Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
All Classes Namespaces Files Functions Variables Typedefs Enumerations Enumerator Friends Macros Pages
G4INCLNNToNSKpiChannel.cc
Go to the documentation of this file.
1//
2// ********************************************************************
3// * License and Disclaimer *
4// * *
5// * The Geant4 software is copyright of the Copyright Holders of *
6// * the Geant4 Collaboration. It is provided under the terms and *
7// * conditions of the Geant4 Software License, included in the file *
8// * LICENSE and available at http://cern.ch/geant4/license . These *
9// * include a list of copyright holders. *
10// * *
11// * Neither the authors of this software system, nor their employing *
12// * institutes,nor the agencies providing financial support for this *
13// * work make any representation or warranty, express or implied, *
14// * regarding this software system or assume any liability for its *
15// * use. Please see the license in the file LICENSE and URL above *
16// * for the full disclaimer and the limitation of liability. *
17// * *
18// * This code implementation is the result of the scientific and *
19// * technical work of the GEANT4 collaboration. *
20// * By using, copying, modifying or distributing the software (or *
21// * any work based on the software) you agree to acknowledge its *
22// * use in resulting scientific publications, and indicate your *
23// * acceptance of all terms of the Geant4 Software license. *
24// ********************************************************************
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 "G4INCLNNToNSKpiChannel.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 NNToNSKpiChannel::angularSlope = 2.; // What is the exact effect? Sould be check
50
51 NNToNSKpiChannel::NNToNSKpiChannel(Particle *p1, Particle *p2)
52 : particle1(p1), particle2(p2)
53 {}
54
55 NNToNSKpiChannel::~NNToNSKpiChannel(){}
56
57 void NNToNSKpiChannel::fillFinalState(FinalState *fs) {
58
59 // pp (36) pn (36)
60 //
61 // pp -> p pi+ S- K+ (9)
62 // pp -> p pi+ S0 K0 (9)
63 // pp -> p pi0 S+ K0 (4)
64 // pp -> n pi+ S+ K0 (2)
65 // pp -> p pi0 S0 K+ (4)
66 // pp -> n pi+ S0 K+ (2)
67 // pp -> p pi- S+ K+ (2)
68 // pp -> n pi0 S+ K+ (4)
69
70 // pn -> p pi0 S- K+ (4)
71 // pn -> n pi+ S- K+ (2)
72 // pn -> p pi0 S0 K0 (2)
73 // pn -> n pi+ S0 K0 (1)
74 // pn -> p pi+ S- K0 (9)
75
76 const G4double sqrtS = KinematicsUtils::totalEnergyInCM(particle1, particle2);
77
78 const G4int iso = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
79
80 ParticleType KaonType;
81 ParticleType PionType;
82
83 G4double rdm = Random::shoot();
84
85 if(iso == 2){
86 if(rdm * 36. < 9.){
87 KaonType = KPlus;
88 PionType = PiPlus;
89 particle2->setType(SigmaMinus);
90 }
91 else if(rdm * 36. < 18.){
92 KaonType = KZero;
93 PionType = PiPlus;
94 particle2->setType(SigmaZero);
95 }
96 else if(rdm * 36. < 22.){
97 KaonType = KZero;
98 PionType = PiZero;
99 particle2->setType(SigmaPlus);
100 }
101 else if(rdm * 36. < 24.){
102 KaonType = KZero;
103 PionType = PiPlus;
104 particle1->setType(Neutron);
105 particle2->setType(SigmaPlus);
106 }
107 else if(rdm * 36. < 28.){
108 KaonType = KPlus;
109 PionType = PiZero;
110 particle2->setType(SigmaZero);
111 }
112 else if(rdm * 36. < 30.){
113 KaonType = KPlus;
114 PionType = PiPlus;
115 particle1->setType(Neutron);
116 particle2->setType(SigmaZero);
117 }
118 else if(rdm * 36. < 32.){
119 KaonType = KPlus;
120 PionType = PiMinus;
121 particle2->setType(SigmaPlus);
122 }
123 else{
124 KaonType = KPlus;
125 PionType = PiZero;
126 particle1->setType(Neutron);
127 particle2->setType(SigmaPlus);
128 }
129
130 }
131 else if(iso == -2){
132 if(rdm * 36. < 9.){
133 KaonType = KZero;
134 PionType = PiMinus;
135 particle2->setType(SigmaPlus);
136 }
137 else if(rdm * 36. < 18.){
138 KaonType = KPlus;
139 PionType = PiMinus;
140 particle2->setType(SigmaZero);
141 }
142 else if(rdm * 36. < 22.){
143 KaonType = KPlus;
144 PionType = PiZero;
145 particle2->setType(SigmaMinus);
146 }
147 else if(rdm * 36. < 24.){
148 KaonType = KPlus;
149 PionType = PiMinus;
150 particle1->setType(Proton);
151 particle2->setType(SigmaMinus);
152 }
153 else if(rdm * 36. < 28.){
154 KaonType = KZero;
155 PionType = PiZero;
156 particle2->setType(SigmaZero);
157 }
158 else if(rdm * 36. < 30.){
159 KaonType = KZero;
160 PionType = PiMinus;
161 particle1->setType(Proton);
162 particle2->setType(SigmaZero);
163 }
164 else if(rdm * 36. < 32.){
165 KaonType = KZero;
166 PionType = PiPlus;
167 particle2->setType(SigmaMinus);
168 }
169 else{
170 KaonType = KZero;
171 PionType = PiZero;
172 particle1->setType(Proton);
173 particle2->setType(SigmaMinus);
174 }
175
176 }
177 else if(rdm*36. < 4.){
178 KaonType = KPlus;
179 PionType = PiZero;
180 particle1->setType(Proton);
181 particle2->setType(SigmaMinus);
182 }
183 else if(rdm*36. < 6.){
184 KaonType = KZero;
185 PionType = PiZero;
186 particle1->setType(Neutron);
187 particle2->setType(SigmaPlus);
188 }
189 else if(rdm*36. < 8.){
190 KaonType = KPlus;
191 PionType = PiPlus;
192 particle1->setType(Neutron);
193 particle2->setType(SigmaMinus);
194 }
195 else if(rdm*36. < 9.){
196 KaonType = KZero;
197 PionType = PiMinus;
198 particle1->setType(Proton);
199 particle2->setType(SigmaPlus);
200 }
201 else if(rdm*36. < 18.){
202 KaonType = KZero;
203 PionType = PiZero;
204 particle1->setType(Proton);
205 particle2->setType(SigmaZero);
206 }
207 else if(rdm*36. < 27.){
208 KaonType = KPlus;
209 PionType = PiZero;
210 particle1->setType(Neutron);
211 particle2->setType(SigmaZero);
212 }
213 else if(rdm*36. < 28.){
214 KaonType = KZero;
215 PionType = PiPlus;
216 particle1->setType(Neutron);
217 particle2->setType(SigmaZero);
218 }
219 else if(rdm*36. < 30.){
220 KaonType = KPlus;
221 PionType = PiMinus;
222 particle1->setType(Proton);
223 particle2->setType(SigmaZero);
224 }
225 else if(rdm*36. < 32.){
226 KaonType = KZero;
227 PionType = PiPlus;
228 particle1->setType(Proton);
229 particle2->setType(SigmaMinus);
230 }
231 else{
232 KaonType = KPlus;
233 PionType = PiMinus;
234 particle1->setType(Neutron);
235 particle2->setType(SigmaPlus);
236 }
237
238 ParticleList list;
239 list.push_back(particle1);
240 list.push_back(particle2);
241 const ThreeVector &rcol1 = particle1->getPosition();
242 const ThreeVector &rcol2 = particle2->getPosition();
243 const ThreeVector zero;
244 Particle *pion = new Particle(PionType,zero,rcol1);
245 Particle *kaon = new Particle(KaonType,zero,rcol2);
246 list.push_back(kaon);
247 list.push_back(pion);
248
249 if(Random::shoot()<0.5) PhaseSpaceGenerator::generateBiased(sqrtS, list, 0, angularSlope);
250 else PhaseSpaceGenerator::generateBiased(sqrtS, list, 1, angularSlope);
251
252 INCL_DEBUG("NNToNSKpi " << (kaon->getMomentum().theta()) * 180. / G4INCL::Math::pi << '\n');
253
254 fs->addModifiedParticle(particle1);
255 fs->addModifiedParticle(particle2);
256 fs->addCreatedParticle(kaon);
257 fs->addCreatedParticle(pion);
258
259 }
260}
INCL_DEBUG
#define INCL_DEBUG(x)
Definition: G4INCLLogger.hh:240
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::NNToNSKpiChannel::NNToNSKpiChannel
NNToNSKpiChannel(Particle *, Particle *)
Definition: G4INCLNNToNSKpiChannel.cc:51
G4INCL::NNToNSKpiChannel::fillFinalState
void fillFinalState(FinalState *fs)
Definition: G4INCLNNToNSKpiChannel.cc:57
G4INCL::Particle::getPosition
const G4INCL::ThreeVector & getPosition() const
Definition: G4INCLParticle.hh:820
G4INCL::Particle::getMomentum
const G4INCL::ThreeVector & getMomentum() const
Definition: G4INCLParticle.hh:798
G4INCL::Particle::getType
G4INCL::ParticleType getType() const
Definition: G4INCLParticle.hh:182
G4INCL::Particle::setType
void setType(ParticleType t)
Definition: G4INCLParticle.hh:191
G4INCL::ThreeVector::theta
G4double theta() const
Definition: G4INCLThreeVector.hh:83
G4INCL::KinematicsUtils::totalEnergyInCM
G4double totalEnergyInCM(Particle const *const p1, Particle const *const p2)
Definition: G4INCLKinematicsUtils.cc:94
G4INCL::Math::pi
const G4double pi
Definition: G4INCLGlobals.hh:68
G4INCL::ParticleTable::getIsospin
G4int getIsospin(const ParticleType t)
Get the isospin of a particle.
Definition: G4INCLParticleTable.cc:478
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