Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
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G4INCLReflectionChannel.cc
Go to the documentation of this file.
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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
39#include "G4INCLFinalState.hh"
40#include "G4INCLRandom.hh"
42
43#include <cmath>
44
45namespace G4INCL {
46 const G4double ReflectionChannel::sinMinReflectionAngleSquaredOverFour = std::pow(std::sin(2.*Math::pi/200.),2.);
47 const G4double ReflectionChannel::positionScalingFactor = 0.99;
48
50 :theNucleus(n),theParticle(p)
51 {
52 }
53
55 {
56 }
57
59 fs->setTotalEnergyBeforeInteraction(theParticle->getEnergy() - theParticle->getPotentialEnergy());
60
61 const ThreeVector &oldMomentum = theParticle->getMomentum();
62 const ThreeVector thePosition = theParticle->getPosition();
63 G4double pspr = thePosition.dot(oldMomentum);
64 if(pspr>=0) { // This means that the particle is trying to leave; perform a reflection
65 const G4double x2cour = thePosition.mag2();
66 const ThreeVector newMomentum = oldMomentum - (thePosition * (2.0 * pspr/x2cour));
67 const G4double deltaP2 = (newMomentum-oldMomentum).mag2();
68 theParticle->setMomentum(newMomentum);
69 const G4double minDeltaP2 = sinMinReflectionAngleSquaredOverFour * newMomentum.mag2();
70 if(deltaP2 < minDeltaP2) { // Avoid extremely small reflection angles
71 theParticle->setPosition(thePosition * positionScalingFactor);
72 INCL_DEBUG("Reflection angle for particle " << theParticle->getID() << " was too tangential: " << '\n'
73 << " " << deltaP2 << "=deltaP2<minDeltaP2=" << minDeltaP2 << '\n'
74 << " Resetting the particle position to ("
75 << thePosition.getX() << ", "
76 << thePosition.getY() << ", "
77 << thePosition.getZ() << ")" << '\n');
78 }
79 theNucleus->updatePotentialEnergy(theParticle);
80 } else { // The particle momentum is already directed towards the inside of the nucleus; do nothing
81 // ...but make sure this only happened because of the frozen propagation
82// assert(theParticle->getPosition().dot(theParticle->getPropagationVelocity())>0.);
83 }
84
85 theParticle->thawPropagation();
86 fs->addModifiedParticle(theParticle);
87 }
88}
89
Abstract interface to the nuclear potential.
#define INCL_DEBUG(x)
double G4double
Definition: G4Types.hh:83
void addModifiedParticle(Particle *p)
void setTotalEnergyBeforeInteraction(G4double E)
void updatePotentialEnergy(Particle *p) const
Update the particle potential energy.
G4double getEnergy() const
G4double getPotentialEnergy() const
Get the particle potential energy.
const G4INCL::ThreeVector & getPosition() const
const G4INCL::ThreeVector & getMomentum() const
virtual void setMomentum(const G4INCL::ThreeVector &momentum)
void thawPropagation()
Unfreeze particle propagation.
virtual void setPosition(const G4INCL::ThreeVector &position)
long getID() const
void fillFinalState(FinalState *fs)
ReflectionChannel(Nucleus *n, Particle *p)
G4double getY() const
G4double getZ() const
G4double dot(const ThreeVector &v) const
G4double mag2() const
G4double getX() const
const G4double pi