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Geant4/processes/electromagnetic/lowenergy/src/G4ecpssrFormFactorMixsModel.cc

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Diff markup

Differences between /processes/electromagnetic/lowenergy/src/G4ecpssrFormFactorMixsModel.cc (Version 11.3.0) and /processes/electromagnetic/lowenergy/src/G4ecpssrFormFactorMixsModel.cc (Version 10.3)


  1 //                                                  1 //
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 19 // * technical work of the GEANT4 collaboratio     19 // * technical work of the GEANT4 collaboration.                      *
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 25 //                                                 25 // 
 26 // History:                                        26 // History:
 27 // -----------                                     27 // -----------
 28 //  01 Oct 2011   A.M., S.I. - 1st implementat     28 //  01 Oct 2011   A.M., S.I. - 1st implementation
 29 //                                                 29 // 
 30 // Class description                               30 // Class description
 31 // ----------------                                31 // ----------------
 32 //  Computation of K, L & M shell ECPSSR ionis     32 //  Computation of K, L & M shell ECPSSR ionisation cross sections for protons and alphas
 33 //  Based on the work of A. Taborda et al.         33 //  Based on the work of A. Taborda et al. 
 34 //  EXRS2012 proceedings                           34 //  EXRS2012 proceedings
 35 // -------------------------------------------     35 // ---------------------------------------------------------------------------------------
 36                                                    36 
 37 #include <fstream>                                 37 #include <fstream>
 38 #include <iomanip>                                 38 #include <iomanip>
                                                   >>  39 
 39 #include "globals.hh"                              40 #include "globals.hh"
 40 #include "G4ios.hh"                                41 #include "G4ios.hh"
 41 #include "G4SystemOfUnits.hh"                      42 #include "G4SystemOfUnits.hh"
                                                   >>  43 
 42 #include "G4EMDataSet.hh"                          44 #include "G4EMDataSet.hh"
 43 #include "G4LinInterpolation.hh"                   45 #include "G4LinInterpolation.hh"
 44 #include "G4Proton.hh"                             46 #include "G4Proton.hh"
 45 #include "G4Alpha.hh"                              47 #include "G4Alpha.hh"
                                                   >>  48 
 46 #include "G4ecpssrFormFactorMixsModel.hh"          49 #include "G4ecpssrFormFactorMixsModel.hh"
 47                                                    50 
 48 //....oooOO0OOooo........oooOO0OOooo........oo     51 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
 49                                                    52 
 50 G4ecpssrFormFactorMixsModel::G4ecpssrFormFacto     53 G4ecpssrFormFactorMixsModel::G4ecpssrFormFactorMixsModel()
 51 {                                                  54 { 
 52   interpolation = new G4LinInterpolation();        55   interpolation = new G4LinInterpolation();
 53                                                    56 
 54   for (G4int i=29; i<93; i++)                  <<  57   for (G4int i=62; i<93; i++) 
 55   {                                                58   {
 56       protonM1DataSetMap[i] = new G4EMDataSet(     59       protonM1DataSetMap[i] = new G4EMDataSet(i,interpolation);
 57       protonM1DataSetMap[i]->LoadData("pixe/ec <<  60       protonM1DataSetMap[i]->LoadData("pixe/ecpssr/proton/m1-");
 58                                                    61       
 59       protonM2DataSetMap[i] = new G4EMDataSet(     62       protonM2DataSetMap[i] = new G4EMDataSet(i,interpolation);
 60       protonM2DataSetMap[i]->LoadData("pixe/ec <<  63       protonM2DataSetMap[i]->LoadData("pixe/ecpssr/proton/m2-");
 61                                                    64       
 62       protonM3DataSetMap[i] = new G4EMDataSet(     65       protonM3DataSetMap[i] = new G4EMDataSet(i,interpolation);
 63       protonM3DataSetMap[i]->LoadData("pixe/ec <<  66       protonM3DataSetMap[i]->LoadData("pixe/ecpssr/proton/m3-");
 64                                                    67       
 65       protonM4DataSetMap[i] = new G4EMDataSet(     68       protonM4DataSetMap[i] = new G4EMDataSet(i,interpolation);
 66       protonM4DataSetMap[i]->LoadData("pixe/ec <<  69       protonM4DataSetMap[i]->LoadData("pixe/ecpssr/proton/m4-");
 67                                                    70       
 68       protonM5DataSetMap[i] = new G4EMDataSet(     71       protonM5DataSetMap[i] = new G4EMDataSet(i,interpolation);
 69       protonM5DataSetMap[i]->LoadData("pixe/ec <<  72       protonM5DataSetMap[i]->LoadData("pixe/ecpssr/proton/m5-");
 70   }                                                73   }
 71                                                    74 
 72   protonMiXsVector.push_back(protonM1DataSetMa     75   protonMiXsVector.push_back(protonM1DataSetMap);
 73   protonMiXsVector.push_back(protonM2DataSetMa     76   protonMiXsVector.push_back(protonM2DataSetMap);
 74   protonMiXsVector.push_back(protonM3DataSetMa     77   protonMiXsVector.push_back(protonM3DataSetMap);
 75   protonMiXsVector.push_back(protonM4DataSetMa     78   protonMiXsVector.push_back(protonM4DataSetMap);
 76   protonMiXsVector.push_back(protonM5DataSetMa     79   protonMiXsVector.push_back(protonM5DataSetMap);
 77                                                    80 
 78   for (G4int i=29; i<93; i++)                  <<  81 
                                                   >>  82   for (G4int i=62; i<93; i++) 
 79   {                                                83   {
 80       alphaM1DataSetMap[i] = new G4EMDataSet(i     84       alphaM1DataSetMap[i] = new G4EMDataSet(i,interpolation);
 81       alphaM1DataSetMap[i]->LoadData("pixe/ecp <<  85       alphaM1DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m1-");
 82                                                    86        
 83       alphaM2DataSetMap[i] = new G4EMDataSet(i     87       alphaM2DataSetMap[i] = new G4EMDataSet(i,interpolation);
 84       alphaM2DataSetMap[i]->LoadData("pixe/ecp <<  88       alphaM2DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m2-");
 85                                                    89        
 86       alphaM3DataSetMap[i] = new G4EMDataSet(i     90       alphaM3DataSetMap[i] = new G4EMDataSet(i,interpolation);
 87       alphaM3DataSetMap[i]->LoadData("pixe/ecp <<  91       alphaM3DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m3-");
 88                                                    92        
 89       alphaM4DataSetMap[i] = new G4EMDataSet(i     93       alphaM4DataSetMap[i] = new G4EMDataSet(i,interpolation);
 90       alphaM4DataSetMap[i]->LoadData("pixe/ecp <<  94       alphaM4DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m4-");
 91                                                    95        
 92       alphaM5DataSetMap[i] = new G4EMDataSet(i     96       alphaM5DataSetMap[i] = new G4EMDataSet(i,interpolation);
 93       alphaM5DataSetMap[i]->LoadData("pixe/ecp <<  97       alphaM5DataSetMap[i]->LoadData("pixe/ecpssr/alpha/m5-");
 94                                                    98 
 95   }                                                99   }
 96                                                   100 
 97   alphaMiXsVector.push_back(alphaM1DataSetMap)    101   alphaMiXsVector.push_back(alphaM1DataSetMap);
 98   alphaMiXsVector.push_back(alphaM2DataSetMap)    102   alphaMiXsVector.push_back(alphaM2DataSetMap);
 99   alphaMiXsVector.push_back(alphaM3DataSetMap)    103   alphaMiXsVector.push_back(alphaM3DataSetMap);
100   alphaMiXsVector.push_back(alphaM4DataSetMap)    104   alphaMiXsVector.push_back(alphaM4DataSetMap);
101   alphaMiXsVector.push_back(alphaM5DataSetMap)    105   alphaMiXsVector.push_back(alphaM5DataSetMap);
                                                   >> 106 
                                                   >> 107 
                                                   >> 108 
102 }                                                 109 }
103                                                   110 
104 //....oooOO0OOooo........oooOO0OOooo........oo    111 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
105                                                   112 
106 G4ecpssrFormFactorMixsModel::~G4ecpssrFormFact    113 G4ecpssrFormFactorMixsModel::~G4ecpssrFormFactorMixsModel()
107 {                                                 114 { 
108   protonM1DataSetMap.clear();                     115   protonM1DataSetMap.clear();
109   alphaM1DataSetMap.clear();                      116   alphaM1DataSetMap.clear();
110                                                   117   
111   protonM2DataSetMap.clear();                     118   protonM2DataSetMap.clear();
112   alphaM2DataSetMap.clear();                      119   alphaM2DataSetMap.clear();
113                                                   120   
114   protonM3DataSetMap.clear();                     121   protonM3DataSetMap.clear();
115   alphaM3DataSetMap.clear();                      122   alphaM3DataSetMap.clear();
116                                                   123   
117   protonM4DataSetMap.clear();                     124   protonM4DataSetMap.clear();
118   alphaM4DataSetMap.clear();                      125   alphaM4DataSetMap.clear();
119                                                   126   
120   protonM5DataSetMap.clear();                     127   protonM5DataSetMap.clear();
121   alphaM5DataSetMap.clear();                      128   alphaM5DataSetMap.clear();
122                                                   129   
123   delete interpolation;                           130   delete interpolation;
124 }                                                 131 }
125                                                   132 
126 //....oooOO0OOooo........oooOO0OOooo........oo    133 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
127                                                   134 
128 G4double G4ecpssrFormFactorMixsModel::Calculat    135 G4double G4ecpssrFormFactorMixsModel::CalculateMiCrossSection(G4int zTarget,G4double massIncident, G4double energyIncident, G4int mShellId)
129 {                                                 136 {
130   G4Proton* aProton = G4Proton::Proton();         137   G4Proton* aProton = G4Proton::Proton();
131   G4Alpha* aAlpha = G4Alpha::Alpha();             138   G4Alpha* aAlpha = G4Alpha::Alpha();  
132   G4double sigma = 0;                             139   G4double sigma = 0;
133   G4int mShellIndex = mShellId -1;                140   G4int mShellIndex = mShellId -1;
134                                                   141 
135   if (energyIncident > 0.1*MeV && energyIncide << 142   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {
136                                                   143 
137     if (massIncident == aProton->GetPDGMass())    144     if (massIncident == aProton->GetPDGMass())
138       {                                           145       {      
139   sigma = protonMiXsVector[mShellIndex][zTarge    146   sigma = protonMiXsVector[mShellIndex][zTarget]->FindValue(energyIncident/MeV);  
140         if (sigma !=0 && energyIncident > prot    147         if (sigma !=0 && energyIncident > protonMiXsVector[mShellIndex][zTarget]->GetEnergies(0).back()*MeV) return 0.;
141       }                                           148       }
142     else if (massIncident == aAlpha->GetPDGMas    149     else if (massIncident == aAlpha->GetPDGMass())
143       {                                           150       {
144         sigma = alphaMiXsVector[mShellIndex][z    151         sigma = alphaMiXsVector[mShellIndex][zTarget]->FindValue(energyIncident/MeV); 
145         if (sigma !=0 && energyIncident > alph    152         if (sigma !=0 && energyIncident > alphaMiXsVector[mShellIndex][zTarget]->GetEnergies(0).back()*MeV) return 0.;
146       }                                           153       }
147     else                                          154     else
148       {                                           155       { 
149   sigma = 0.;                                     156   sigma = 0.;
150       }                                           157       }
151   }                                               158   }
152                                                   159   
153   // sigma is in internal units: it has been c    160   // sigma is in internal units: it has been converted from 
154   // the input file in barns bt the EmDataset     161   // the input file in barns bt the EmDataset
155   return sigma;                                   162   return sigma;
156 }                                                 163 }
157                                                   164 
158 //....oooOO0OOooo........oooOO0OOooo........oo    165 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
159                                                   166 
160 G4double G4ecpssrFormFactorMixsModel::Calculat    167 G4double G4ecpssrFormFactorMixsModel::CalculateM1CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
161 {                                                 168 {
                                                   >> 169 
162   // mShellId                                     170   // mShellId
163   return  CalculateMiCrossSection (zTarget, ma    171   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 1); 
                                                   >> 172 
164 }                                                 173 }
165                                                   174 
166 //....oooOO0OOooo........oooOO0OOooo........oo    175 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
167                                                   176 
168 G4double G4ecpssrFormFactorMixsModel::Calculat    177 G4double G4ecpssrFormFactorMixsModel::CalculateM2CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
169 {                                                 178 {
                                                   >> 179 
170   // mShellId                                     180   // mShellId
171   return  CalculateMiCrossSection (zTarget, ma    181   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 2); 
                                                   >> 182 
                                                   >> 183   /*
                                                   >> 184 
                                                   >> 185   G4Proton* aProton = G4Proton::Proton();
                                                   >> 186   G4Alpha* aAlpha = G4Alpha::Alpha();  
                                                   >> 187   G4double sigma = 0;
                                                   >> 188 
                                                   >> 189   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {
                                                   >> 190 
                                                   >> 191     if (massIncident == aProton->GetPDGMass())
                                                   >> 192       {      
                                                   >> 193   sigma = protonM2DataSetMap[zTarget]->FindValue(energyIncident/MeV);  
                                                   >> 194         if (sigma !=0 && energyIncident > protonM2DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 195       }
                                                   >> 196     else if (massIncident == aAlpha->GetPDGMass())
                                                   >> 197       {
                                                   >> 198         sigma = alphaM2DataSetMap[zTarget]->FindValue(energyIncident/MeV); 
                                                   >> 199         if (sigma !=0 && energyIncident > alphaM2DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 200       }
                                                   >> 201     else
                                                   >> 202       { 
                                                   >> 203   sigma = 0.;
                                                   >> 204       }
                                                   >> 205   }
                                                   >> 206   
                                                   >> 207   // sigma is in internal units: it has been converted from 
                                                   >> 208   // the input file in barns bt the EmDataset
                                                   >> 209   return sigma;
                                                   >> 210   */
172 }                                                 211 }
173                                                   212 
174 //....oooOO0OOooo........oooOO0OOooo........oo    213 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
175                                                   214 
176 G4double G4ecpssrFormFactorMixsModel::Calculat    215 G4double G4ecpssrFormFactorMixsModel::CalculateM3CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
177 {                                                 216 {
                                                   >> 217 
178   return  CalculateMiCrossSection (zTarget, ma    218   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 3); 
                                                   >> 219   /*
                                                   >> 220 
                                                   >> 221 
                                                   >> 222   G4Proton* aProton = G4Proton::Proton();
                                                   >> 223   G4Alpha* aAlpha = G4Alpha::Alpha();  
                                                   >> 224   G4double sigma = 0;
                                                   >> 225 
                                                   >> 226   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {
                                                   >> 227 
                                                   >> 228     if (massIncident == aProton->GetPDGMass())
                                                   >> 229       {      
                                                   >> 230   sigma = protonM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);  
                                                   >> 231         if (sigma !=0 && energyIncident > protonM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 232       }
                                                   >> 233     else if (massIncident == aAlpha->GetPDGMass())
                                                   >> 234       {
                                                   >> 235         sigma = alphaM3DataSetMap[zTarget]->FindValue(energyIncident/MeV); 
                                                   >> 236         if (sigma !=0 && energyIncident > alphaM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 237       }
                                                   >> 238     else
                                                   >> 239       { 
                                                   >> 240   sigma = 0.;
                                                   >> 241       }
                                                   >> 242   }
                                                   >> 243   
                                                   >> 244   // sigma is in internal units: it has been converted from 
                                                   >> 245   // the input file in barns bt the EmDataset
                                                   >> 246   return sigma;
                                                   >> 247   */
179 }                                                 248 }
180                                                   249 
181 //....oooOO0OOooo........oooOO0OOooo........oo    250 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
182                                                   251 
183 G4double G4ecpssrFormFactorMixsModel::Calculat    252 G4double G4ecpssrFormFactorMixsModel::CalculateM4CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
184 {                                                 253 {
                                                   >> 254 
185   return  CalculateMiCrossSection (zTarget, ma    255   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 4); 
                                                   >> 256   /*
                                                   >> 257   G4Proton* aProton = G4Proton::Proton();
                                                   >> 258   G4Alpha* aAlpha = G4Alpha::Alpha();  
                                                   >> 259   G4double sigma = 0;
                                                   >> 260 
                                                   >> 261   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {
                                                   >> 262 
                                                   >> 263     if (massIncident == aProton->GetPDGMass())
                                                   >> 264       {      
                                                   >> 265   sigma = protonM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);  
                                                   >> 266         if (sigma !=0 && energyIncident > protonM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 267       }
                                                   >> 268     else if (massIncident == aAlpha->GetPDGMass())
                                                   >> 269       {
                                                   >> 270         sigma = alphaM3DataSetMap[zTarget]->FindValue(energyIncident/MeV); 
                                                   >> 271         if (sigma !=0 && energyIncident > alphaM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 272       }
                                                   >> 273     else
                                                   >> 274       { 
                                                   >> 275   sigma = 0.;
                                                   >> 276       }
                                                   >> 277   }
                                                   >> 278   
                                                   >> 279   // sigma is in internal units: it has been converted from 
                                                   >> 280   // the input file in barns bt the EmDataset
                                                   >> 281   return sigma;
                                                   >> 282   */
186 }                                                 283 }
187                                                   284 
188 //....oooOO0OOooo........oooOO0OOooo........oo    285 //....oooOO0OOooo........oooOO0OOooo........oooOO0OOooo........oooOO0OOooo......
189                                                   286 
190 G4double G4ecpssrFormFactorMixsModel::Calculat    287 G4double G4ecpssrFormFactorMixsModel::CalculateM5CrossSection(G4int zTarget,G4double massIncident, G4double energyIncident)
191 {                                                 288 {
                                                   >> 289 
192   return  CalculateMiCrossSection (zTarget, ma    290   return  CalculateMiCrossSection (zTarget, massIncident, energyIncident, 5); 
                                                   >> 291   /*
                                                   >> 292   G4Proton* aProton = G4Proton::Proton();
                                                   >> 293   G4Alpha* aAlpha = G4Alpha::Alpha();  
                                                   >> 294   G4double sigma = 0;
                                                   >> 295 
                                                   >> 296   if (energyIncident > 0.1*MeV && energyIncident < 10*MeV && zTarget < 93 && zTarget > 61) {
                                                   >> 297 
                                                   >> 298     if (massIncident == aProton->GetPDGMass())
                                                   >> 299       {      
                                                   >> 300   sigma = protonM3DataSetMap[zTarget]->FindValue(energyIncident/MeV);  
                                                   >> 301         if (sigma !=0 && energyIncident > protonM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 302       }
                                                   >> 303     else if (massIncident == aAlpha->GetPDGMass())
                                                   >> 304       {
                                                   >> 305         sigma = alphaM3DataSetMap[zTarget]->FindValue(energyIncident/MeV); 
                                                   >> 306         if (sigma !=0 && energyIncident > alphaM3DataSetMap[zTarget]->GetEnergies(0).back()*MeV) return 0.;
                                                   >> 307       }
                                                   >> 308     else
                                                   >> 309       { 
                                                   >> 310   sigma = 0.;
                                                   >> 311       }
                                                   >> 312   }
                                                   >> 313   
                                                   >> 314   // sigma is in internal units: it has been converted from 
                                                   >> 315   // the input file in barns bt the EmDataset
                                                   >> 316   return sigma;
                                                   >> 317   */
193 }                                                 318 }
194                                                   319