Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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Public Member Functions | Static Public Member Functions | List of all members
G4INCL::DeltaDecayChannel Class Reference

#include <G4INCLDeltaDecayChannel.hh>

+ Inheritance diagram for G4INCL::DeltaDecayChannel:

Public Member Functions

 DeltaDecayChannel (Particle *, ThreeVector const &)
 
virtual ~DeltaDecayChannel ()
 
void fillFinalState (FinalState *fs)
 
- Public Member Functions inherited from G4INCL::IChannel
 IChannel ()
 
virtual ~IChannel ()
 
FinalStategetFinalState ()
 
virtual void fillFinalState (FinalState *fs)=0
 

Static Public Member Functions

static G4double computeDecayTime (Particle *p)
 

Detailed Description

Definition at line 49 of file G4INCLDeltaDecayChannel.hh.

Constructor & Destructor Documentation

◆ DeltaDecayChannel()

G4INCL::DeltaDecayChannel::DeltaDecayChannel ( Particle p,
ThreeVector const &  dir 
)

Definition at line 46 of file G4INCLDeltaDecayChannel.cc.

47 :theParticle(p), incidentDirection(dir)
48 { }

◆ ~DeltaDecayChannel()

G4INCL::DeltaDecayChannel::~DeltaDecayChannel ( )
virtual

Definition at line 50 of file G4INCLDeltaDecayChannel.cc.

50{}

Member Function Documentation

◆ computeDecayTime()

G4double G4INCL::DeltaDecayChannel::computeDecayTime ( Particle p)
static

Definition at line 52 of file G4INCLDeltaDecayChannel.cc.

52 {
53 const G4double m = p->getMass();
54 const G4double g0 = 115.0;
55 G4double gg = g0;
56 if(m > 1500.0) gg = 200.0;
57 const G4double geff = p->getEnergy()/m;
58 const G4double qqq = KinematicsUtils::momentumInCM(m, ParticleTable::effectiveNucleonMass, ParticleTable::effectivePionMass);
59 const G4double psf = std::pow(qqq, 3)/(std::pow(qqq, 3) + 5832000.0); // phase space factor 5.832E6 = 180^3
60 const G4double tdel = -G4INCL::PhysicalConstants::hc/(gg*psf)*std::log(Random::shoot())*geff; // fm
61 if( m > 1400) return tdel * 1./(1. + std::pow((m-1400)/g0,2)); // reduction of Delta life time for high masses.
62 return tdel; // fm
63 }
G4double
double G4double
Definition: G4Types.hh:83
G4INCL::KinematicsUtils::momentumInCM
G4double momentumInCM(Particle const *const p1, Particle const *const p2)
gives the momentum in the CM frame of two particles.
Definition: G4INCLKinematicsUtils.cc:107
G4INCL::ParticleTable::effectiveNucleonMass
const G4double effectiveNucleonMass
Definition: G4INCLParticleTable.hh:69
G4INCL::ParticleTable::effectivePionMass
const G4double effectivePionMass
Definition: G4INCLParticleTable.hh:73
G4INCL::PhysicalConstants::hc
const G4double hc
[MeV*fm]
Definition: G4INCLGlobals.hh:51
G4INCL::Random::shoot
G4double shoot()
Definition: G4INCLRandom.cc:93

Referenced by G4INCL::StandardPropagationModel::generateDecays().

◆ fillFinalState()

void G4INCL::DeltaDecayChannel::fillFinalState ( FinalState fs)
virtual

Implements G4INCL::IChannel.

Definition at line 78 of file G4INCLDeltaDecayChannel.cc.

78 {
79 // SUBROUTINE DECAY2(P1,P2,P3,WP,ij,
80 // s X1,X2,hel,B1,B2,B3)
81
82 // This routine describes the anisotropic decay of a particle of mass
83 // xi into 2 particles of masses x1,x2.
84 // The anisotropy is supposed to follow a 1+3*hel*(cos(theta))**2
85 // law with respect to the direction of the incoming particle.
86 // In the input, p1,p2,p3 is the momentum of particle xi.
87 // In the output, p1,p2,p3 is the momentum of particle x1 , while
88 // q1,q2,q3 is the momentum of particle x2.
89
90 // COMMON/bl12/QQ1(200),QQ2(200),QQ3(200),QQ4(200),
91 // s YY1(200),YY2(200),YY3(200),YM(200),IPI(200)
92 // common/hazard/ial,IY1,IY2,IY3,IY4,IY5,IY6,IY7,IY8,IY9,IY10,
93 // s IY11,IY12,IY13,IY14,IY15,IY16,IY17,IY18,IY19
94
95 // DATA IY8,IY9,IY10/82345,92345,45681/
96 // PCM(E,A,C)=0.5*SQRT((E**2-(A+C)**2)*(E**2-(A-C)**2))/E P-N20800
97 // XI=YM(ij)
98
99 // XE=WP P-N20810
100 // B1=P1/XE P-N20820
101 // B2=P2/XE P-N20830
102 // B3=P3/XE
103 // XQ=PCM(XI,X1,X2)
104
105 const G4double deltaMass = theParticle->getMass();
106
107 G4double fi, ctet, stet;
108 sampleAngles(&ctet, &stet, &fi);
109
110 G4double cfi = std::cos(fi);
111 G4double sfi = std::sin(fi);
112 G4double beta = incidentDirection.mag();
113
114 G4double q1, q2, q3;
115 G4double sal=0.0;
116 if (beta >= 1.0e-10)
117 sal = incidentDirection.perp()/beta;
118 if (sal >= 1.0e-6) {
119 G4double b1 = incidentDirection.getX();
120 G4double b2 = incidentDirection.getY();
121 G4double b3 = incidentDirection.getZ();
122 G4double cal = b3/beta;
123 G4double t1 = ctet+cal*stet*sfi/sal;
124 G4double t2 = stet/sal;
125 q1=(b1*t1+b2*t2*cfi)/beta;
126 q2=(b2*t1-b1*t2*cfi)/beta;
127 q3=(b3*t1/beta-t2*sfi);
128 } else {
129 q1 = stet*cfi;
130 q2 = stet*sfi;
131 q3 = ctet;
132 }
133 theParticle->setHelicity(0.0);
134
135 ParticleType pionType;
136 switch(theParticle->getType()) {
137 case DeltaPlusPlus:
138 theParticle->setType(Proton);
139 pionType = PiPlus;
140 break;
141 case DeltaPlus:
142 if(Random::shoot() < 1.0/3.0) {
143 theParticle->setType(Neutron);
144 pionType = PiPlus;
145 } else {
146 theParticle->setType(Proton);
147 pionType = PiZero;
148 }
149 break;
150 case DeltaZero:
151 if(Random::shoot() < 1.0/3.0) {
152 theParticle->setType(Proton);
153 pionType = PiMinus;
154 } else {
155 theParticle->setType(Neutron);
156 pionType = PiZero;
157 }
158 break;
159 case DeltaMinus:
160 theParticle->setType(Neutron);
161 pionType = PiMinus;
162 break;
163 default:
164 INCL_FATAL("Unrecognized delta type; type=" << theParticle->getType() << '\n');
165 pionType = UnknownParticle;
166 break;
167 }
168
169 G4double xq = KinematicsUtils::momentumInCM(deltaMass,
170 theParticle->getMass(),
171 ParticleTable::getINCLMass(pionType));
172
173 q1 *= xq;
174 q2 *= xq;
175 q3 *= xq;
176
177 ThreeVector pionMomentum(q1, q2, q3);
178 ThreeVector pionPosition(theParticle->getPosition());
179 Particle *pion = new Particle(pionType, pionMomentum, pionPosition);
180 theParticle->setMomentum(-pionMomentum);
181 theParticle->adjustEnergyFromMomentum();
182
183 fs->addModifiedParticle(theParticle);
184 fs->addCreatedParticle(pion);
185 // call loren(q1,q2,q3,b1,b2,b3,wq)
186 // call loren(p1,p2,p3,b1,b2,b3,wp)
187 // qq1(ij)=q1
188 // qq2(ij)=q2
189 // qq3(ij)=q3
190 // qq4(ij)=wq
191 // ym(ij)=xi
192 // RETURN P-N21120
193 // END P-N21130
194 }
INCL_FATAL
#define INCL_FATAL(x)
Definition: G4INCLLogger.hh:216
G4INCL::Particle::setHelicity
void setHelicity(G4double h)
Definition: G4INCLParticle.hh:827
G4INCL::Particle::getPosition
const G4INCL::ThreeVector & getPosition() const
Definition: G4INCLParticle.hh:816
G4INCL::Particle::adjustEnergyFromMomentum
G4double adjustEnergyFromMomentum()
Recompute the energy to match the momentum.
Definition: G4INCLParticle.cc:155
G4INCL::Particle::setMomentum
virtual void setMomentum(const G4INCL::ThreeVector &momentum)
Definition: G4INCLParticle.hh:808
G4INCL::Particle::getType
G4INCL::ParticleType getType() const
Definition: G4INCLParticle.hh:178
G4INCL::Particle::setType
void setType(ParticleType t)
Definition: G4INCLParticle.hh:187
G4INCL::Particle::getMass
G4double getMass() const
Get the cached particle mass.
Definition: G4INCLParticle.hh:451
G4INCL::ThreeVector::getY
G4double getY() const
Definition: G4INCLThreeVector.hh:65
G4INCL::ThreeVector::getZ
G4double getZ() const
Definition: G4INCLThreeVector.hh:66
G4INCL::ThreeVector::mag
G4double mag() const
Definition: G4INCLThreeVector.hh:73
G4INCL::ThreeVector::perp
G4double perp() const
Definition: G4INCLThreeVector.hh:68
G4INCL::ThreeVector::getX
G4double getX() const
Definition: G4INCLThreeVector.hh:64
G4INCL::ParticleTable::getINCLMass
G4double getINCLMass(const G4int A, const G4int Z, const G4int S)
Get INCL nuclear mass (in MeV/c^2)
Definition: G4INCLParticleTable.cc:794
G4InuclParticleNames::pion
G4bool pion(G4int ityp)
Definition: G4InuclParticleNames.hh:90
The documentation for this class was generated from the following files: