Geant4 11.2.2
Toolkit for the simulation of the passage of particles through matter
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G4INCLNNToNLK2piChannel.cc
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25//
26// INCL++ intra-nuclear cascade model
27// Alain Boudard, CEA-Saclay, France
28// Joseph Cugnon, University of Liege, Belgium
29// Jean-Christophe David, CEA-Saclay, France
30// Pekka Kaitaniemi, CEA-Saclay, France, and Helsinki Institute of Physics, Finland
31// Sylvie Leray, CEA-Saclay, France
32// Davide Mancusi, CEA-Saclay, France
33//
34#define INCLXX_IN_GEANT4_MODE 1
35
36#include "globals.hh"
37
38#include "G4INCLNNToNLK2piChannel.hh"
39#include "G4INCLKinematicsUtils.hh"
40#include "G4INCLBinaryCollisionAvatar.hh"
41#include "G4INCLRandom.hh"
42#include "G4INCLGlobals.hh"
43#include "G4INCLLogger.hh"
44#include <algorithm>
45#include "G4INCLPhaseSpaceGenerator.hh"
46
47namespace G4INCL {
48
49 const G4double NNToNLK2piChannel::angularSlope = 2.; // What is the exact effect? Sould be check
50
51 NNToNLK2piChannel::NNToNLK2piChannel(Particle *p1, Particle *p2)
52 : particle1(p1), particle2(p2)
53 {}
54
55 NNToNLK2piChannel::~NNToNLK2piChannel(){}
56
57 void NNToNLK2piChannel::fillFinalState(FinalState *fs) {
58
59 /* Equipartition in all channel with factor N(pi)!
60 */
61
62 const G4double sqrtS = KinematicsUtils::totalEnergyInCM(particle1, particle2);
63
64 const G4int iso = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
65
66 ParticleType KaonType;
67 ParticleType Pion1Type;
68 ParticleType Pion2Type;
69
70 G4double rdm = Random::shoot();
71 particle2->setType(Lambda);
72
73 if(iso == 2){
74 if(rdm*7. < 2.){
75 particle1->setType(Neutron);
76 KaonType = KZero;
77 Pion1Type = PiPlus;
78 Pion2Type = PiPlus;
79 }
80 else if(rdm*7. < 3.){
81 particle1->setType(Neutron);
82 KaonType = KPlus;
83 Pion1Type = PiZero;
84 Pion2Type = PiPlus;
85 }
86 else if(rdm*7. < 4.){
87 particle1->setType(Proton);
88 KaonType = KZero;
89 Pion1Type = PiZero;
90 Pion2Type = PiPlus;
91 }
92 else if(rdm*7. < 5.){
93 particle1->setType(Proton);
94 KaonType = KPlus;
95 Pion1Type = PiMinus;
96 Pion2Type = PiPlus;
97 }
98 else{
99 particle1->setType(Proton);
100 KaonType = KPlus;
101 Pion1Type = PiZero;
102 Pion2Type = PiZero;
103 }
104
105 }
106 else if(iso == -2){
107 if(rdm*7. < 1.){
108 particle1->setType(Neutron);
109 KaonType = KZero;
110 Pion1Type = PiMinus;
111 Pion2Type = PiPlus;
112 }
113 else if(rdm*7. < 3.){
114 particle1->setType(Neutron);
115 KaonType = KZero;
116 Pion1Type = PiZero;
117 Pion2Type = PiZero;
118 }
119 else if(rdm*7. < 4.){
120 particle1->setType(Neutron);
121 KaonType = KPlus;
122 Pion1Type = PiMinus;
123 Pion2Type = PiZero;
124 }
125 else if(rdm*7. < 5.){
126 particle1->setType(Proton);
127 KaonType = KZero;
128 Pion1Type = PiMinus;
129 Pion2Type = PiZero;
130 }
131 else{
132 particle1->setType(Proton);
133 KaonType = KPlus;
134 Pion1Type = PiMinus;
135 Pion2Type = PiMinus;
136 }
137 }
138 else{
139 if(rdm*8. < 1.){
140 particle1->setType(Neutron);
141 KaonType = KZero;
142 Pion1Type = PiZero;
143 Pion2Type = PiPlus;
144 }
145 else if(rdm*8. < 2.){
146 particle1->setType(Neutron);
147 KaonType = KPlus;
148 Pion1Type = PiMinus;
149 Pion2Type = PiPlus;
150 }
151 else if(rdm*8. < 4.){
152 particle1->setType(Neutron);
153 KaonType = KPlus;
154 Pion1Type = PiZero;
155 Pion2Type = PiZero;
156 }
157 else if(rdm*8. < 5.){
158 particle1->setType(Proton);
159 KaonType = KZero;
160 Pion1Type = PiMinus;
161 Pion2Type = PiPlus;
162 }
163 else if(rdm*8. < 7.){
164 particle1->setType(Proton);
165 KaonType = KZero;
166 Pion1Type = PiZero;
167 Pion2Type = PiZero;
168 }
169 else{
170 particle1->setType(Proton);
171 KaonType = KPlus;
172 Pion1Type = PiMinus;
173 Pion2Type = PiZero;
174 }
175 }
176
177
178 ParticleList list;
179 list.push_back(particle1);
180 list.push_back(particle2);
181 const ThreeVector &rcol1 = particle1->getPosition();
182 const ThreeVector &rcol2 = particle2->getPosition();
183 const ThreeVector zero;
184 Particle *pion1 = new Particle(Pion1Type,zero,rcol1);
185 Particle *pion2 = new Particle(Pion2Type,zero,rcol1);
186 Particle *kaon = new Particle(KaonType,zero,rcol2);
187 list.push_back(kaon);
188 list.push_back(pion1);
189 list.push_back(pion2);
190
191 if(Random::shoot()<0.5) PhaseSpaceGenerator::generateBiased(sqrtS, list, 0, angularSlope);
192 else PhaseSpaceGenerator::generateBiased(sqrtS, list, 1, angularSlope);
193
194 fs->addModifiedParticle(particle1);
195 fs->addModifiedParticle(particle2);
196 fs->addCreatedParticle(kaon);
197 fs->addCreatedParticle(pion1);
198 fs->addCreatedParticle(pion2);
199
200 }
201}
G4double
double G4double
Definition G4Types.hh:83
G4int
int G4int
Definition G4Types.hh:85
G4INCL::FinalState::addModifiedParticle
void addModifiedParticle(Particle *p)
Definition G4INCLFinalState.cc:60
G4INCL::FinalState::addCreatedParticle
void addCreatedParticle(Particle *p)
Definition G4INCLFinalState.cc:75
G4INCL::NNToNLK2piChannel::NNToNLK2piChannel
NNToNLK2piChannel(Particle *, Particle *)
Definition G4INCLNNToNLK2piChannel.cc:51
G4INCL::Particle::getPosition
const G4INCL::ThreeVector & getPosition() const
Definition G4INCLParticle.hh:956
G4INCL::Particle::getType
G4INCL::ParticleType getType() const
Definition G4INCLParticle.hh:187
G4INCL::Particle::setType
void setType(ParticleType t)
Definition G4INCLParticle.hh:196
G4INCL::KinematicsUtils::totalEnergyInCM
G4double totalEnergyInCM(Particle const *const p1, Particle const *const p2)
Definition G4INCLKinematicsUtils.cc:121
G4INCL::ParticleTable::getIsospin
G4int getIsospin(const ParticleType t)
Get the isospin of a particle.
Definition G4INCLParticleTable.cc:531
G4INCL::PhaseSpaceGenerator::generateBiased
void generateBiased(const G4double sqrtS, ParticleList &particles, const size_t index, const G4double slope)
Generate a biased event in the CM system.
Definition G4INCLPhaseSpaceGenerator.cc:98
G4INCL::Random::shoot
G4double shoot()
Definition G4INCLRandom.cc:93