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 // $Id$

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 #include "G4RPGNeutronInelastic.hh"

 #include "G4PhysicalConstants.hh"

 #include "G4SystemOfUnits.hh"

 #include "Randomize.hh"


 G4HadFinalState*

 G4RPGNeutronInelastic::ApplyYourself(const G4HadProjectile& aTrack,

                                      G4Nucleus& targetNucleus)

 {

   theParticleChange.Clear();

   const G4HadProjectile* originalIncident = &aTrack;


   // create the target particle

   G4DynamicParticle* originalTarget = targetNucleus.ReturnTargetParticle();


   G4ReactionProduct modifiedOriginal;

   modifiedOriginal = *originalIncident;

   G4ReactionProduct targetParticle;

   targetParticle = *originalTarget;

   if( originalIncident->GetKineticEnergy()/GeV < 0.01 + 2.*G4UniformRand()/9. )

   {

     SlowNeutron(originalIncident,modifiedOriginal,targetParticle,targetNucleus );

     delete originalTarget;

     return &theParticleChange;

   }


   // Fermi motion and evaporation

   // As of Geant3, the Fermi energy calculation had not been Done

   G4double ek = originalIncident->GetKineticEnergy()/MeV;

   G4double amas = originalIncident->GetDefinition()->GetPDGMass()/MeV;


   G4double tkin = targetNucleus.Cinema( ek );

   ek += tkin;

   modifiedOriginal.SetKineticEnergy( ek*MeV );

   G4double et = ek + amas;

   G4double p = std::sqrt( std::abs((et-amas)*(et+amas)) );

   G4double pp = modifiedOriginal.GetMomentum().mag()/MeV;

   if( pp > 0.0 )

   {

     G4ThreeVector momentum = modifiedOriginal.GetMomentum();

     modifiedOriginal.SetMomentum( momentum * (p/pp) );

   }

   //

   // calculate black track energies

   //

   tkin = targetNucleus.EvaporationEffects( ek );

   ek -= tkin;

   modifiedOriginal.SetKineticEnergy(ek);

   et = ek + amas;

   p = std::sqrt( std::abs((et-amas)*(et+amas)) );

   pp = modifiedOriginal.GetMomentum().mag();

   if( pp > 0.0 )

   {

     G4ThreeVector momentum = modifiedOriginal.GetMomentum();

     modifiedOriginal.SetMomentum( momentum * (p/pp) );

   }

   const G4double cutOff = 0.1;

   if( modifiedOriginal.GetKineticEnergy()/MeV <= cutOff )

   {

     SlowNeutron( originalIncident, modifiedOriginal, targetParticle, targetNucleus );

     delete originalTarget;

     return &theParticleChange;

   }


   G4ReactionProduct currentParticle = modifiedOriginal;

   currentParticle.SetSide( 1 ); // incident always goes in forward hemisphere

   targetParticle.SetSide( -1 );  // target always goes in backward hemisphere

   G4bool incidentHasChanged = false;

   G4bool targetHasChanged = false;

   G4bool quasiElastic = false;

   G4FastVector<G4ReactionProduct,256> vec;  // vec will contain sec. particles

   G4int vecLen = 0;

   vec.Initialize( 0 );


   InitialCollision(vec, vecLen, currentParticle, targetParticle,

                    incidentHasChanged, targetHasChanged);


   CalculateMomenta(vec, vecLen,

                    originalIncident, originalTarget, modifiedOriginal,

                    targetNucleus, currentParticle, targetParticle,

                    incidentHasChanged, targetHasChanged, quasiElastic);


   SetUpChange(vec, vecLen,

               currentParticle, targetParticle,

               incidentHasChanged);


   delete originalTarget;

   return &theParticleChange;

 }


 void

 G4RPGNeutronInelastic::SlowNeutron(const G4HadProjectile* originalIncident,

                               G4ReactionProduct& modifiedOriginal,

                               G4ReactionProduct& targetParticle,

                               G4Nucleus& targetNucleus)

 {

   const G4double A = targetNucleus.GetA_asInt();    // atomic weight

   const G4double Z = targetNucleus.GetZ_asInt();    // atomic number


   G4double currentKinetic = modifiedOriginal.GetKineticEnergy()/MeV;

   G4double currentMass = modifiedOriginal.GetMass()/MeV;

   if( A < 1.5 )   // Hydrogen

   {

     //

     // very simple simulation of scattering angle and energy

     // nonrelativistic approximation with isotropic angular

     // distribution in the cms system

     //

     G4double cost1, eka = 0.0;

     while (eka <= 0.0)

     {

       cost1 = -1.0 + 2.0*G4UniformRand();

       eka = 1.0 + 2.0*cost1*A + A*A;

     }

     G4double cost = std::min( 1.0, std::max( -1.0, (A*cost1+1.0)/std::sqrt(eka) ) );

     eka /= (1.0+A)*(1.0+A);

     G4double ek = currentKinetic*MeV/GeV;

     G4double amas = currentMass*MeV/GeV;

     ek *= eka;

     G4double en = ek + amas;

     G4double p = std::sqrt(std::abs(en*en-amas*amas));

     G4double sint = std::sqrt(std::abs(1.0-cost*cost));

     G4double phi = G4UniformRand()*twopi;

     G4double px = sint*std::sin(phi);

     G4double py = sint*std::cos(phi);

     G4double pz = cost;

     targetParticle.SetMomentum( px*GeV, py*GeV, pz*GeV );

     G4double pxO = originalIncident->Get4Momentum().x()/GeV;

     G4double pyO = originalIncident->Get4Momentum().y()/GeV;

     G4double pzO = originalIncident->Get4Momentum().z()/GeV;

     G4double ptO = pxO*pxO + pyO+pyO;

     if( ptO > 0.0 )

     {

       G4double pO = std::sqrt(pxO*pxO+pyO*pyO+pzO*pzO);

       cost = pzO/pO;

       sint = 0.5*(std::sqrt(std::abs((1.0-cost)*(1.0+cost)))+std::sqrt(ptO)/pO);

       G4double ph = pi/2.0;

       if( pyO < 0.0 )ph = ph*1.5;

       if( std::abs(pxO) > 0.000001 )ph = std::atan2(pyO,pxO);

       G4double cosp = std::cos(ph);

       G4double sinp = std::sin(ph);

       px = cost*cosp*px - sinp*py+sint*cosp*pz;

       py = cost*sinp*px + cosp*py+sint*sinp*pz;

       pz = -sint*px     + cost*pz;

     }

     else

     {

       if( pz < 0.0 )pz *= -1.0;

     }

     G4double pu = std::sqrt(px*px+py*py+pz*pz);

     modifiedOriginal.SetMomentum( targetParticle.GetMomentum() * (p/pu) );

     modifiedOriginal.SetKineticEnergy( ek*GeV );


     targetParticle.SetMomentum(

      originalIncident->Get4Momentum().vect() - modifiedOriginal.GetMomentum() );

     G4double pp = targetParticle.GetMomentum().mag();

     G4double tarmas = targetParticle.GetMass();

     targetParticle.SetTotalEnergy( std::sqrt( pp*pp + tarmas*tarmas ) );


     theParticleChange.SetEnergyChange( modifiedOriginal.GetKineticEnergy() );

     G4DynamicParticle *pd = new G4DynamicParticle;

     pd->SetDefinition( targetParticle.GetDefinition() );

     pd->SetMomentum( targetParticle.GetMomentum() );

     theParticleChange.AddSecondary( pd );

     return;

   }


   G4FastVector<G4ReactionProduct,4> vec;  // vec will contain the secondary particles

   G4int vecLen = 0;

   vec.Initialize( 0 );


   G4double theAtomicMass = targetNucleus.AtomicMass( A, Z );

   G4double massVec[9];

   massVec[0] = targetNucleus.AtomicMass( A+1.0, Z     );

   massVec[1] = theAtomicMass;

   massVec[2] = 0.;

   if (Z > 1.0) massVec[2] = targetNucleus.AtomicMass(A, Z-1.0);

   massVec[3] = 0.;

   if (Z > 1.0 && A > 1.0) massVec[3] = targetNucleus.AtomicMass(A-1.0, Z-1.0 );

   massVec[4] = 0.;

   if (Z > 1.0 && A > 2.0 && A-2.0 > Z-1.0)

     massVec[4] = targetNucleus.AtomicMass( A-2.0, Z-1.0 );

   massVec[5] = 0.;

   if (Z > 2.0 && A > 3.0 && A-3.0 > Z-2.0)

     massVec[5] = targetNucleus.AtomicMass( A-3.0, Z-2.0 );

   massVec[6] = 0.;

   if (A > 1.0 && A-1.0 > Z) massVec[6] = targetNucleus.AtomicMass(A-1.0, Z);

   massVec[7] = massVec[3];

   massVec[8] = 0.;

   if (Z > 2.0 && A > 1.0) massVec[8] = targetNucleus.AtomicMass( A-1.0,Z-2.0 );


   twoBody.NuclearReaction(vec, vecLen, originalIncident,

                           targetNucleus, theAtomicMass, massVec );


   theParticleChange.SetStatusChange( stopAndKill );

   theParticleChange.SetEnergyChange( 0.0 );


   G4DynamicParticle* pd;

   for( G4int i=0; i<vecLen; ++i ) {

     pd = new G4DynamicParticle();

     pd->SetDefinition( vec[i]->GetDefinition() );

     pd->SetMomentum( vec[i]->GetMomentum() );

     theParticleChange.AddSecondary( pd );

     delete vec[i];

   }

 }


 // Initial Collision

 //   selects the particle types arising from the initial collision of

 //   the neutron and target nucleon.  Secondaries are assigned to

 //   forward and backward reaction hemispheres, but final state energies

 //   and momenta are not calculated here.


 void

 G4RPGNeutronInelastic::InitialCollision(G4FastVector<G4ReactionProduct,256>& vec,

                                    G4int& vecLen,

                                    G4ReactionProduct& currentParticle,

                                    G4ReactionProduct& targetParticle,

                                    G4bool& incidentHasChanged,

                                    G4bool& targetHasChanged)

 {

   G4double KE = currentParticle.GetKineticEnergy()/GeV;


   G4int mult;

   G4int partType;

   std::vector<G4int> fsTypes;

   G4int part1;

   G4int part2;


   G4double testCharge;

   G4double testBaryon;

   G4double testStrange;


   // Get particle types according to incident and target types


   if (targetParticle.GetDefinition() == particleDef[neu]) {

     mult = GetMultiplicityT1(KE);

     fsTypes = GetFSPartTypesForNN(mult, KE);


     part1 = fsTypes[0];

     part2 = fsTypes[1];

     currentParticle.SetDefinition(particleDef[part1]);

     targetParticle.SetDefinition(particleDef[part2]);

     if (part1 == pro) {

       if (part2 == neu) {

         if (G4UniformRand() > 0.5) {

           incidentHasChanged = true;

     } else {

           targetHasChanged = true;

           currentParticle.SetDefinition(particleDef[part2]);

           targetParticle.SetDefinition(particleDef[part1]);

     }

       } else {

         targetHasChanged = true;

         incidentHasChanged = true;

       }


     } else { // neutron

       if (part2 > neu && part2 < xi0) targetHasChanged = true;

     }


     testCharge = 0.0;

     testBaryon = 2.0;

     testStrange = 0.0;


   } else { // target was a proton

     mult = GetMultiplicityT0(KE);

     fsTypes = GetFSPartTypesForNP(mult, KE);


     part1 = fsTypes[0];

     part2 = fsTypes[1];

     currentParticle.SetDefinition(particleDef[part1]);

     targetParticle.SetDefinition(particleDef[part2]);

     if (part1 == pro) {

       if (part2 == pro) {

         incidentHasChanged = true;

       } else if (part2 == neu) {

         if (G4UniformRand() > 0.5) {

           incidentHasChanged = true;

           targetHasChanged = true;

     } else {

           currentParticle.SetDefinition(particleDef[part2]);

           targetParticle.SetDefinition(particleDef[part1]);

     }


       } else if (part2 > neu && part2 < xi0) {

         incidentHasChanged = true;

         targetHasChanged = true;

       }


     } else { // neutron

       targetHasChanged = true;

     }


     testCharge = 1.0;

     testBaryon = 2.0;

     testStrange = 0.0;

   }


   //  if (mult == 2 && !incidentHasChanged && !targetHasChanged)

   //                                              quasiElastic = true;


   // Remove incident and target from fsTypes


   fsTypes.erase(fsTypes.begin());

   fsTypes.erase(fsTypes.begin());


   // Remaining particles are secondaries.  Put them into vec.


   G4ReactionProduct* rp(0);

   for(G4int i=0; i < mult-2; ++i ) {

     partType = fsTypes[i];

     rp = new G4ReactionProduct();

     rp->SetDefinition(particleDef[partType]);

     (G4UniformRand() < 0.5) ? rp->SetSide(-1) : rp->SetSide(1);

     vec.SetElement(vecLen++, rp);

   }


   // Check conservation of charge, strangeness, baryon number


   CheckQnums(vec, vecLen, currentParticle, targetParticle,

              testCharge, testBaryon, testStrange);


   return;

 }

G4Nucleus::GetA_asInt
G4int GetA_asInt() const
Definition: G4Nucleus.hh:109

G4HadFinalState
Definition: G4HadFinalState.hh:45

G4Nucleus::AtomicMass
G4double AtomicMass(const G4double A, const G4double Z) const
Definition: G4Nucleus.cc:240

CLHEP::Hep3Vector
Definition: ThreeVector.h:41

G4FastVector::SetElement
void SetElement(G4int anIndex, Type *anElement)
Definition: G4FastVector.hh:76

G4Nucleus::EvaporationEffects
G4double EvaporationEffects(G4double kineticEnergy)
Definition: G4Nucleus.cc:264

python.hepunit.pi
float pi
Definition: hepunit.py:247

python.hepunit.GeV
GeV
Definition: hepunit.py:120

stopAndKill
Definition: G4HadFinalState.hh:42

G4DynamicParticle::SetMomentum
void SetMomentum(const G4ThreeVector &momentum)
Definition: G4DynamicParticle.cc:339

G4Nucleus
Definition: G4Nucleus.hh:50

CLHEP::HepLorentzVector::x
double x() const

G4RPGInelastic::SetUpChange
void SetUpChange(G4FastVector< G4ReactionProduct, 256 > &vec, G4int &vecLen, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, G4bool &incidentHasChanged)
Definition: G4RPGInelastic.cc:403

G4RPGNeutronInelastic::ApplyYourself
G4HadFinalState * ApplyYourself(const G4HadProjectile &aTrack, G4Nucleus &targetNucleus)
Definition: G4RPGNeutronInelastic.cc:35

G4ReactionProduct::SetKineticEnergy
void SetKineticEnergy(const G4double en)
Definition: G4ReactionProduct.hh:132

G4ReactionProduct::SetMomentum
void SetMomentum(const G4double x, const G4double y, const G4double z)
Definition: G4ReactionProduct.cc:165

python.hepunit.MeV
MeV
Definition: hepunit.py:117

p
const char * p
Definition: xmltok.h:285

python.hepunit.twopi
int twopi
Definition: hepunit.py:248

G4HadFinalState::Clear
void Clear()
Definition: G4HadFinalState.cc:89

G4DynamicParticle
Definition: G4DynamicParticle.hh:73

G4ReactionProduct::SetSide
void SetSide(const G4int sid)
Definition: G4ReactionProduct.hh:159

G4HadProjectile
Definition: G4HadProjectile.hh:39

G4RPGInelastic::CalculateMomenta
void CalculateMomenta(G4FastVector< G4ReactionProduct, 256 > &vec, G4int &vecLen, const G4HadProjectile *originalIncident, const G4DynamicParticle *originalTarget, G4ReactionProduct &modifiedOriginal, G4Nucleus &targetNucleus, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, G4bool &incidentHasChanged, G4bool &targetHasChanged, G4bool quasiElastic)
Definition: G4RPGInelastic.cc:202

G4RPGInelastic::xi0
Definition: G4RPGInelastic.hh:122

G4RPGInelastic::pro
Definition: G4RPGInelastic.hh:121

G4FastVector::Initialize
void Initialize(G4int items)
Definition: G4FastVector.hh:63

G4int
int G4int
Definition: G4Types.hh:78

G4Nucleus::ReturnTargetParticle
G4DynamicParticle * ReturnTargetParticle() const
Definition: G4Nucleus.cc:227

G4ReactionProduct
Definition: G4ReactionProduct.hh:53

G4RPGInelastic::neu
Definition: G4RPGInelastic.hh:121

G4ReactionProduct::GetDefinition
G4ParticleDefinition * GetDefinition() const
Definition: G4ReactionProduct.hh:107

G4HadFinalState::SetStatusChange
void SetStatusChange(G4HadFinalStateStatus aS)
Definition: G4HadFinalState.cc:81

G4RPGNucleonInelastic::GetMultiplicityT1
G4int GetMultiplicityT1(G4double KE) const
Definition: G4RPGNucleonInelastic.cc:118

CLHEP::HepLorentzVector::vect
Hep3Vector vect() const

G4UniformRand
#define G4UniformRand()
Definition: Randomize.hh:87

G4RPGNeutronInelastic.hh

G4HadProjectile::GetDefinition
const G4ParticleDefinition * GetDefinition() const
Definition: G4HadProjectile.hh:81

G4RPGInelastic::particleDef
G4ParticleDefinition * particleDef[18]
Definition: G4RPGInelastic.hh:126

G4bool
bool G4bool
Definition: G4Types.hh:79

CLHEP::HepLorentzVector::y
double y() const

G4HadProjectile::GetKineticEnergy
G4double GetKineticEnergy() const
Definition: G4HadProjectile.hh:106

G4ReactionProduct::SetTotalEnergy
void SetTotalEnergy(const G4double en)
Definition: G4ReactionProduct.hh:141

Randomize.hh

CLHEP::HepLorentzVector::z
double z() const

G4HadProjectile::Get4Momentum
const G4LorentzVector & Get4Momentum() const
Definition: G4HadProjectile.hh:86

G4PhysicalConstants.hh

G4ReactionProduct::GetKineticEnergy
G4double GetKineticEnergy() const
Definition: G4ReactionProduct.hh:138

G4FastVector
Definition: G4FastVector.hh:43

G4HadFinalState::SetEnergyChange
void SetEnergyChange(G4double anEnergy)
Definition: G4HadFinalState.cc:42

G4ParticleDefinition::GetPDGMass
G4double GetPDGMass() const
Definition: G4ParticleDefinition.hh:161

G4RPGReaction::NuclearReaction
void NuclearReaction(G4FastVector< G4ReactionProduct, 4 > &vec, G4int &vecLen, const G4HadProjectile *originalIncident, const G4Nucleus &aNucleus, const G4double theAtomicMass, const G4double *massVec)
Definition: G4RPGReaction.cc:1094

G4InuclParticleNames::pp
Definition: G4InuclParticleNames.hh:67

G4INCL::Math::max
T max(const T t1, const T t2)
brief Return the largest of the two arguments
Definition: G4INCLGlobals.hh:116

G4Nucleus::Cinema
G4double Cinema(G4double kineticEnergy)
Definition: G4Nucleus.cc:368

G4RPGNucleonInelastic::GetFSPartTypesForNN
std::vector< G4int > GetFSPartTypesForNN(G4int mult, G4double KE) const
Definition: G4RPGNucleonInelastic.hh:65

G4Nucleus::GetZ_asInt
G4int GetZ_asInt() const
Definition: G4Nucleus.hh:115

G4INCL::Math::min
T min(const T t1, const T t2)
brief Return the smallest of the two arguments
Definition: G4INCLGlobals.hh:121

G4ReactionProduct::SetDefinition
void SetDefinition(G4ParticleDefinition *aParticleDefinition)
Definition: G4ReactionProduct.cc:154

G4ReactionProduct::GetMomentum
G4ThreeVector GetMomentum() const
Definition: G4ReactionProduct.hh:123

G4HadronicInteraction::theParticleChange
G4HadFinalState theParticleChange
Definition: G4HadronicInteraction.hh:177

G4RPGNucleonInelastic::GetFSPartTypesForNP
std::vector< G4int > GetFSPartTypesForNP(G4int mult, G4double KE) const
Definition: G4RPGNucleonInelastic.hh:71

G4RPGInelastic::CheckQnums
void CheckQnums(G4FastVector< G4ReactionProduct, 256 > &vec, G4int &vecLen, G4ReactionProduct &currentParticle, G4ReactionProduct &targetParticle, G4double Q, G4double B, G4double S)
Definition: G4RPGInelastic.cc:545

G4double
double G4double
Definition: G4Types.hh:76

G4DynamicParticle::SetDefinition
void SetDefinition(const G4ParticleDefinition *aParticleDefinition)
Definition: G4DynamicParticle.cc:273

G4SystemOfUnits.hh

G4RPGNucleonInelastic::GetMultiplicityT0
G4int GetMultiplicityT0(G4double KE) const
Definition: G4RPGNucleonInelastic.cc:99

CLHEP::Hep3Vector::mag
double mag() const

G4ReactionProduct::GetMass
G4double GetMass() const
Definition: G4ReactionProduct.hh:150

G4HadFinalState::AddSecondary
void AddSecondary(G4DynamicParticle *aP)
Definition: G4HadFinalState.cc:70

G4RPGInelastic::twoBody
G4RPGTwoBody twoBody
Definition: G4RPGInelastic.hh:109