Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
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G4IonDEDXScalingICRU73.hh
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28// ===========================================================================
29// GEANT4 class header file
30//
31// Class: G4IonDEDXScalingICRU73
32//
33// Base class: G4VIonDEDXScalingAlgorithm
34//
35// Author: Anton Lechner ([email protected])
36//
37// First implementation: 10. 05. 2009
38//
39// Modifications: 12. 11. 2009 - Moved all decision logic concerning ICRU 73
40// scaling for heavy ions into this class.
41// Adapting ScalingFactorEnergy class according
42// to changes in base class (AL).
43//
44// Class description:
45// dE/dx scaling algorithm applied on top of ICRU 73 data (for ions not
46// covered by the ICRU 73 report)
47//
48// Comments:
49//
50// ===========================================================================
51
52#ifndef G4IONDEDXSCALINGICRU73_HH
53#define G4IONDEDXSCALINGICRU73_HH
54
55#include "globals.hh"
57#include "G4Material.hh"
59#include <vector>
60#include "G4Exp.hh"
61
63
64 public:
65 explicit G4IonDEDXScalingICRU73(G4int minAtomicNumberIon = 19,
66 G4int maxAtomicNumberIon = 102);
68
69 // Function for scaling the kinetic energy (no scaling by default).
70 // Returns scaling factor for a given ion.
72 const G4ParticleDefinition* particle, // Projectile (ion)
73 const G4Material* material) override; // Target material
74
75
76 // Function for scaling the dE/dx value (no scaling by default).
77 // Returns scaling factor for a given ion-material couple and
78 // a given kinetic energy.
80 const G4ParticleDefinition* particle, // Projectile (ion)
81 const G4Material*, // Target material
82 G4double kineticEnergy) override; // Kinetic energy
83
84
85 // Function for defining a base particle for dE/dx calculation.
86 // (no base particle by default). Returns atomic number of base
87 // particle.
89 G4int atomicNumberIon, // Atomic number of ion
90 const G4Material*) override; // Target material
91
92 private:
93 void UpdateCacheParticle(
94 const G4ParticleDefinition* particle); // Projectile (ion)
95
96 void UpdateCacheMaterial(
97 const G4Material* material); // Target material
98
99 void CreateReferenceParticles();
100
101 G4double EquilibriumCharge(
102 G4double mass, // Ion mass
103 G4double charge, // Ion charge
104 G4double atomicNumberPow, // Power of atomic nmb
105 G4double kineticEnergy); // Kinetic energy
106
107 // Scaling is only applied for ions with atomic numbers in the range
108 // defined by the following parameters:
109 G4int minAtomicNumber;
110 G4int maxAtomicNumber;
111
112 G4bool referencePrepared;
113
114 // Some properties of reference particle (Fe) are stored for faster access
115 ///////////////////////////G4ParticleDefinition* referenceFe;
116 G4int atomicNumberRefFe;
117 G4int massNumberRefFe;
118 G4double atomicNumberRefPow23Fe;
119 G4double chargeRefFe;
120 G4double massRefFe;
121
122 // Some properties of reference particle (Ar) are stored for faster access
123 ///////////////////////////G4ParticleDefinition* referenceAr;
124 G4int atomicNumberRefAr;
125 G4int massNumberRefAr;
126 G4double atomicNumberRefPow23Ar;
127 G4double chargeRefAr;
128 G4double massRefAr;
129
130 // Flag indicating the use of Fe ions as reference particles
131 G4bool useFe;
132
133 // Some properties of projectiles are stored for faster access
134 const G4ParticleDefinition* cacheParticle;
135 G4int cacheMassNumber;
136 G4int cacheAtomicNumber;
137 G4double cacheAtomicNumberPow23;
138 G4double cacheCharge;
139 G4double cacheMass;
140
141 // Material pointer
142 const G4Material* cacheMaterial;
143};
144
145// ###########################################################################
146
147inline void G4IonDEDXScalingICRU73::UpdateCacheParticle (
148 const G4ParticleDefinition* particle) { // Projectile (ion)
149
150 if(particle != cacheParticle) {
151
152 cacheParticle = particle;
153 cacheAtomicNumber = particle -> GetAtomicNumber();
154 cacheMassNumber = particle -> GetAtomicMass();
155 cacheCharge = particle -> GetPDGCharge();
156 cacheMass = particle -> GetPDGMass();
157 cacheAtomicNumberPow23 = std::pow(G4double(cacheAtomicNumber), 2./3.);
158 }
159}
160
161// ###########################################################################
162
163inline void G4IonDEDXScalingICRU73::UpdateCacheMaterial (
164 const G4Material* material) { // Target material
165
166 if(cacheMaterial != material) {
167
168 cacheMaterial = material;
169
170 useFe = true;
171
172 size_t nmbElements = material -> GetNumberOfElements();
173 if( nmbElements > 1 ) useFe = false;
174
175 if( material -> GetName() == "G4_WATER" ) useFe = true;
176 }
177}
178
179// ###########################################################################
180
181inline G4double G4IonDEDXScalingICRU73::EquilibriumCharge(
182 G4double mass,
183 G4double charge,
184 G4double atomicNumberPow,
185 G4double kineticEnergy) {
186
187 G4double totalEnergy = kineticEnergy + mass;
188 G4double betaSquared = kineticEnergy *
189 (totalEnergy + mass) / (totalEnergy * totalEnergy);
190
191 G4double beta = std::sqrt( betaSquared );
192
193 G4double velOverBohrVel = beta / CLHEP::fine_structure_const;
194
195 G4double q1 = 1.0 - G4Exp(-velOverBohrVel / atomicNumberPow);
196
197 return q1 * charge;
198}
199
200// ###########################################################################
201
202#endif
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
Definition: G4Exp.hh:180
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
G4double ScalingFactorDEDX(const G4ParticleDefinition *particle, const G4Material *, G4double kineticEnergy) override
G4int AtomicNumberBaseIon(G4int atomicNumberIon, const G4Material *) override
G4double ScalingFactorEnergy(const G4ParticleDefinition *particle, const G4Material *material) override