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>> 26 // $Id: G4NistMaterialBuilder.hh 91920 2015-08-11 09:50:13Z gcosmo $
26 27
27 #ifndef G4NistMaterialBuilder_h 28 #ifndef G4NistMaterialBuilder_h
28 #define G4NistMaterialBuilder_h 1 29 #define G4NistMaterialBuilder_h 1
29 30
30 //-------------------------------------------- 31 //---------------------------------------------------------------------------
31 // 32 //
32 // ClassName: G4NistMaterialBuilder 33 // ClassName: G4NistMaterialBuilder
33 // 34 //
34 // Description: Utility class to hold and mani 35 // Description: Utility class to hold and manipulate G4Materials
35 // 36 //
36 // Author: V.Ivanchenko 21.11.2004 37 // Author: V.Ivanchenko 21.11.2004
37 // 38 //
38 // Modifications: 39 // Modifications:
39 // 31.10.05 Add chemical effect and gas proper 40 // 31.10.05 Add chemical effect and gas properties (V.Ivanchenko)
40 // 27.02.06 V.Ivanchneko add ConstructNewGasMa 41 // 27.02.06 V.Ivanchneko add ConstructNewGasMaterial
41 // 11.05.06 V.Ivanchneko add warning flag to F 42 // 11.05.06 V.Ivanchneko add warning flag to FindOrBuildMaterial method
42 // 27.07.06 V.Ivanchneko set defaul warning=tr 43 // 27.07.06 V.Ivanchneko set defaul warning=true for FindOrBuildMaterial
43 // 27.07.07 V.Ivanchneko add matIndex vector t 44 // 27.07.07 V.Ivanchneko add matIndex vector to control built materials
44 // 28.07.07 V.Ivanchneko add BuildMaterial met 45 // 28.07.07 V.Ivanchneko add BuildMaterial method using Nist index
45 // 29.04.10 V.Ivanchneko add GetMeanIonisation 46 // 29.04.10 V.Ivanchneko add GetMeanIonisationEnergy method using Nist index
46 // 09.02.12 P.Gumplinger add ConstructNewIdeal 47 // 09.02.12 P.Gumplinger add ConstructNewIdealGasMaterial
47 // 48 //
48 //-------------------------------------------- 49 //----------------------------------------------------------------------------
49 // 50 //
50 // Class Description: 51 // Class Description:
51 // 52 //
52 // Element data from the NIST DB on Atomic Wei 53 // Element data from the NIST DB on Atomic Weights and Isotope Compositions
53 // http://physics.nist.gov/PhysRefData/Composi 54 // http://physics.nist.gov/PhysRefData/Compositions/index.html
54 // 55 //
55 56
56 #include "G4Material.hh" << 57 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
57 #include "globals.hh" <<
58 58
>> 59 #include <vector>
59 #include <CLHEP/Units/PhysicalConstants.h> 60 #include <CLHEP/Units/PhysicalConstants.h>
60 61
61 #include <vector> << 62 #include "globals.hh"
>> 63 #include "G4Material.hh"
>> 64
>> 65 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
62 66
63 class G4NistElementBuilder; 67 class G4NistElementBuilder;
64 68
65 class G4NistMaterialBuilder 69 class G4NistMaterialBuilder
66 { 70 {
67 public: << 71 public:
68 G4NistMaterialBuilder(G4NistElementBuilder*, <<
69 <<
70 ~G4NistMaterialBuilder() = default; <<
71 72
>> 73 G4NistMaterialBuilder(G4NistElementBuilder*, G4int verb=0);
>> 74
>> 75 ~G4NistMaterialBuilder();
>> 76
72 // Find or build a G4Material by name, from 77 // Find or build a G4Material by name, from dataBase
73 inline G4Material* FindMaterial(const G4Stri << 78 //
74 G4Material* FindOrBuildMaterial(const G4Stri << 79 G4Material* FindOrBuildMaterial (const G4String& name,
>> 80 G4bool isotopes=true,
>> 81 G4bool warning =true);
>> 82
75 83
76 // Find or build a simple material via atomi 84 // Find or build a simple material via atomic number
77 inline G4Material* FindSimpleMaterial(G4int << 85 //
78 G4Material* FindOrBuildSimpleMaterial(G4int 86 G4Material* FindOrBuildSimpleMaterial(G4int Z, G4bool warning);
79 87
80 // construct a G4Material from scratch by at 88 // construct a G4Material from scratch by atome count
81 G4Material* ConstructNewMaterial(const G4Str << 89 //
82 const std::vector<G4int>& nbAtoms, G4doubl << 90 G4Material* ConstructNewMaterial (const G4String& name,
83 G4double temp = NTP_Temperature, G4double << 91 const std::vector<G4String>& elm,
>> 92 const std::vector<G4int>& nbAtoms,
>> 93 G4double dens,
>> 94 G4bool isotopes = true,
>> 95 G4State state = kStateSolid,
>> 96 G4double temp = NTP_Temperature,
>> 97 G4double pressure = CLHEP::STP_Pressure);
84 98
85 // construct a G4Material from scratch by fr 99 // construct a G4Material from scratch by fraction mass
86 G4Material* ConstructNewMaterial(const G4Str << 100 //
87 const std::vector<G4double>& weight, G4dou << 101 G4Material* ConstructNewMaterial (const G4String& name,
88 G4double temp = NTP_Temperature, G4double << 102 const std::vector<G4String>& elm,
>> 103 const std::vector<G4double>& weight,
>> 104 G4double dens,
>> 105 G4bool isotopes = true,
>> 106 G4State state = kStateSolid,
>> 107 G4double temp = NTP_Temperature,
>> 108 G4double pressure = CLHEP::STP_Pressure);
>> 109
89 110
90 // construct a gas G4Material from scratch b 111 // construct a gas G4Material from scratch by atome count
91 G4Material* ConstructNewGasMaterial( << 112 //
92 const G4String& name, const G4String& name << 113 G4Material* ConstructNewGasMaterial(const G4String& name,
>> 114 const G4String& nameDB,
>> 115 G4double temp, G4double pres,
>> 116 G4bool isotopes = true);
93 117
94 // Construct an ideal gas G4Material from sc 118 // Construct an ideal gas G4Material from scratch by atom count
95 G4Material* ConstructNewIdealGasMaterial(con << 119 //
96 const std::vector<G4int>& nbAtoms, G4doubl << 120 G4Material* ConstructNewIdealGasMaterial(const G4String& name,
97 G4double pressure = CLHEP::STP_Pressure); << 121 const std::vector<G4String>& elm,
98 << 122 const std::vector<G4int>& nbAtoms,
>> 123 G4bool isotopes = true,
>> 124 G4double temp = NTP_Temperature,
>> 125 G4double pressure = CLHEP::STP_Pressure);
>> 126
99 // verbosity level defined by G4NistManager 127 // verbosity level defined by G4NistManager
>> 128 //
100 void SetVerbose(G4int val); 129 void SetVerbose(G4int val);
101 130
102 // cout predefined materials: 131 // cout predefined materials:
103 // "simple" - only pure materials in basic s 132 // "simple" - only pure materials in basic state (Z = 1, ..., 98)
104 // "compound" - NIST compounds 133 // "compound" - NIST compounds
105 // "hep" - HEP materials and compounds 134 // "hep" - HEP materials and compounds
106 // "biochemical" - bio-chemical materials << 135 // "biochemical" - bio-chemical materials
107 // "all" - all 136 // "all" - all
>> 137 //
108 void ListMaterials(const G4String&) const; 138 void ListMaterials(const G4String&) const;
109 139
110 // cout lists of predefined materials 140 // cout lists of predefined materials
>> 141 //
111 void ListNistSimpleMaterials() const; 142 void ListNistSimpleMaterials() const;
112 void ListNistCompoundMaterials() const; 143 void ListNistCompoundMaterials() const;
113 void ListHepMaterials() const; 144 void ListHepMaterials() const;
114 void ListSpaceMaterials() const; 145 void ListSpaceMaterials() const;
115 void ListBioChemicalMaterials() const; 146 void ListBioChemicalMaterials() const;
116 147
117 // access to the list of names of Geant4 pre 148 // access to the list of names of Geant4 predefined materials
>> 149 //
118 const std::vector<G4String>& GetMaterialName 150 const std::vector<G4String>& GetMaterialNames() const;
119 151
120 // access to the NIST mean ionisation potent 152 // access to the NIST mean ionisation potentials and nominal densities
>> 153 //
121 inline G4double GetMeanIonisationEnergy(G4in 154 inline G4double GetMeanIonisationEnergy(G4int index) const;
122 inline G4double GetNominalDensity(G4int inde 155 inline G4double GetNominalDensity(G4int index) const;
123 156
124 G4bool operator==(const G4NistMaterialBuilde << 157 private:
125 G4bool operator!=(const G4NistMaterialBuilde <<
126 G4NistMaterialBuilder(const G4NistMaterialBu <<
127 const G4NistMaterialBuilder& operator=(const <<
128 158
129 private: <<
130 void Initialise(); 159 void Initialise();
131 void NistSimpleMaterials(); 160 void NistSimpleMaterials();
132 void NistCompoundMaterials(); 161 void NistCompoundMaterials();
133 void NistCompoundMaterials2(); 162 void NistCompoundMaterials2();
134 void HepAndNuclearMaterials(); 163 void HepAndNuclearMaterials();
135 void SpaceMaterials(); 164 void SpaceMaterials();
136 void BioChemicalMaterials(); 165 void BioChemicalMaterials();
137 166
138 // add parameters of material from NIST DB t 167 // add parameters of material from NIST DB to internal vectors
139 // density in g/cm3, mean ionisation potenti 168 // density in g/cm3, mean ionisation potential in eV
140 // << 169 //
141 void AddMaterial(const G4String& nameMat, G4 << 170 void AddMaterial(const G4String& nameMat, G4double dens, G4int Z=0,
142 G4int ncomp = 1, G4State = kStateSolid, G4 << 171 G4double pot=0.0, G4int ncomp=1,
>> 172 G4State=kStateSolid, G4bool stp = true);
143 173
144 void AddGas(const G4String& nameMat, G4doubl << 174 void AddGas(const G4String& nameMat, G4double t=NTP_Temperature,
>> 175 G4double p=CLHEP::STP_Pressure);
145 176
146 void AddElementByWeightFraction(G4int Z, G4d 177 void AddElementByWeightFraction(G4int Z, G4double);
147 void AddElementByAtomCount(G4int Z, G4int); << 178 void AddElementByAtomCount (G4int Z, G4int);
148 179
149 void AddElementByWeightFraction(const G4Stri 180 void AddElementByWeightFraction(const G4String& name, G4double);
150 void AddElementByAtomCount(const G4String& n << 181 void AddElementByAtomCount (const G4String& name, G4int);
151 182
152 // build a G4Material from dataBase 183 // build a G4Material from dataBase
153 G4Material* BuildNistMaterial(const G4String <<
154 G4Material* BuildMaterial(G4int idx); 184 G4Material* BuildMaterial(G4int idx);
155 185
156 void DumpElm(G4int) const; 186 void DumpElm(G4int) const;
157 void DumpMix(G4int) const; 187 void DumpMix(G4int) const;
158 188
159 private: << 189 private:
160 G4NistElementBuilder* elmBuilder; <<
161 190
162 G4int verbose; << 191 G4NistElementBuilder* elmBuilder;
163 G4int nMaterials{0}; <<
164 G4int nComponents{0}; <<
165 G4int nCurrent{0}; <<
166 G4int nElementary; <<
167 G4int nNIST; <<
168 G4int nHEP; <<
169 G4int nSpace; <<
170 <<
171 std::vector<G4String> names; <<
172 std::vector<G4String> chFormulas; <<
173 <<
174 std::vector<G4double> densities; <<
175 std::vector<G4double> ionPotentials; <<
176 std::vector<G4State> states; <<
177 std::vector<G4double> fractions; <<
178 std::vector<G4bool> atomCount; <<
179 std::vector<G4int> components; <<
180 std::vector<G4int> indexes; <<
181 std::vector<G4int> elements; <<
182 std::vector<G4int> matIndex; <<
183 std::vector<G4bool> STP; <<
184 <<
185 std::vector<G4int> idxGas; <<
186 std::vector<G4double> gasTemperature; <<
187 std::vector<G4double> gasPressure; <<
188 }; <<
189 192
190 inline const std::vector<G4String>& G4NistMate << 193 G4int verbose;
191 { << 194 G4int nMaterials;
192 return names; << 195 G4int nComponents;
193 } << 196 G4int nCurrent;
>> 197 G4int nElementary;
>> 198 G4int nNIST;
>> 199 G4int nHEP;
>> 200 G4int nSpace;
>> 201
>> 202 std::vector<G4String> names;
>> 203 std::vector<G4String> chFormulas;
>> 204
>> 205 std::vector<G4double> densities;
>> 206 std::vector<G4double> ionPotentials;
>> 207 std::vector<G4State> states;
>> 208 std::vector<G4double> fractions;
>> 209 std::vector<G4bool> atomCount;
>> 210 std::vector<G4int> components;
>> 211 std::vector<G4int> indexes;
>> 212 std::vector<G4int> elements;
>> 213 std::vector<G4int> matIndex;
>> 214 std::vector<G4bool> STP;
>> 215
>> 216 std::vector<G4int> idxGas;
>> 217 std::vector<G4double> gasTemperature;
>> 218 std::vector<G4double> gasPressure;
194 219
195 inline G4double G4NistMaterialBuilder::GetMean << 220 G4bool first;
196 { <<
197 return (index >= 0 && index < nMaterials) ? <<
198 } <<
199 221
200 inline G4double G4NistMaterialBuilder::GetNomi << 222 };
>> 223
>> 224 inline const std::vector<G4String>&
>> 225 G4NistMaterialBuilder::GetMaterialNames() const
201 { 226 {
202 return (index >= 0 && index < nMaterials) ? << 227 return names;
203 } 228 }
204 229
205 inline G4Material* G4NistMaterialBuilder::Find << 230 inline G4double
>> 231 G4NistMaterialBuilder::GetMeanIonisationEnergy(G4int index) const
206 { 232 {
207 const G4MaterialTable* theMaterialTable = G4 << 233 G4double res = 10*index;
208 G4Material* ptr = nullptr; << 234 if(index >= 0 && index < nMaterials) { res = ionPotentials[index]; }
209 for (auto& mat : *theMaterialTable) { << 235 return res;
210 if (name == mat->GetName()) { <<
211 ptr = mat; <<
212 break; <<
213 } <<
214 } <<
215 return ptr; <<
216 } 236 }
217 237
218 inline G4Material* G4NistMaterialBuilder::Find << 238 inline G4double
>> 239 G4NistMaterialBuilder::GetNominalDensity(G4int index) const
219 { 240 {
220 return (Z > 0 && Z < nElementary) ? FindMate << 241 G4double res = 0.0;
>> 242 if(index >= 0 && index < nMaterials) { res = densities[index]; }
>> 243 return res;
221 } 244 }
222 245
223 #endif 246 #endif
224 247