMaterialPropertiesTable;
289                                                   320 
290   //                                              321   //
291   // General atomic properties defined in cons    322   // General atomic properties defined in constructor or
292   // computed from the basic data members         323   // computed from the basic data members
293   //                                              324   //
294                                                << 325   
295   G4ElementVector* theElementVector;  // vecto << 326   G4ElementVector* theElementVector; // vector of constituent G4Elements
296   G4int* fAtomsVector;  // composition by atom << 327   G4int* fAtomsVector;               // composition by atom count
297   G4double* fMassFractionVector;  // compositi << 328   G4double* fMassFractionVector;     // composition by fractional mass   
298   G4double* fVecNbOfAtomsPerVolume;  // number    329   G4double* fVecNbOfAtomsPerVolume;  // number of atoms per volume
299                                                << 330   
300   G4IonisParamMat* fIonisation;  // ionisation << 331   G4IonisParamMat* fIonisation;    // ionisation parameters
301   G4SandiaTable* fSandiaTable;  // Sandia tabl << 332   G4SandiaTable* fSandiaTable;     // Sandia table         
302                                                << 333 
303   G4double fDensity;  // Material density      << 334   G4double fDensity;               // Material density
304   G4double fFreeElecDensity;  // Free electron << 335   G4double fFreeElecDensity;       // Free electron density
305   G4double fTemp;  // Temperature (defaults: S << 336   G4double fTemp;                  // Temperature (defaults: STP)
306   G4double fPressure;  // Pressure    (default << 337   G4double fPressure;              // Pressure    (defaults: STP)
307                                                << 338 
308   G4double fTotNbOfAtomsPerVolume;  // Total n << 339   G4double fTotNbOfAtomsPerVolume; // Total nb of atoms per volume 
309   G4double fTotNbOfElectPerVolume;  // Total n << 340   G4double fTotNbOfElectPerVolume; // Total nb of electrons per volume 
310   G4double fRadlen;  // Radiation length       << 341   G4double fRadlen;                // Radiation length
311   G4double fNuclInterLen;  // Nuclear interact << 342   G4double fNuclInterLen;          // Nuclear interaction length  
312   G4double fMassOfMolecule;  // Correct for ma << 343   G4double fMassOfMolecule;        // Correct for materials built by atoms count
313                                                << 344 
314   G4State fState;  // Material state           << 345   G4State fState;                  // Material state
315   std::size_t fIndexInTable;  // Index in the  << 346   size_t fIndexInTable;            // Index in the material table 
316   G4int fNumberOfElements;  // Number of G4Ele << 347   G4int fNumberOfElements;         // Number of G4Elements in the material
317                                                   348 
318   // Class members used only at initialisation    349   // Class members used only at initialisation
319   G4int fNbComponents;  // Number of component << 350   G4int fNbComponents;             // Number of material components 
320   G4int fIdxComponent;  // Index of a new comp << 351   G4int fIdxComponent;             // Index of a new component
321   G4bool fMassFraction;  // Flag of the method << 352   G4bool fMassFraction;            // Flag of the method to add components
322                                                << 353 
323   // For composites built                      << 354   // For composites built 
324   std::vector<G4int>* fAtoms = nullptr;        << 355   std::vector<G4int>* fAtoms; 
325   std::vector<G4double>* fElmFrac = nullptr;   << 356   std::vector<G4double>* fElmFrac; 
326   std::vector<const G4Element*>* fElm = nullpt << 357   std::vector<const G4Element*>* fElm;
327                                                   358 
328   // For composites built via AddMaterial()       359   // For composites built via AddMaterial()
329   std::map<G4Material*, G4double> fMatComponen << 360   std::map<G4Material*, G4double> fMatComponents; 
330                                                   361 
331   G4String fName;  // Material name            << 362   G4String fName;                  // Material name
332   G4String fChemicalFormula;  // Material chem << 363   G4String fChemicalFormula;       // Material chemical formula
                                                   >> 364 
                                                   >> 365 #ifdef G4MULTITHREADED
                                                   >> 366   static G4Mutex materialMutex;
                                                   >> 367 #endif
333 };                                                368 };
                                                   >> 369 
                                                   >> 370 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
334                                                   371 
335 #endif                                            372 #endif
336                                                   373