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 // $Id: G4VGammaDeexcitation.cc 67983 2013-03-13 10:42:03Z gcosmo $

 //

 // -------------------------------------------------------------------

 //      GEANT 4 class file

 //

 //      CERN, Geneva, Switzerland

 //

 //      File name:     G4VGammaDeexcitation

 //

 //      Author:        Maria Grazia Pia (pia@genova.infn.it)

 //

 //      Creation date: 23 October 1998

 //

 //      Modifications:

 //

 //        21 Nov 2001, Fan Lei (flei@space.qinetiq.com)

 //           Modified GenerateGamma() and UpdateUncleus() for implementation

 //           of Internal Conversion processs

 //

 //        15 April 1999, Alessandro Brunengo (Alessandro.Brunengo@ge.infn.it)

 //              Added creation time evaluation for products of evaporation

 //

 //        19 April 2010, J. M. Quesada calculations in CM system

 //              pending final boost to lab system  (not critical)

 //

 //        23 April 2010, V.Ivanchenko rewite kinematic part using PDG formula

 //                                    for 2-body decay

 //

 //        07 May   2011, V.Ivanchenko implement check ICM flag - produce or not e-

 //

 // -------------------------------------------------------------------


 #include "G4VGammaDeexcitation.hh"


 #include "globals.hh"

 #include "G4PhysicalConstants.hh"

 #include "Randomize.hh"

 #include "G4Gamma.hh"

 #include "G4Electron.hh"

 #include "G4LorentzVector.hh"

 #include "G4VGammaTransition.hh"

 #include "G4Fragment.hh"

 #include "G4FragmentVector.hh"


 #include "G4ParticleTable.hh"

 #include "G4IonTable.hh"


 #include "G4DiscreteGammaTransition.hh"


 G4VGammaDeexcitation::G4VGammaDeexcitation(): _transition(0), _verbose(0),

                           _electronO (0), _vSN(-1)

 {

   _nucleus = 0;

   fTimeLimit = DBL_MAX;

 }


 G4VGammaDeexcitation::~G4VGammaDeexcitation()

 {

   if (_transition != 0) { delete _transition; }

 }


 G4FragmentVector* G4VGammaDeexcitation::DoTransition()

 {

   Initialize();

   G4FragmentVector* products = new G4FragmentVector();


   if (CanDoTransition())

     {

       G4Fragment* gamma = GenerateGamma();

       if (gamma != 0) { products->push_back(gamma); }

     }


   if (_verbose > 1) {

     G4cout << "G4VGammaDeexcitation::DoTransition - Transition deleted " << G4endl;

   }


   return products;

 }


 G4FragmentVector* G4VGammaDeexcitation::DoChain()

 {

   if (_verbose > 1) { G4cout << "G4VGammaDeexcitation::DoChain" << G4endl; }

   const G4double tolerance = CLHEP::keV;


   Initialize();

   G4FragmentVector* products = new G4FragmentVector();


   while (CanDoTransition())

     {

       _transition->SetEnergyFrom(_nucleus->GetExcitationEnergy());

       G4Fragment* gamma = GenerateGamma();

       if (gamma != 0)

     {

       products->push_back(gamma);

       //G4cout << "Eex(keV)= " << _nucleus->GetExcitationEnergy()/keV << G4endl;

       if(_nucleus->GetExcitationEnergy() <= tolerance) { break; }

       Update();

     }

     }


   if (_verbose > 1) {

     G4cout << "G4VGammaDeexcitation::DoChain - Transition deleted, end of chain " << G4endl;

   }


   return products;

 }


 G4Fragment* G4VGammaDeexcitation::GenerateGamma()

 {

   // 23/04/10 V.Ivanchenko rewrite complitely

   G4double eGamma = 0.;


   if (_transition) {

     _transition->SelectGamma();  // it can be conversion electron too

     eGamma = _transition->GetGammaEnergy();

     //G4cout << "G4VGammaDeexcitation::GenerateGamma - Egam(MeV)= "

     //     << eGamma << G4endl;

     if(eGamma <= 0.0) { return 0; }

   } else { return 0; }


   G4double excitation = _nucleus->GetExcitationEnergy() - eGamma;

   if(excitation < 0.0) { excitation = 0.0; }

   if (_verbose > 1)

     {

       G4cout << "G4VGammaDeexcitation::GenerateGamma - Edeexc(MeV)= " << eGamma

          << " ** left Eexc(MeV)= " << excitation

          << G4endl;

     }


   G4double gammaTime = _transition->GetGammaCreationTime();


   // Do complete Lorentz computation

   G4LorentzVector lv = _nucleus->GetMomentum();

   G4double Mass = _nucleus->GetGroundStateMass() + excitation;


   // select secondary

   G4ParticleDefinition* gamma = G4Gamma::Gamma();


   G4DiscreteGammaTransition* dtransition =

     dynamic_cast <G4DiscreteGammaTransition*> (_transition);


   G4bool eTransition = false;

   if (dtransition && !( dtransition->IsAGamma()) ) {

     eTransition = true;

     gamma = G4Electron::Electron();

     _vSN = dtransition->GetOrbitNumber();

     _electronO.RemoveElectron(_vSN);

     lv += G4LorentzVector(0.0,0.0,0.0,CLHEP::electron_mass_c2 - dtransition->GetBondEnergy());

   }


   G4double cosTheta = 1. - 2. * G4UniformRand();

   G4double sinTheta = std::sqrt(1. - cosTheta * cosTheta);

   G4double phi = twopi * G4UniformRand();


   G4double eMass = gamma->GetPDGMass();

   G4LorentzVector Gamma4P;


   //G4cout << "Egamma= " << eGamma << " Mass= " << eMass << " t= " << gammaTime

   //     << " tlim= " << fTimeLimit << G4endl;


   if(gammaTime > fTimeLimit) {

     // shortcut for long lived levels

     // not correct position of stopping ion gamma emission

     // 4-momentum balance is breaked

     G4double e = eGamma + eMass;

     G4double mom = std::sqrt(eGamma*(eGamma + 2*eMass));

     Gamma4P.set(mom * sinTheta * std::cos(phi),

         mom * sinTheta * std::sin(phi),

         mom * cosTheta, e);

     lv -= Gamma4P;

     e = lv.e();

     if(e < Mass) { e = Mass; }

     mom = std::sqrt((e - Mass)*(e + Mass));

     G4ThreeVector v = lv.vect().unit();

     lv.set(mom*v.x(), mom*v.y(), mom*v.z(), e);


   } else {

     // 2-body decay in rest frame

     G4double Ecm       = lv.mag();

     G4ThreeVector bst  = lv.boostVector();


     G4double GammaEnergy = 0.5*((Ecm - Mass)*(Ecm + Mass) + eMass*eMass)/Ecm;

     if(GammaEnergy <= eMass) { return 0; }


     G4double mom = std::sqrt((GammaEnergy - eMass)*(GammaEnergy + eMass));

     Gamma4P.set(mom * sinTheta * std::cos(phi),

         mom * sinTheta * std::sin(phi),

         mom * cosTheta,

         GammaEnergy);


     Gamma4P.boost(bst);

     lv -= Gamma4P;

   }


   // modified primary fragment

   gammaTime += _nucleus->GetCreationTime();


   _nucleus->SetMomentum(lv);

   _nucleus->SetCreationTime(gammaTime);


   // e- is not produced

   if(eTransition && !dtransition->GetICM()) { return 0; }


   // gamma or e- are produced

   G4Fragment * thePhoton = new G4Fragment(Gamma4P,gamma);

   thePhoton->SetCreationTime(gammaTime);


   //G4cout << "G4VGammaDeexcitation::GenerateGamma : " << thePhoton << G4endl;

   //G4cout << "       Left nucleus: " << _nucleus << G4endl;

   return thePhoton;

 }


 void G4VGammaDeexcitation::Update()

 {

   if (_transition !=  0)

     {

       delete _transition;

       _transition = 0;

       if (_verbose > 1) {

     G4cout << "G4VGammaDeexcitation::Update - Transition deleted " << G4endl;

       }

     }


   _transition = CreateTransition();

   if (_transition != 0)

     {

       _transition->SetEnergyFrom(_nucleus->GetExcitationEnergy());

       // if ( _vSN != -1) (dynamic_cast <G4DiscreteGammaTransition*> (_transition))->SetICM(false);

       // the above line is commented out for bug fix #952. It was intruduced for reason that

       // the k-shell electron is most likely one to be kicked out and there is no time for

       // the atom to deexcite before the next IC. But this limitation is causing other problems as

       // reported in #952

     }


   return;

 }

G4LorentzVector.hh

CLHEP::HepLorentzVector::boostVector
Hep3Vector boostVector() const
Definition: LorentzVector.cc:177

CLHEP::Hep3Vector
Definition: ThreeVector.h:41

G4VGammaDeexcitation::CanDoTransition
virtual G4bool CanDoTransition()=0

G4VGammaTransition::GetGammaEnergy
virtual G4double GetGammaEnergy()=0

G4VGammaDeexcitation::Update
void Update()
Definition: G4VGammaDeexcitation.cc:239

CLHEP::Hep3Vector::x
double x() const

G4VGammaDeexcitation::G4VGammaDeexcitation
G4VGammaDeexcitation()
Definition: G4VGammaDeexcitation.cc:76

G4VGammaTransition::SetEnergyFrom
virtual void SetEnergyFrom(G4double energy)=0

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

G4DiscreteGammaTransition::IsAGamma
G4bool IsAGamma()
Definition: G4DiscreteGammaTransition.hh:102

G4DiscreteGammaTransition::GetOrbitNumber
G4int GetOrbitNumber()
Definition: G4DiscreteGammaTransition.hh:101

G4Fragment
Definition: G4Fragment.hh:68

G4ParticleDefinition
Definition: G4ParticleDefinition.hh:111

CLHEP::Hep3Vector::z
double z() const

G4IonTable.hh

G4VGammaDeexcitation::CreateTransition
virtual G4VGammaTransition * CreateTransition()=0

G4DiscreteGammaTransition::GetICM
G4bool GetICM() const
Definition: G4DiscreteGammaTransition.hh:99

G4VGammaDeexcitation::Initialize
void Initialize()
Definition: G4VGammaDeexcitation.hh:143

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

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

G4cout
G4GLOB_DLL std::ostream G4cout

G4VGammaTransition::SelectGamma
virtual void SelectGamma()=0

G4ParticleTable.hh

G4Fragment::GetCreationTime
G4double GetCreationTime() const
Definition: G4Fragment.hh:398

G4Fragment.hh

CLHEP::HepLorentzVector::mag
double mag() const

G4bool
bool G4bool
Definition: G4Types.hh:79

G4Fragment::GetMomentum
const G4LorentzVector & GetMomentum() const
Definition: G4Fragment.hh:271

CLHEP::HepLorentzVector::boost
HepLorentzVector & boost(double, double, double)
Definition: LorentzVector.cc:59

G4Fragment::SetMomentum
void SetMomentum(const G4LorentzVector &value)
Definition: G4Fragment.hh:276

G4FragmentVector
std::vector< G4Fragment * > G4FragmentVector
Definition: G4Fragment.hh:65

G4Fragment::GetGroundStateMass
G4double GetGroundStateMass() const
Definition: G4Fragment.hh:260

Randomize.hh

G4Gamma::Gamma
static G4Gamma * Gamma()
Definition: G4Gamma.cc:86

G4VGammaDeexcitation::DoChain
G4FragmentVector * DoChain()
Definition: G4VGammaDeexcitation.cc:106

globals.hh

G4VGammaDeexcitation::GenerateGamma
G4Fragment * GenerateGamma()
Definition: G4VGammaDeexcitation.cc:134

test.v
tuple v
Definition: tests/test12/test.py:18

G4PhysicalConstants.hh

G4Electron.hh

G4Fragment::SetCreationTime
void SetCreationTime(G4double time)
Definition: G4Fragment.hh:403

CLHEP::HepLorentzVector::set
void set(double x, double y, double z, double t)

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

G4DiscreteGammaTransition::GetBondEnergy
G4double GetBondEnergy()
Definition: G4DiscreteGammaTransition.hh:100

G4FragmentVector.hh

G4VGammaDeexcitation::DoTransition
G4FragmentVector * DoTransition()
Definition: G4VGammaDeexcitation.cc:88

CLHEP::HepLorentzVector::e
double e() const

G4DiscreteGammaTransition.hh

CLHEP::Hep3Vector::unit
Hep3Vector unit() const

CLHEP::Hep3Vector::y
double y() const

G4VGammaDeexcitation::_transition
G4VGammaTransition * _transition
Definition: G4VGammaDeexcitation.hh:111

G4VGammaDeexcitation::~G4VGammaDeexcitation
virtual ~G4VGammaDeexcitation()
Definition: G4VGammaDeexcitation.cc:83

G4DiscreteGammaTransition
Definition: G4DiscreteGammaTransition.hh:79

G4Electron::Electron
static G4Electron * Electron()
Definition: G4Electron.cc:94

G4endl
#define G4endl
Definition: G4ios.hh:61

CLHEP::HepLorentzVector
Definition: LorentzVector.h:72

G4double
double G4double
Definition: G4Types.hh:76

G4VGammaTransition.hh

DBL_MAX
#define DBL_MAX
Definition: templates.hh:83

G4VGammaDeexcitation::_verbose
G4int _verbose
Definition: G4VGammaDeexcitation.hh:112

G4Fragment::GetExcitationEnergy
G4double GetExcitationEnergy() const
Definition: G4Fragment.hh:255

G4VGammaDeexcitation.hh

G4Gamma.hh

G4ElectronOccupancy::RemoveElectron
G4int RemoveElectron(G4int orbit, G4int number=1)
Definition: G4ElectronOccupancy.hh:160

G4LorentzVector
CLHEP::HepLorentzVector G4LorentzVector
Definition: G4LorentzVector.hh:35

G4VGammaTransition::GetGammaCreationTime
virtual G4double GetGammaCreationTime()=0