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25 // 25 //
26 /// \file field/field02/src/F02DetectorConstru 26 /// \file field/field02/src/F02DetectorConstruction.cc
27 /// \brief Implementation of the F02DetectorCo 27 /// \brief Implementation of the F02DetectorConstruction class
28 // 28 //
29 // 29 //
30 // 30 //
31 // 31 //
32 //....oooOO0OOooo........oooOO0OOooo........oo 32 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
33 //....oooOO0OOooo........oooOO0OOooo........oo 33 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
34 34
35 #include "F02DetectorConstruction.hh" 35 #include "F02DetectorConstruction.hh"
>> 36 #include "F02DetectorMessenger.hh"
36 37
37 #include "F02CalorimeterSD.hh" 38 #include "F02CalorimeterSD.hh"
38 #include "F02DetectorMessenger.hh" << 39 #include "F02ElectricFieldSetup.hh"
39 40
40 #include "G4AutoDelete.hh" <<
41 #include "G4GeometryManager.hh" 41 #include "G4GeometryManager.hh"
42 #include "G4FieldBuilder.hh" << 42 #include "G4PhysicalVolumeStore.hh"
43 #include "G4LogicalVolume.hh" <<
44 #include "G4LogicalVolumeStore.hh" 43 #include "G4LogicalVolumeStore.hh"
>> 44 #include "G4SolidStore.hh"
>> 45
45 #include "G4Material.hh" 46 #include "G4Material.hh"
>> 47 #include "G4Tubs.hh"
>> 48 #include "G4LogicalVolume.hh"
46 #include "G4PVPlacement.hh" 49 #include "G4PVPlacement.hh"
47 #include "G4PhysicalConstants.hh" <<
48 #include "G4PhysicalVolumeStore.hh" <<
49 #include "G4RunManager.hh" 50 #include "G4RunManager.hh"
>> 51 #include "G4AutoDelete.hh"
50 #include "G4SDManager.hh" 52 #include "G4SDManager.hh"
51 #include "G4SolidStore.hh" << 53
>> 54 #include "G4PhysicalConstants.hh"
52 #include "G4SystemOfUnits.hh" 55 #include "G4SystemOfUnits.hh"
53 #include "G4Tubs.hh" <<
54 #include "G4UniformElectricField.hh" <<
55 56
56 //....oooOO0OOooo........oooOO0OOooo........oo 57 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
57 58
58 F02DetectorConstruction::F02DetectorConstructi 59 F02DetectorConstruction::F02DetectorConstruction()
59 { 60 {
60 // create commands for interactive definitio 61 // create commands for interactive definition of the calorimeter
61 62
62 fDetectorMessenger = new F02DetectorMessenge 63 fDetectorMessenger = new F02DetectorMessenger(this);
63 64
64 // create field builder <<
65 // this will create commands for field confi <<
66 G4FieldBuilder::Instance(); <<
67 // G4FieldBuilder::Instance()->SetVerboseLev <<
68 <<
69 // create materials 65 // create materials
>> 66
70 DefineMaterials(); 67 DefineMaterials();
>> 68
71 } 69 }
72 70
73 //....oooOO0OOooo........oooOO0OOooo........oo 71 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
74 72
75 F02DetectorConstruction::~F02DetectorConstruct 73 F02DetectorConstruction::~F02DetectorConstruction()
76 { 74 {
77 delete fDetectorMessenger; 75 delete fDetectorMessenger;
78 } 76 }
79 77
80 //....oooOO0OOooo........oooOO0OOooo........oo 78 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
81 79
82 G4VPhysicalVolume* F02DetectorConstruction::Co 80 G4VPhysicalVolume* F02DetectorConstruction::Construct()
83 { 81 {
84 return ConstructCalorimeter(); 82 return ConstructCalorimeter();
85 } 83 }
86 84
87 //....oooOO0OOooo........oooOO0OOooo........oo 85 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
88 86
89 void F02DetectorConstruction::DefineMaterials( 87 void F02DetectorConstruction::DefineMaterials()
90 { 88 {
91 // This function illustrates the possible wa << 89 //This function illustrates the possible ways to define materials
92 90
93 G4String name, symbol; // a=mass of a mole; << 91 G4String name, symbol; // a=mass of a mole;
94 G4double a, z, density; // z=mean number of << 92 G4double a, z, density; // z=mean number of protons;
95 G4int nel; 93 G4int nel;
96 G4int ncomponents; 94 G4int ncomponents;
97 G4double fractionmass, pressure, temperature 95 G4double fractionmass, pressure, temperature;
98 96
99 // 97 //
100 // define Elements 98 // define Elements
101 // 99 //
102 100
103 a = 1.01 * g / mole; << 101 a = 1.01*g/mole;
104 auto elH = new G4Element(name = "Hydrogen", << 102 auto elH = new G4Element(name="Hydrogen",symbol="H" , z= 1., a);
105 103
106 a = 12.01 * g / mole; << 104 a = 12.01*g/mole;
107 auto elC = new G4Element(name = "Carbon", sy << 105 auto elC = new G4Element(name="Carbon", symbol="C", z=6., a);
108 106
109 a = 14.01 * g / mole; << 107 a = 14.01*g/mole;
110 auto elN = new G4Element(name = "Nitrogen", << 108 auto elN = new G4Element(name="Nitrogen",symbol="N" , z= 7., a);
111 109
112 a = 16.00 * g / mole; << 110 a = 16.00*g/mole;
113 auto elO = new G4Element(name = "Oxygen", sy << 111 auto elO = new G4Element(name="Oxygen" ,symbol="O" , z= 8., a);
114 112
115 a = 39.948 * g / mole; << 113 a = 39.948*g/mole;
116 auto elAr = new G4Element(name = "Argon", sy << 114 auto elAr = new G4Element(name="Argon", symbol="Ar", z=18., a);
117 115
118 // 116 //
119 // define simple materials 117 // define simple materials
120 // 118 //
121 119
122 // Mylar 120 // Mylar
123 121
124 density = 1.39 * g / cm3; << 122 density = 1.39*g/cm3;
125 auto mylar = new G4Material(name = "Mylar", << 123 auto mylar = new G4Material(name="Mylar", density, nel=3);
126 mylar->AddElement(elO, 2); << 124 mylar->AddElement(elO,2);
127 mylar->AddElement(elC, 5); << 125 mylar->AddElement(elC,5);
128 mylar->AddElement(elH, 4); << 126 mylar->AddElement(elH,4);
129 127
130 // Polypropelene 128 // Polypropelene
131 129
132 auto CH2 = new G4Material("Polypropelene", 0 << 130 auto CH2 = new G4Material ("Polypropelene" , 0.91*g/cm3, 2);
133 CH2->AddElement(elH, 2); << 131 CH2->AddElement(elH,2);
134 CH2->AddElement(elC, 1); << 132 CH2->AddElement(elC,1);
135 133
136 // Krypton as detector gas, STP 134 // Krypton as detector gas, STP
137 135
138 density = 3.700 * mg / cm3; << 136 density = 3.700*mg/cm3;
139 a = 83.80 * g / mole; << 137 a = 83.80*g/mole;
140 auto Kr = new G4Material(name = "Kr", z = 36 << 138 auto Kr = new G4Material(name="Kr",z=36., a, density );
141 139
142 // Dry air (average composition) 140 // Dry air (average composition)
143 141
144 density = 1.7836 * mg / cm3; // STP << 142 density = 1.7836*mg/cm3; // STP
145 auto argon = new G4Material(name = "Argon", << 143 auto argon = new G4Material(name="Argon" , density, ncomponents=1);
146 argon->AddElement(elAr, 1); 144 argon->AddElement(elAr, 1);
147 145
148 density = 1.25053 * mg / cm3; // STP << 146 density = 1.25053*mg/cm3; // STP
149 auto nitrogen = new G4Material(name = "N2", << 147 auto nitrogen = new G4Material(name="N2" , density, ncomponents=1);
150 nitrogen->AddElement(elN, 2); 148 nitrogen->AddElement(elN, 2);
151 149
152 density = 1.4289 * mg / cm3; // STP << 150 density = 1.4289*mg/cm3; // STP
153 auto oxygen = new G4Material(name = "O2", de << 151 auto oxygen = new G4Material(name="O2" , density, ncomponents=1);
154 oxygen->AddElement(elO, 2); 152 oxygen->AddElement(elO, 2);
155 153
156 density = 1.2928 * mg / cm3; // STP << 154 density = 1.2928*mg/cm3; // STP
157 155
158 temperature = STP_Temperature; 156 temperature = STP_Temperature;
159 pressure = 1.0e-0 * STP_Pressure; << 157 pressure = 1.0e-0*STP_Pressure;
160 158
161 auto air = << 159 auto air = new G4Material(name="Air" , density, ncomponents=3,
162 new G4Material(name = "Air", density, ncom << 160 kStateGas,temperature,pressure);
163 air->AddMaterial(nitrogen, fractionmass = 0. << 161 air->AddMaterial( nitrogen, fractionmass = 0.7557 );
164 air->AddMaterial(oxygen, fractionmass = 0.23 << 162 air->AddMaterial( oxygen, fractionmass = 0.2315 );
165 air->AddMaterial(argon, fractionmass = 0.012 << 163 air->AddMaterial( argon, fractionmass = 0.0128 );
166 164
167 // Xenon as detector gas, STP 165 // Xenon as detector gas, STP
168 166
169 density = 5.858 * mg / cm3; << 167 density = 5.858*mg/cm3;
170 a = 131.29 * g / mole; << 168 a = 131.29*g/mole;
171 auto Xe = new G4Material(name = "Xenon", z = << 169 auto Xe = new G4Material(name="Xenon",z=54., a, density );
172 170
173 // Carbon dioxide, STP 171 // Carbon dioxide, STP
174 172
175 density = 1.842 * mg / cm3; << 173 density = 1.842*mg/cm3;
176 auto CarbonDioxide = new G4Material(name = " << 174 auto CarbonDioxide = new G4Material(name="CO2", density, nel=2);
177 CarbonDioxide->AddElement(elC, 1); << 175 CarbonDioxide->AddElement(elC,1);
178 CarbonDioxide->AddElement(elO, 2); << 176 CarbonDioxide->AddElement(elO,2);
179 177
180 // 80% Xe + 20% CO2, STP 178 // 80% Xe + 20% CO2, STP
181 179
182 density = 5.0818 * mg / cm3; << 180 density = 5.0818*mg/cm3;
183 auto Xe20CO2 = new G4Material(name = "Xe20CO << 181 auto Xe20CO2 = new G4Material(name="Xe20CO2", density, ncomponents=2);
184 Xe20CO2->AddMaterial(Xe, fractionmass = 0.92 << 182 Xe20CO2->AddMaterial( Xe, fractionmass = 0.922 );
185 Xe20CO2->AddMaterial(CarbonDioxide, fraction << 183 Xe20CO2->AddMaterial( CarbonDioxide, fractionmass = 0.078 );
186 184
187 // 80% Kr + 20% CO2, STP 185 // 80% Kr + 20% CO2, STP
188 186
189 density = 3.601 * mg / cm3; << 187 density = 3.601*mg/cm3;
190 auto Kr20CO2 = new G4Material(name = "Kr20CO << 188 auto Kr20CO2 = new G4Material(name="Kr20CO2", density, ncomponents=2);
191 Kr20CO2->AddMaterial(Kr, fractionmass = 0.89 << 189 Kr20CO2->AddMaterial( Kr, fractionmass = 0.89 );
192 Kr20CO2->AddMaterial(CarbonDioxide, fraction << 190 Kr20CO2->AddMaterial( CarbonDioxide, fractionmass = 0.11 );
193 191
194 G4cout << *(G4Material::GetMaterialTable()) 192 G4cout << *(G4Material::GetMaterialTable()) << G4endl;
195 193
196 // default materials of the calorimeter 194 // default materials of the calorimeter
197 195
198 fAbsorberMaterial = Kr20CO2; // XeCO2CF4; << 196 fAbsorberMaterial = Kr20CO2; // XeCO2CF4;
199 197
200 fWorldMaterial = air; << 198 fWorldMaterial = air;
201 } 199 }
202 200
203 //....oooOO0OOooo........oooOO0OOooo........oo 201 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
204 202
205 G4VPhysicalVolume* F02DetectorConstruction::Co 203 G4VPhysicalVolume* F02DetectorConstruction::ConstructCalorimeter()
206 { 204 {
207 // Cleanup old geometry 205 // Cleanup old geometry
208 206
209 if (fPhysiWorld) { << 207 if (fPhysiWorld)
>> 208 {
210 G4GeometryManager::GetInstance()->OpenGeom 209 G4GeometryManager::GetInstance()->OpenGeometry();
211 G4PhysicalVolumeStore::GetInstance()->Clea 210 G4PhysicalVolumeStore::GetInstance()->Clean();
212 G4LogicalVolumeStore::GetInstance()->Clean 211 G4LogicalVolumeStore::GetInstance()->Clean();
213 G4SolidStore::GetInstance()->Clean(); 212 G4SolidStore::GetInstance()->Clean();
214 } 213 }
215 214
216 // complete the Calor parameters definition 215 // complete the Calor parameters definition and Print
217 216
218 ComputeCalorParameters(); 217 ComputeCalorParameters();
219 PrintCalorParameters(); 218 PrintCalorParameters();
220 219
221 // World 220 // World
222 221
223 fSolidWorld = new G4Tubs("World", // its na << 222 fSolidWorld = new G4Tubs("World", // its name
224 0., fWorldSizeR, fW << 223 0.,fWorldSizeR,fWorldSizeZ/2.,0.,twopi);// its size
225 224
226 fLogicWorld = new G4LogicalVolume(fSolidWorl << 225 fLogicWorld = new G4LogicalVolume(fSolidWorld, // its solid
227 fWorldMate << 226 fWorldMaterial, // its material
228 "World"); << 227 "World"); // its name
229 << 228
230 fPhysiWorld = new G4PVPlacement(nullptr, // << 229 fPhysiWorld = new G4PVPlacement(nullptr, // no rotation
231 G4ThreeVecto << 230 G4ThreeVector(), // at (0,0,0)
232 "World", // << 231 "World", // its name
233 fLogicWorld, << 232 fLogicWorld, // its logical volume
234 nullptr, // << 233 nullptr, // its mother volume
235 false, // n << 234 false, // no boolean op.
236 0); // copy << 235 0); // copy number
237 // Absorber 236 // Absorber
238 237
239 fSolidAbsorber = new G4Tubs("Absorber", 0., << 238 fSolidAbsorber = new G4Tubs("Absorber",0.,
240 << 239 fAbsorberRadius,
241 fLogicAbsorber = new G4LogicalVolume(fSolidA << 240 fAbsorberThickness/2.,
242 << 241 0.0,twopi);
243 fPhysiAbsorber = new G4PVPlacement(nullptr, << 242
244 fLogicAbs << 243 fLogicAbsorber = new G4LogicalVolume(fSolidAbsorber,
>> 244 fAbsorberMaterial,
>> 245 "Absorber");
>> 246
>> 247 fPhysiAbsorber = new G4PVPlacement(nullptr,
>> 248 G4ThreeVector(0.,0.,fZAbsorber),
>> 249 "Absorber",
>> 250 fLogicAbsorber,
>> 251 fPhysiWorld,
>> 252 false,
>> 253 0);
245 254
246 return fPhysiWorld; 255 return fPhysiWorld;
247 } 256 }
248 257
249 //....oooOO0OOooo........oooOO0OOooo........oo 258 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
250 259
251 void F02DetectorConstruction::PrintCalorParame 260 void F02DetectorConstruction::PrintCalorParameters()
252 { 261 {
253 G4cout << "\n The WORLD is made of " << f << 262 G4cout << "\n The WORLD is made of "
254 << fWorldMaterial->GetName(); << 263 << fWorldSizeZ/mm << "mm of " << fWorldMaterial->GetName();
255 G4cout << ", the transverse size (R) of the << 264 G4cout << ", the transverse size (R) of the world is "
256 G4cout << " The ABSORBER is made of " << fAb << 265 << fWorldSizeR/mm << " mm. " << G4endl;
257 << fAbsorberMaterial->GetName(); << 266 G4cout << " The ABSORBER is made of "
258 G4cout << ", the transverse size (R) is " << << 267 << fAbsorberThickness/mm << "mm of " << fAbsorberMaterial->GetName();
259 G4cout << " Z position of the (middle of the << 268 G4cout << ", the transverse size (R) is " << fAbsorberRadius/mm
>> 269 << " mm. " << G4endl;
>> 270 G4cout << " Z position of the (middle of the) absorber "
>> 271 << fZAbsorber/mm << " mm." << G4endl;
260 G4cout << G4endl; 272 G4cout << G4endl;
261 } 273 }
262 274
263 //....oooOO0OOooo........oooOO0OOooo........oo 275 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
264 276
265 void F02DetectorConstruction::SetAbsorberMater 277 void F02DetectorConstruction::SetAbsorberMaterial(G4String materialChoice)
266 { 278 {
267 // get the pointer to the material table 279 // get the pointer to the material table
268 const G4MaterialTable* theMaterialTable = G4 280 const G4MaterialTable* theMaterialTable = G4Material::GetMaterialTable();
269 281
270 // search the material by its name 282 // search the material by its name
271 G4Material* material; 283 G4Material* material;
272 for (size_t j = 0; j < theMaterialTable->siz << 284 for (size_t j=0 ; j<theMaterialTable->size() ; j++)
273 material = (*theMaterialTable)[j]; << 285 { material = (*theMaterialTable)[j];
274 if (material->GetName() == materialChoice) << 286 if (material->GetName() == materialChoice)
275 fAbsorberMaterial = material; << 287 {
276 fLogicAbsorber->SetMaterial(material); << 288 fAbsorberMaterial = material;
277 G4RunManager::GetRunManager()->PhysicsHa << 289 fLogicAbsorber->SetMaterial(material);
278 } << 290 G4RunManager::GetRunManager()->PhysicsHasBeenModified();
279 } << 291 }
>> 292 }
280 } 293 }
281 294
282 //....oooOO0OOooo........oooOO0OOooo........oo 295 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
283 296
284 void F02DetectorConstruction::SetWorldMaterial 297 void F02DetectorConstruction::SetWorldMaterial(G4String materialChoice)
285 { 298 {
286 // get the pointer to the material table 299 // get the pointer to the material table
287 const G4MaterialTable* theMaterialTable = G4 300 const G4MaterialTable* theMaterialTable = G4Material::GetMaterialTable();
288 301
289 // search the material by its name 302 // search the material by its name
290 G4Material* material; 303 G4Material* material;
291 for (size_t j = 0; j < theMaterialTable->siz << 304 for (size_t j=0 ; j<theMaterialTable->size() ; j++)
292 material = (*theMaterialTable)[j]; << 305 { material = (*theMaterialTable)[j];
293 if (material->GetName() == materialChoice) << 306 if(material->GetName() == materialChoice)
294 fWorldMaterial = material; << 307 {
295 fLogicWorld->SetMaterial(material); << 308 fWorldMaterial = material;
296 G4RunManager::GetRunManager()->PhysicsHa << 309 fLogicWorld->SetMaterial(material);
297 } << 310 G4RunManager::GetRunManager()->PhysicsHasBeenModified();
298 } << 311 }
>> 312 }
299 } 313 }
300 314
301 //....oooOO0OOooo........oooOO0OOooo........oo 315 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
302 316
303 void F02DetectorConstruction::SetAbsorberThick 317 void F02DetectorConstruction::SetAbsorberThickness(G4double val)
304 { 318 {
305 // change Absorber thickness and recompute t 319 // change Absorber thickness and recompute the calorimeter parameters
306 fAbsorberThickness = val; 320 fAbsorberThickness = val;
307 ComputeCalorParameters(); 321 ComputeCalorParameters();
308 G4RunManager::GetRunManager()->GeometryHasBe << 322 G4RunManager::GetRunManager()->ReinitializeGeometry();
309 } 323 }
310 324
311 //....oooOO0OOooo........oooOO0OOooo........oo 325 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
312 326
313 void F02DetectorConstruction::SetAbsorberRadiu 327 void F02DetectorConstruction::SetAbsorberRadius(G4double val)
314 { 328 {
315 // change the transverse size and recompute 329 // change the transverse size and recompute the calorimeter parameters
316 fAbsorberRadius = val; 330 fAbsorberRadius = val;
317 ComputeCalorParameters(); 331 ComputeCalorParameters();
318 G4RunManager::GetRunManager()->GeometryHasBe << 332 G4RunManager::GetRunManager()->ReinitializeGeometry();
319 } 333 }
320 334
321 //....oooOO0OOooo........oooOO0OOooo........oo 335 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
322 336
323 void F02DetectorConstruction::SetWorldSizeZ(G4 337 void F02DetectorConstruction::SetWorldSizeZ(G4double val)
324 { 338 {
325 fWorldChanged = true; 339 fWorldChanged = true;
326 fWorldSizeZ = val; 340 fWorldSizeZ = val;
327 ComputeCalorParameters(); 341 ComputeCalorParameters();
328 G4RunManager::GetRunManager()->GeometryHasBe << 342 G4RunManager::GetRunManager()->ReinitializeGeometry();
329 } 343 }
330 344
331 //....oooOO0OOooo........oooOO0OOooo........oo 345 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
332 346
333 void F02DetectorConstruction::SetWorldSizeR(G4 347 void F02DetectorConstruction::SetWorldSizeR(G4double val)
334 { 348 {
335 fWorldChanged = true; 349 fWorldChanged = true;
336 fWorldSizeR = val; 350 fWorldSizeR = val;
337 ComputeCalorParameters(); 351 ComputeCalorParameters();
338 G4RunManager::GetRunManager()->GeometryHasBe << 352 G4RunManager::GetRunManager()->ReinitializeGeometry();
339 } 353 }
340 354
341 //....oooOO0OOooo........oooOO0OOooo........oo 355 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
342 356
343 void F02DetectorConstruction::SetAbsorberZpos( 357 void F02DetectorConstruction::SetAbsorberZpos(G4double val)
344 { 358 {
345 fZAbsorber = val; 359 fZAbsorber = val;
346 ComputeCalorParameters(); 360 ComputeCalorParameters();
347 G4RunManager::GetRunManager()->GeometryHasBe << 361 G4RunManager::GetRunManager()->ReinitializeGeometry();
348 } <<
349 <<
350 //....oooOO0OOooo........oooOO0OOooo........oo <<
351 <<
352 void F02DetectorConstruction::SetFieldValue(G4 <<
353 { <<
354 fFieldVector = value; <<
355 <<
356 G4UniformElectricField* elField = nullptr; <<
357 if (fFieldVector != G4ThreeVector(0.,0.,0.)) <<
358 elField = new G4UniformElectricField(fFiel <<
359 } <<
360 <<
361 // Set field to the field builder <<
362 auto fieldBuilder = G4FieldBuilder::Instance <<
363 fieldBuilder->SetGlobalField(elField); <<
364 } 362 }
365 363
366 //....oooOO0OOooo........oooOO0OOooo........oo 364 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
367 365
368 void F02DetectorConstruction::ConstructSDandFi 366 void F02DetectorConstruction::ConstructSDandField()
369 { 367 {
370 // Sensitive Detectors: Absorber 368 // Sensitive Detectors: Absorber
371 369
372 if (!fCalorimeterSD.Get()) { 370 if (!fCalorimeterSD.Get()) {
373 auto calorimeterSD = new F02CalorimeterSD( << 371 auto calorimeterSD = new F02CalorimeterSD("CalorSD",this);
374 fCalorimeterSD.Put(calorimeterSD); 372 fCalorimeterSD.Put(calorimeterSD);
375 } 373 }
376 G4SDManager::GetSDMpointer()->AddNewDetector 374 G4SDManager::GetSDMpointer()->AddNewDetector(fCalorimeterSD.Get());
377 SetSensitiveDetector(fLogicAbsorber, fCalori 375 SetSensitiveDetector(fLogicAbsorber, fCalorimeterSD.Get());
378 376
379 // Create detector field << 377 // Construct the field creator - this will register the field it creates
380 SetFieldValue(fFieldVector); <<
381 378
382 // Construct all Geant4 field objects << 379 if (!fEmFieldSetup.Get()) {
383 auto fieldBuilder = G4FieldBuilder::Instance << 380 auto fieldSetup = new F02ElectricFieldSetup();
384 fieldBuilder->SetFieldType(kElectroMagnetic) << 381 G4AutoDelete::Register(fieldSetup); //Kernel will delete the messenger
385 fieldBuilder->ConstructFieldSetup(); << 382 fEmFieldSetup.Put(fieldSetup);
>> 383 }
386 } 384 }
387 385
388 //....oooOO0OOooo........oooOO0OOooo........oo 386 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
389 387