Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
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G4Scintillation.hh
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1//
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25//
26////////////////////////////////////////////////////////////////////////
27// Scintillation Light Class Definition
28////////////////////////////////////////////////////////////////////////
29//
30// File: G4Scintillation.hh
31// Description: Discrete Process - Generation of Scintillation Photons
32// Version: 1.0
33// Created: 1998-11-07
34// Author: Peter Gumplinger
35// Updated: 2010-10-20 Allow the scintillation yield to be a function
36// of energy deposited by particle type
37// Thanks to Zach Hartwig (Department of Nuclear
38// Science and Engineeering - MIT)
39// 2005-07-28 add G4ProcessType to constructor
40// 2002-11-21 change to user G4Poisson for small MeanNumPotons
41// 2002-11-07 allow for fast and slow scintillation
42// 2002-11-05 make use of constant material properties
43// 2002-05-16 changed to inherit from VRestDiscreteProcess
44// 2002-05-09 changed IsApplicable method
45// 1999-10-29 add method and class descriptors
46//
47//
48////////////////////////////////////////////////////////////////////////
49
50#ifndef G4Scintillation_h
51#define G4Scintillation_h 1
52
53#include "globals.hh"
54#include "G4EmSaturation.hh"
55#include "G4OpticalPhoton.hh"
57
58class G4PhysicsTable;
59class G4Step;
60class G4Track;
61
62// Class Description:
63// RestDiscrete Process - Generation of Scintillation Photons.
64// Class inherits publicly from G4VRestDiscreteProcess.
65// Class Description - End:
66
68{
69 public:
70 explicit G4Scintillation(const G4String& processName = "Scintillation",
73
74 G4Scintillation(const G4Scintillation& right) = delete;
75 G4Scintillation& operator=(const G4Scintillation& right) = delete;
76
77 // G4Scintillation Process has both PostStepDoIt (for energy
78 // deposition of particles in flight) and AtRestDoIt (for energy
79 // given to the medium by particles at rest)
80
81 G4bool IsApplicable(const G4ParticleDefinition& aParticleType) override;
82 // Returns true -> 'is applicable', for any particle type except
83 // for an 'opticalphoton' and for short-lived particles
84
85 void ProcessDescription(std::ostream&) const override;
86 void DumpInfo() const override {ProcessDescription(G4cout);};
87
88 void BuildPhysicsTable(const G4ParticleDefinition& aParticleType) override;
89 // Build table at the right time
90
91 void PreparePhysicsTable(const G4ParticleDefinition& part) override;
92 void Initialise();
93
95 G4ForceCondition*) override;
96 // Returns infinity; i. e. the process does not limit the step,
97 // but sets the 'StronglyForced' condition for the DoIt to be
98 // invoked at every step.
99
100 G4double GetMeanLifeTime(const G4Track& aTrack, G4ForceCondition*) override;
101 // Returns infinity; i. e. the process does not limit the time,
102 // but sets the 'StronglyForced' condition for the DoIt to be
103 // invoked at every step.
104
106 const G4Step& aStep) override;
107 G4VParticleChange* AtRestDoIt(const G4Track& aTrack,
108 const G4Step& aStep) override;
109
111 const G4Step& aStep,
112 G4double& yield1,
113 G4double& yield2,
114 G4double& yield3);
115 // allow multiple time constants with scint by particle type
116 // Returns the number of scintillation photons calculated when
117 // scintillation depends on the particle type and energy
118 // deposited (includes nonlinear dependendency) and updates the
119 // yields for each channel
120
121 void SetTrackSecondariesFirst(const G4bool state);
122 // If set, the primary particle tracking is interrupted and any
123 // produced scintillation photons are tracked next. When all
124 // have been tracked, the tracking of the primary resumes.
125
127 // Returns the boolean flag for tracking secondaries first.
128
129 void SetFiniteRiseTime(const G4bool state);
130 // If set, the G4Scintillation process expects the user to have
131 // set the constant material property SCINTILLATIONRISETIME{1,2,3}.
132
134 // Returns the boolean flag for a finite scintillation rise time.
135
137 // Returns the address of scintillation integral table #1.
138
140 // Returns the address of scintillation integral table #2.
141
143 // Returns the address of scintillation integral table #3.
144
145 void AddSaturation(G4EmSaturation* sat);
146 // Adds Birks Saturation to the process.
147
148 void RemoveSaturation();
149 // Removes the Birks Saturation from the process.
150
152 // Returns the Birks Saturation.
153
155 // Called by the user to set the scintillation yield as a function
156 // of energy deposited by particle type
157
159 // Return the boolean that determines the method of scintillation
160 // production
161
162 void SetScintillationTrackInfo(const G4bool trackType);
163 // Call by the user to set the G4ScintillationTrackInformation
164 // to scintillation photon track
165
167 // Return the boolean for whether or not the
168 // G4ScintillationTrackInformation is set to the scint. photon track
169
170 void SetStackPhotons(const G4bool);
171 // Call by the user to set the flag for stacking the scint. photons
172
173 G4bool GetStackPhotons() const;
174 // Return the boolean for whether or not the scint. photons are stacked
175
176 G4int GetNumPhotons() const;
177 // Returns the current number of scint. photons (after PostStepDoIt)
178
179 void DumpPhysicsTable() const;
180 // Prints the fast and slow scintillation integral tables.
181
183 // sets verbosity
184
185 private:
186
187 G4PhysicsTable* fIntegralTable1;
188 G4PhysicsTable* fIntegralTable2;
189 G4PhysicsTable* fIntegralTable3;
190
191 G4EmSaturation* fEmSaturation;
192 const G4ParticleDefinition* opticalphoton =
194
195 G4int fNumPhotons;
196
197 G4bool fScintillationByParticleType;
198 G4bool fScintillationTrackInfo;
199 G4bool fStackingFlag;
200 G4bool fTrackSecondariesFirst;
201 G4bool fFiniteRiseTime;
202
203#ifdef G4DEBUG_SCINTILLATION
204 G4double ScintTrackEDep, ScintTrackYield;
205#endif
206
207 G4double single_exp(G4double t, G4double tau2);
208 G4double bi_exp(G4double t, G4double tau1, G4double tau2);
209
210 // emission time distribution when there is a finite rise time
211 G4double sample_time(G4double tau1, G4double tau2);
212
213 G4int secID = -1; // creator modelID
214
215};
216
217////////////////////
218// Inline methods
219////////////////////
220
222{
223 return fTrackSecondariesFirst;
224}
225
227{
228 return fFiniteRiseTime;
229}
230
232{
233 return fIntegralTable1;
234}
235
237{
238 return fIntegralTable2;
239}
240
242{
243 return fIntegralTable3;
244}
245
247{
248 fEmSaturation = sat;
249}
250
251inline void G4Scintillation::RemoveSaturation() { fEmSaturation = nullptr; }
252
254{
255 return fEmSaturation;
256}
257
259{
260 return fScintillationByParticleType;
261}
262
264{
265 return fScintillationTrackInfo;
266}
267
268inline G4bool G4Scintillation::GetStackPhotons() const { return fStackingFlag; }
269
270inline G4int G4Scintillation::GetNumPhotons() const { return fNumPhotons; }
271
272inline G4double G4Scintillation::single_exp(G4double t, G4double tau2)
273{
274 return std::exp(-1.0 * t / tau2) / tau2;
275}
276
277inline G4double G4Scintillation::bi_exp(G4double t, G4double tau1,
278 G4double tau2)
279{
280 return std::exp(-1.0 * t / tau2) * (1 - std::exp(-1.0 * t / tau1)) / tau2 /
281 tau2 * (tau1 + tau2);
282}
283
284#endif /* G4Scintillation_h */
G4ForceCondition
G4ProcessType
@ fElectromagnetic
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
G4GLOB_DLL std::ostream G4cout
static G4OpticalPhoton * OpticalPhotonDefinition()
G4bool GetScintillationTrackInfo() const
G4VParticleChange * AtRestDoIt(const G4Track &aTrack, const G4Step &aStep) override
G4EmSaturation * GetSaturation() const
G4double GetScintillationYieldByParticleType(const G4Track &aTrack, const G4Step &aStep, G4double &yield1, G4double &yield2, G4double &yield3)
G4PhysicsTable * GetIntegralTable1() const
void SetTrackSecondariesFirst(const G4bool state)
void SetStackPhotons(const G4bool)
G4double GetMeanFreePath(const G4Track &aTrack, G4double, G4ForceCondition *) override
void BuildPhysicsTable(const G4ParticleDefinition &aParticleType) override
void SetVerboseLevel(G4int)
void SetScintillationTrackInfo(const G4bool trackType)
G4bool GetFiniteRiseTime() const
G4double GetMeanLifeTime(const G4Track &aTrack, G4ForceCondition *) override
G4PhysicsTable * GetIntegralTable2() const
G4PhysicsTable * GetIntegralTable3() const
G4VParticleChange * PostStepDoIt(const G4Track &aTrack, const G4Step &aStep) override
G4Scintillation(const G4Scintillation &right)=delete
void AddSaturation(G4EmSaturation *sat)
G4bool IsApplicable(const G4ParticleDefinition &aParticleType) override
void DumpPhysicsTable() const
void SetFiniteRiseTime(const G4bool state)
G4Scintillation & operator=(const G4Scintillation &right)=delete
void DumpInfo() const override
G4int GetNumPhotons() const
G4bool GetTrackSecondariesFirst() const
G4bool GetScintillationByParticleType() const
void PreparePhysicsTable(const G4ParticleDefinition &part) override
void SetScintillationByParticleType(const G4bool)
void ProcessDescription(std::ostream &) const override
G4bool GetStackPhotons() const
Definition: G4Step.hh:62