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Geant4/processes/electromagnetic/pii/include/G4hImpactIonisation.hh

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Differences between /processes/electromagnetic/pii/include/G4hImpactIonisation.hh (Version 11.3.0) and /processes/electromagnetic/pii/include/G4hImpactIonisation.hh (Version 10.7.p2)


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 25 //                                                 25 //
 26 //                                                 26 //
 27 // -------------------------------------------     27 // ------------------------------------------------------------
 28 // G4hImpactIonisation                             28 // G4hImpactIonisation
 29 //                                                 29 //
 30 //                                                 30 //
 31 // Author: Maria Grazia Pia (MariaGrazia.Pia@g     31 // Author: Maria Grazia Pia (MariaGrazia.Pia@ge.infn.it)
 32 //                                                 32 //
 33 // 08 Sep 2008 - MGP - Created (initially base     33 // 08 Sep 2008 - MGP - Created (initially based on G4hLowEnergyIonisation) 
 34 //                     Added PIXE capabilities     34 //                     Added PIXE capabilities
 35 //                     Partial clean-up of the     35 //                     Partial clean-up of the implementation (more needed)
 36 //                     Calculation of Microsco     36 //                     Calculation of MicroscopicCrossSection delegated to specialised class 
 37 //                                                 37 //
 38 // -------------------------------------------     38 // ------------------------------------------------------------
 39                                                    39  
 40 // Class Description:                              40 // Class Description:
 41 // Impact Ionisation process of charged hadron     41 // Impact Ionisation process of charged hadrons and ions
 42 // Initially based on G4hLowEnergyIonisation,      42 // Initially based on G4hLowEnergyIonisation, to be subject to redesign
 43 // and further evolution of physics capabiliti     43 // and further evolution of physics capabilities
 44 //                                                 44 //
 45 // The physics model of G4hLowEnergyIonisation     45 // The physics model of G4hLowEnergyIonisation is described in 
 46 // CERN-OPEN-99-121 and CERN-OPEN-99-300.          46 // CERN-OPEN-99-121 and CERN-OPEN-99-300. 
 47 //                                                 47 //
 48 // Documentation available in:                     48 // Documentation available in:
 49 // M.G. Pia et al., PIXE Simulation With Geant     49 // M.G. Pia et al., PIXE Simulation With Geant4,
 50 // IEEE Trans. Nucl. Sci., vol. 56, no. 6, pp.     50 // IEEE Trans. Nucl. Sci., vol. 56, no. 6, pp. 3614-3649, Dec. 2009.
 51                                                    51 
 52 // -------------------------------------------     52 // ------------------------------------------------------------
 53                                                    53 
 54 #ifndef G4HIMPACTIONISATION                        54 #ifndef G4HIMPACTIONISATION
 55 #define G4HIMPACTIONISATION 1                      55 #define G4HIMPACTIONISATION 1
 56                                                    56 
 57 #include <map>                                     57 #include <map>
 58 #include <CLHEP/Units/PhysicalConstants.h>         58 #include <CLHEP/Units/PhysicalConstants.h>
 59                                                    59 
 60 #include "globals.hh"                              60 #include "globals.hh"
 61 #include "G4hRDEnergyLoss.hh"                      61 #include "G4hRDEnergyLoss.hh"
 62 #include "G4DataVector.hh"                         62 #include "G4DataVector.hh"
 63 #include "G4AtomicDeexcitation.hh"                 63 #include "G4AtomicDeexcitation.hh"
 64 #include "G4PixeCrossSectionHandler.hh"            64 #include "G4PixeCrossSectionHandler.hh"
 65                                                    65 
 66 class G4VLowEnergyModel;                           66 class G4VLowEnergyModel;
 67 class G4VParticleChange;                           67 class G4VParticleChange;
 68 class G4ParticleDefinition;                        68 class G4ParticleDefinition;
 69 class G4PhysicsTable;                              69 class G4PhysicsTable;
 70 class G4MaterialCutsCouple;                        70 class G4MaterialCutsCouple;
 71 class G4Track;                                     71 class G4Track;
 72 class G4Step;                                      72 class G4Step;
 73                                                    73 
 74 class G4hImpactIonisation : public G4hRDEnergy     74 class G4hImpactIonisation : public G4hRDEnergyLoss
 75 {                                                  75 {
 76 public: // With description                        76 public: // With description
 77                                                    77   
 78   G4hImpactIonisation(const G4String& processN     78   G4hImpactIonisation(const G4String& processName = "hImpactIoni"); 
 79   // The ionisation process for hadrons/ions t     79   // The ionisation process for hadrons/ions to be include in the
 80   // UserPhysicsList                               80   // UserPhysicsList
 81                                                    81 
 82   ~G4hImpactIonisation();                          82   ~G4hImpactIonisation();
 83   // Destructor                                    83   // Destructor
 84                                                    84   
 85   G4bool IsApplicable(const G4ParticleDefiniti     85   G4bool IsApplicable(const G4ParticleDefinition&);
 86   // True for all charged hadrons/ions             86   // True for all charged hadrons/ions
 87                                                    87     
 88   void BuildPhysicsTable(const G4ParticleDefin     88   void BuildPhysicsTable(const G4ParticleDefinition& aParticleType) ;
 89   // Build physics table during initialisation     89   // Build physics table during initialisation
 90                                                    90 
 91   G4double GetMeanFreePath(const G4Track& trac     91   G4double GetMeanFreePath(const G4Track& track,
 92          G4double previousStepSize,                92          G4double previousStepSize,
 93          enum G4ForceCondition* condition );       93          enum G4ForceCondition* condition );
 94   // Return MeanFreePath until delta-electron      94   // Return MeanFreePath until delta-electron production
 95                                                    95   
 96   void PrintInfoDefinition() const;                96   void PrintInfoDefinition() const;
 97   // Print out of the class parameters             97   // Print out of the class parameters
 98                                                    98 
 99   void SetHighEnergyForProtonParametrisation(G     99   void SetHighEnergyForProtonParametrisation(G4double energy) {protonHighEnergy = energy;} ;
100   // Definition of the boundary proton energy.    100   // Definition of the boundary proton energy. For higher energies
101   // Bethe-Bloch formula is used, for lower en    101   // Bethe-Bloch formula is used, for lower energies a parametrisation
102   // of the energy losses is performed. Defaul    102   // of the energy losses is performed. Default is 2 MeV.
103                                                   103 
104   void SetLowEnergyForProtonParametrisation(G4    104   void SetLowEnergyForProtonParametrisation(G4double energy) {protonLowEnergy = energy;} ;
105   // Set of the boundary proton energy. For lo    105   // Set of the boundary proton energy. For lower energies
106   // the Free Electron Gas model is used for t    106   // the Free Electron Gas model is used for the energy losses.
107   // Default is 1 keV.                            107   // Default is 1 keV.
108                                                   108 
109   void SetHighEnergyForAntiProtonParametrisati    109   void SetHighEnergyForAntiProtonParametrisation(G4double energy) {antiprotonHighEnergy = energy;} ;
110   // Set of the boundary antiproton energy. Fo    110   // Set of the boundary antiproton energy. For higher energies
111   // Bethe-Bloch formula is used, for lower en    111   // Bethe-Bloch formula is used, for lower energies parametrisation
112   // of the energy losses is performed. Defaul    112   // of the energy losses is performed. Default is 2 MeV.
113                                                   113 
114   void SetLowEnergyForAntiProtonParametrisatio    114   void SetLowEnergyForAntiProtonParametrisation(G4double energy) {antiprotonLowEnergy = energy;} ;
115   // Set of the boundary antiproton energy. Fo    115   // Set of the boundary antiproton energy. For lower energies
116   // the Free Electron Gas model is used for t    116   // the Free Electron Gas model is used for the energy losses. 
117   // Default is 1 keV.                            117   // Default is 1 keV.
118                                                   118 
119   G4double GetContinuousStepLimit(const G4Trac    119   G4double GetContinuousStepLimit(const G4Track& track,
120           G4double previousStepSize,              120           G4double previousStepSize,
121           G4double currentMinimumStep,            121           G4double currentMinimumStep,
122           G4double& currentSafety);               122           G4double& currentSafety); 
123   // Calculation of the step limit due to ioni    123   // Calculation of the step limit due to ionisation losses
124                                                   124 
125   void SetElectronicStoppingPowerModel(const G    125   void SetElectronicStoppingPowerModel(const G4ParticleDefinition* aParticle,
126                                        const G    126                                        const G4String& dedxTable);
127   // This method defines the electron ionisati    127   // This method defines the electron ionisation parametrisation method 
128   // via the name of the table. Default is "IC    128   // via the name of the table. Default is "ICRU_49p".
129                                                   129 
130   void SetNuclearStoppingPowerModel(const G4St    130   void SetNuclearStoppingPowerModel(const G4String& dedxTable)
131   {theNuclearTable = dedxTable; SetNuclearStop    131   {theNuclearTable = dedxTable; SetNuclearStoppingOn();};
132   // This method defines the nuclear ionisatio    132   // This method defines the nuclear ionisation parametrisation method 
133   // via the name of the table. Default is "IC    133   // via the name of the table. Default is "ICRU_49".
134                                                   134 
135   // ---- MGP ---- The following design of On/    135   // ---- MGP ---- The following design of On/Off is nonsense; to be modified
136   // in a following design iteration              136   // in a following design iteration
137                                                   137 
138   void SetNuclearStoppingOn() {nStopping = tru    138   void SetNuclearStoppingOn() {nStopping = true;};
139   // This method switch on calculation of the     139   // This method switch on calculation of the nuclear stopping power.
140                                                   140   
141   void SetNuclearStoppingOff() {nStopping = fa    141   void SetNuclearStoppingOff() {nStopping = false;};
142   // This method switch off calculation of the    142   // This method switch off calculation of the nuclear stopping power.
143                                                   143 
144   void SetBarkasOn() {theBarkas = true;};         144   void SetBarkasOn() {theBarkas = true;};
145   // This method switch on calculation of the     145   // This method switch on calculation of the Barkas and Bloch effects.
146                                                   146 
147   void SetBarkasOff() {theBarkas = false;};       147   void SetBarkasOff() {theBarkas = false;};
148   // This method switch off calculation of the    148   // This method switch off calculation of the Barkas and Bloch effects.
149                                                   149 
150   void SetPixe(const G4bool /* val */ ) {pixeI    150   void SetPixe(const G4bool /* val */ ) {pixeIsActive = true;};
151   // This method switches atomic relaxation on    151   // This method switches atomic relaxation on/off; currently always on
152                                                   152 
153   G4VParticleChange* AlongStepDoIt(const G4Tra    153   G4VParticleChange* AlongStepDoIt(const G4Track& trackData ,
154                                    const G4Ste    154                                    const G4Step& stepData ) ;
155   // Function to determine total energy deposi    155   // Function to determine total energy deposition on the step
156                                                   156 
157   G4VParticleChange* PostStepDoIt(const G4Trac    157   G4VParticleChange* PostStepDoIt(const G4Track& track,
158           const G4Step& Step  ) ;                 158           const G4Step& Step  ) ;
159   // Simulation of delta-ray production.          159   // Simulation of delta-ray production.
160                                                   160 
161   G4double ComputeDEDX(const G4ParticleDefinit    161   G4double ComputeDEDX(const G4ParticleDefinition* aParticle,
162                        const G4MaterialCutsCou    162                        const G4MaterialCutsCouple* couple,
163            G4double kineticEnergy);               163            G4double kineticEnergy);
164   // This method returns electronic dE/dx for     164   // This method returns electronic dE/dx for protons or antiproton
165                                                   165 
166   void SetCutForSecondaryPhotons(G4double cut)    166   void SetCutForSecondaryPhotons(G4double cut);
167   // Set threshold energy for fluorescence        167   // Set threshold energy for fluorescence
168                                                   168 
169   void SetCutForAugerElectrons(G4double cut);     169   void SetCutForAugerElectrons(G4double cut);
170   // Set threshold energy for Auger electron p    170   // Set threshold energy for Auger electron production
171                                                   171 
172   void ActivateAugerElectronProduction(G4bool     172   void ActivateAugerElectronProduction(G4bool val);
173   // Set Auger electron production flag on/off    173   // Set Auger electron production flag on/off
174                                                   174 
175   // Accessors to configure PIXE                  175   // Accessors to configure PIXE
176   void SetPixeCrossSectionK(const G4String& na    176   void SetPixeCrossSectionK(const G4String& name) { modelK = name; }
177   void SetPixeCrossSectionL(const G4String& na    177   void SetPixeCrossSectionL(const G4String& name) { modelL = name; }
178   void SetPixeCrossSectionM(const G4String& na    178   void SetPixeCrossSectionM(const G4String& name) { modelM = name; }
179   void SetPixeProjectileMinEnergy(G4double ene    179   void SetPixeProjectileMinEnergy(G4double energy) { eMinPixe = energy; }
180   void SetPixeProjectileMaxEnergy(G4double ene    180   void SetPixeProjectileMaxEnergy(G4double energy) { eMaxPixe = energy; }
181                                                   181 
182 protected:                                        182 protected:
183                                                   183 
184 private:                                          184 private:
185                                                   185 
186   void InitializeMe();                            186   void InitializeMe();
187   void InitializeParametrisation();               187   void InitializeParametrisation();
188   void BuildLossTable(const G4ParticleDefiniti    188   void BuildLossTable(const G4ParticleDefinition& aParticleType);
189   // void BuildDataForFluorescence(const G4Par    189   // void BuildDataForFluorescence(const G4ParticleDefinition& aParticleType);
190   void BuildLambdaTable(const G4ParticleDefini    190   void BuildLambdaTable(const G4ParticleDefinition& aParticleType);
191   void SetProtonElectronicStoppingPowerModel(c    191   void SetProtonElectronicStoppingPowerModel(const G4String& dedxTable)
192   {protonTable = dedxTable ;};                    192   {protonTable = dedxTable ;};
193   // This method defines the ionisation parame    193   // This method defines the ionisation parametrisation method via its name
194                                                   194 
195   void SetAntiProtonElectronicStoppingPowerMod    195   void SetAntiProtonElectronicStoppingPowerModel(const G4String& dedxTable)
196   {antiprotonTable = dedxTable;};                 196   {antiprotonTable = dedxTable;};
197                                                   197 
198   G4double MicroscopicCrossSection(const G4Par    198   G4double MicroscopicCrossSection(const G4ParticleDefinition& aParticleType,
199            G4double kineticEnergy,                199            G4double kineticEnergy,
200            G4double atomicNumber,                 200            G4double atomicNumber,
201            G4double deltaCutInEnergy) const;      201            G4double deltaCutInEnergy) const;
202                                                   202 
203   G4double GetConstraints(const G4DynamicParti    203   G4double GetConstraints(const G4DynamicParticle* particle,
204                           const G4MaterialCuts    204                           const G4MaterialCutsCouple* couple);
205   // Function to determine StepLimit              205   // Function to determine StepLimit
206                                                   206 
207   G4double ProtonParametrisedDEDX(const G4Mate    207   G4double ProtonParametrisedDEDX(const G4MaterialCutsCouple* couple,
208           G4double kineticEnergy) const;          208           G4double kineticEnergy) const;
209                                                   209 
210   G4double AntiProtonParametrisedDEDX(const G4    210   G4double AntiProtonParametrisedDEDX(const G4MaterialCutsCouple* couple,
211               G4double kineticEnergy) const;      211               G4double kineticEnergy) const;
212                                                   212 
213   G4double DeltaRaysEnergy(const G4MaterialCut    213   G4double DeltaRaysEnergy(const G4MaterialCutsCouple* couple,
214          G4double kineticEnergy,                  214          G4double kineticEnergy,
215          G4double particleMass) const;            215          G4double particleMass) const;
216   // This method returns average energy loss d    216   // This method returns average energy loss due to delta-rays emission with
217   // energy higher than the cut energy for giv    217   // energy higher than the cut energy for given material.
218                                                   218 
219   G4double BarkasTerm(const G4Material* materi    219   G4double BarkasTerm(const G4Material* material,
220           G4double kineticEnergy) const;          220           G4double kineticEnergy) const;
221   // Function to compute the Barkas term for p    221   // Function to compute the Barkas term for protons
222                                                   222 
223   G4double BlochTerm(const G4Material* materia    223   G4double BlochTerm(const G4Material* material,
224          G4double kineticEnergy,                  224          G4double kineticEnergy,
225          G4double cSquare) const;                 225          G4double cSquare) const;
226   // Function to compute the Bloch term for pr    226   // Function to compute the Bloch term for protons
227                                                   227 
228   G4double ElectronicLossFluctuation(const G4D    228   G4double ElectronicLossFluctuation(const G4DynamicParticle* particle,
229                                      const G4M    229                                      const G4MaterialCutsCouple* material,
230              G4double meanLoss,                   230              G4double meanLoss,
231              G4double step) const;                231              G4double step) const;
232   // Function to sample electronic losses         232   // Function to sample electronic losses
233                                                   233 
234   // hide assignment operator                     234   // hide assignment operator
235   G4hImpactIonisation & operator=(const G4hImp    235   G4hImpactIonisation & operator=(const G4hImpactIonisation &right);
236   G4hImpactIonisation(const G4hImpactIonisatio    236   G4hImpactIonisation(const G4hImpactIonisation&);
237                                                   237 
238 private:                                          238 private:
239   //  private data members ...................    239   //  private data members ...............................
240   G4VLowEnergyModel* betheBlochModel;             240   G4VLowEnergyModel* betheBlochModel;
241   G4VLowEnergyModel* protonModel;                 241   G4VLowEnergyModel* protonModel;
242   G4VLowEnergyModel* antiprotonModel;             242   G4VLowEnergyModel* antiprotonModel;
243   G4VLowEnergyModel* theIonEffChargeModel;        243   G4VLowEnergyModel* theIonEffChargeModel;
244   G4VLowEnergyModel* theNuclearStoppingModel;     244   G4VLowEnergyModel* theNuclearStoppingModel;
245   G4VLowEnergyModel* theIonChuFluctuationModel    245   G4VLowEnergyModel* theIonChuFluctuationModel;
246   G4VLowEnergyModel* theIonYangFluctuationMode    246   G4VLowEnergyModel* theIonYangFluctuationModel;
247                                                   247 
248   // std::map<G4int,G4double,std::less<G4int>     248   // std::map<G4int,G4double,std::less<G4int> > totalCrossSectionMap;
249                                                   249 
250   // name of parametrisation table of electron    250   // name of parametrisation table of electron stopping power
251   G4String protonTable;                           251   G4String protonTable;
252   G4String antiprotonTable;                       252   G4String antiprotonTable;
253   G4String theNuclearTable;                       253   G4String theNuclearTable;
254                                                   254 
255   // interval of parametrisation of electron s    255   // interval of parametrisation of electron stopping power
256   G4double protonLowEnergy;                       256   G4double protonLowEnergy;
257   G4double protonHighEnergy;                      257   G4double protonHighEnergy;
258   G4double antiprotonLowEnergy;                   258   G4double antiprotonLowEnergy;
259   G4double antiprotonHighEnergy;                  259   G4double antiprotonHighEnergy;
260                                                   260 
261   // flag of parametrisation of nucleus stoppi    261   // flag of parametrisation of nucleus stopping power
262   G4bool nStopping;                               262   G4bool nStopping;
263   G4bool theBarkas;                               263   G4bool theBarkas;
264                                                   264 
265   G4DataVector cutForDelta;                       265   G4DataVector cutForDelta;
266   G4DataVector cutForGamma;                       266   G4DataVector cutForGamma;
267   G4double minGammaEnergy;                        267   G4double minGammaEnergy;
268   G4double minElectronEnergy;                     268   G4double minElectronEnergy;
269   G4PhysicsTable* theMeanFreePathTable;           269   G4PhysicsTable* theMeanFreePathTable;
270                                                   270 
271   const G4double paramStepLimit; // parameter     271   const G4double paramStepLimit; // parameter limits the step at low energy
272                                                   272 
273   G4double fdEdx;        // computed in GetCon    273   G4double fdEdx;        // computed in GetContraints
274   G4double fRangeNow ;   //                       274   G4double fRangeNow ;   //
275   G4double charge;       //                       275   G4double charge;       //
276   G4double chargeSquare; //                       276   G4double chargeSquare; //
277   G4double initialMass;  // mass to calculate     277   G4double initialMass;  // mass to calculate Lambda tables
278   G4double fBarkas;                               278   G4double fBarkas;
279                                                   279 
280   G4PixeCrossSectionHandler* pixeCrossSectionH    280   G4PixeCrossSectionHandler* pixeCrossSectionHandler;
281   G4AtomicDeexcitation atomicDeexcitation;        281   G4AtomicDeexcitation atomicDeexcitation;
282   G4String modelK;                                282   G4String modelK;
283   G4String modelL;                                283   G4String modelL;
284   G4String modelM;                                284   G4String modelM;
285   G4double eMinPixe;                              285   G4double eMinPixe;
286   G4double eMaxPixe;                              286   G4double eMaxPixe;
287                                                   287  
288   G4bool pixeIsActive;                            288   G4bool pixeIsActive;
289                                                   289 
290 };                                                290 };
291                                                   291 
292                                                   292 
293 inline G4double G4hImpactIonisation::GetContin    293 inline G4double G4hImpactIonisation::GetContinuousStepLimit(const G4Track& track,
294                   G4double,                       294                   G4double,
295                   G4double currentMinimumStep,    295                   G4double currentMinimumStep,
296                   G4double&)                      296                   G4double&)
297 {                                                 297 {
298   G4double step = GetConstraints(track.GetDyna    298   G4double step = GetConstraints(track.GetDynamicParticle(),track.GetMaterialCutsCouple()) ;
299                                                   299 
300   // ---- MGP ---- The following line, taken a    300   // ---- MGP ---- The following line, taken as is from G4hLowEnergyIonisation,
301   // is meaningless: currentMinimumStep is pas    301   // is meaningless: currentMinimumStep is passed by value,
302   // therefore any local modification to it ha    302   // therefore any local modification to it has no effect
303                                                   303 
304   if ((step > 0.) && (step < currentMinimumSte    304   if ((step > 0.) && (step < currentMinimumStep)) currentMinimumStep = step ;
305                                                   305 
306   return step ;                                   306   return step ;
307 }                                                 307 }
308                                                   308 
309                                                   309 
310 inline G4bool G4hImpactIonisation::IsApplicabl    310 inline G4bool G4hImpactIonisation::IsApplicable(const G4ParticleDefinition& particle)
311 {                                                 311 {
312   // ---- MGP ---- Better criterion for applic    312   // ---- MGP ---- Better criterion for applicability to be defined;
313   // now hard-coded particle mass > 0.1 * prot    313   // now hard-coded particle mass > 0.1 * proton_mass
314                                                   314 
315   return (particle.GetPDGCharge() != 0.0 && pa    315   return (particle.GetPDGCharge() != 0.0 && particle.GetPDGMass() > CLHEP::proton_mass_c2*0.1);
316 }                                                 316 }
317                                                   317 
318 #endif                                            318 #endif
319                                                   319 
320                                                   320 
321                                                   321 
322                                                   322 
323                                                   323 
324                                                   324 
325                                                   325 
326                                                   326 
327                                                   327