G4VLongitudinalStringDecay Class Reference

#include <G4VLongitudinalStringDecay.hh>

Inheritance diagram for G4VLongitudinalStringDecay:

Public Member Functions
	G4VLongitudinalStringDecay (const G4String &name="StringDecay")
virtual	~G4VLongitudinalStringDecay ()
G4HadFinalState *	ApplyYourself (const G4HadProjectile &, G4Nucleus &) final
virtual G4KineticTrackVector *	FragmentString (const G4ExcitedString &theString)=0
void	AddNewParticles ()
void	EraseNewParticles ()
void	SetMinMasses ()
void	SetMinimalStringMass (const G4FragmentingString *const string)
void	SetMinimalStringMass2 (const G4double aValue)
G4int	SampleQuarkFlavor (void)
G4ThreeVector	SampleQuarkPt (G4double ptMax=-1.)
void	SetSigmaTransverseMomentum (G4double aQT)
void	SetStrangenessSuppression (G4double aValue)
void	SetDiquarkSuppression (G4double aValue)
void	SetDiquarkBreakProbability (G4double aValue)
void	SetSpinThreeHalfBarionProbability (G4double aValue)
void	SetScalarMesonMixings (std::vector< G4double > aVector)
void	SetVectorMesonMixings (std::vector< G4double > aVector)
void	SetStringTensionParameter (G4double aValue)
void	SetProbCCbar (G4double aValue)
void	SetProbEta_c (G4double aValue)
void	SetProbBBbar (G4double aValue)
void	SetProbEta_b (G4double aValue)
Public Member Functions inherited from G4HadronicInteraction
	G4HadronicInteraction (const G4String &modelName="HadronicModel")
virtual	~G4HadronicInteraction ()
virtual G4double	SampleInvariantT (const G4ParticleDefinition *p, G4double plab, G4int Z, G4int A)
virtual G4bool	IsApplicable (const G4HadProjectile &aTrack, G4Nucleus &targetNucleus)
G4double	GetMinEnergy () const
G4double	GetMinEnergy (const G4Material *aMaterial, const G4Element *anElement) const
void	SetMinEnergy (G4double anEnergy)
void	SetMinEnergy (G4double anEnergy, const G4Element *anElement)
void	SetMinEnergy (G4double anEnergy, const G4Material *aMaterial)
G4double	GetMaxEnergy () const
G4double	GetMaxEnergy (const G4Material *aMaterial, const G4Element *anElement) const
void	SetMaxEnergy (const G4double anEnergy)
void	SetMaxEnergy (G4double anEnergy, const G4Element *anElement)
void	SetMaxEnergy (G4double anEnergy, const G4Material *aMaterial)
G4int	GetVerboseLevel () const
void	SetVerboseLevel (G4int value)
const G4String &	GetModelName () const
void	DeActivateFor (const G4Material *aMaterial)
void	ActivateFor (const G4Material *aMaterial)
void	DeActivateFor (const G4Element *anElement)
void	ActivateFor (const G4Element *anElement)
G4bool	IsBlocked (const G4Material *aMaterial) const
G4bool	IsBlocked (const G4Element *anElement) const
void	SetRecoilEnergyThreshold (G4double val)
G4double	GetRecoilEnergyThreshold () const
virtual const std::pair< G4double, G4double >	GetFatalEnergyCheckLevels () const
virtual std::pair< G4double, G4double >	GetEnergyMomentumCheckLevels () const
void	SetEnergyMomentumCheckLevels (G4double relativeLevel, G4double absoluteLevel)
virtual void	ModelDescription (std::ostream &outFile) const
virtual void	BuildPhysicsTable (const G4ParticleDefinition &)
virtual void	InitialiseModel ()
	G4HadronicInteraction (const G4HadronicInteraction &right)=delete
const G4HadronicInteraction &	operator= (const G4HadronicInteraction &right)=delete
G4bool	operator== (const G4HadronicInteraction &right) const =delete
G4bool	operator!= (const G4HadronicInteraction &right) const =delete

Public Attributes
G4double	Mass_of_light_quark
G4double	Mass_of_s_quark
G4double	Mass_of_c_quark
G4double	Mass_of_b_quark
G4double	Mass_of_string_junction
G4double	minMassQQbarStr [5][5]
G4double	minMassQDiQStr [5][5][5]
G4double	MinimalStringMass
G4double	MinimalStringMass2
G4int	Qcharge [5]
G4int	Meson [5][5][7]
G4double	MesonWeight [5][5][7]
G4int	Baryon [5][5][5][4]
G4double	BaryonWeight [5][5][5][4]
G4double	Prob_QQbar [5]
G4int	DecayQuark
G4int	NewQuark
G4ParticleDefinition *	FS_LeftHadron [350]
G4ParticleDefinition *	FS_RightHadron [350]
G4double	FS_Weight [350]
G4int	NumberOf_FS

Protected Types
typedef std::pair< G4ParticleDefinition *, G4ParticleDefinition * >	pDefPair
typedef G4ParticleDefinition *(G4HadronBuilder::*)	Pcreate(G4ParticleDefinition *, G4ParticleDefinition *)

Protected Member Functions
virtual void	SetMassCut (G4double aValue)
G4double	GetMassCut ()
G4KineticTrackVector *	ProduceOneHadron (const G4ExcitedString *const theString)
G4double	PossibleHadronMass (const G4FragmentingString *const string, Pcreate build=0, pDefPair *pdefs=0)
G4ParticleDefinition *	FindParticle (G4int Encoding)
virtual G4bool	StopFragmenting (const G4FragmentingString *const string)=0
virtual G4bool	IsItFragmentable (const G4FragmentingString *const string)=0
virtual G4bool	SplitLast (G4FragmentingString *string, G4KineticTrackVector *LeftVector, G4KineticTrackVector *RightVector)=0
virtual void	Sample4Momentum (G4LorentzVector *Mom, G4double Mass, G4LorentzVector *AntiMom, G4double AntiMass, G4double InitialMass)=0
G4ExcitedString *	CopyExcited (const G4ExcitedString &string)
virtual G4KineticTrack *	Splitup (G4FragmentingString *string, G4FragmentingString *&newString)=0
virtual G4ParticleDefinition *	QuarkSplitup (G4ParticleDefinition *decay, G4ParticleDefinition *&created)
virtual G4ParticleDefinition *	DiQuarkSplitup (G4ParticleDefinition *decay, G4ParticleDefinition *&created)=0
pDefPair	CreatePartonPair (G4int NeedParticle, G4bool AllowDiquarks=true)
virtual G4LorentzVector *	SplitEandP (G4ParticleDefinition *pHadron, G4FragmentingString *string, G4FragmentingString *newString)=0
virtual G4double	GetLightConeZ (G4double zmin, G4double zmax, G4int PartonEncoding, G4ParticleDefinition *pHadron, G4double Px, G4double Py)=0
void	CalculateHadronTimePosition (G4double theInitialStringMass, G4KineticTrackVector *)
void	ConstructParticle ()
G4ParticleDefinition *	CreateHadron (G4int id1, G4int id2, G4bool theGivenSpin, G4int theSpin)
G4double	GetDiquarkSuppress ()
G4double	GetDiquarkBreakProb ()
G4double	GetStrangeSuppress ()
G4int	GetClusterLoopInterrupt ()
G4double	GetProbCCbar ()
G4double	GetProbEta_c ()
G4double	GetProbBBbar ()
G4double	GetProbEta_b ()
G4double	GetStringTensionParameter ()
Protected Member Functions inherited from G4HadronicInteraction
void	SetModelName (const G4String &nam)
G4bool	IsBlocked () const
void	Block ()

Protected Attributes
G4double	MassCut
G4double	SigmaQT
G4double	DiquarkSuppress
G4double	DiquarkBreakProb
G4double	StrangeSuppress
G4int	StringLoopInterrupt
G4int	ClusterLoopInterrupt
G4HadronBuilder *	hadronizer
std::vector< G4double >	pspin_meson
G4double	pspin_barion
std::vector< G4double >	vectorMesonMix
std::vector< G4double >	scalarMesonMix
G4double	ProbCCbar
G4double	ProbEta_c
G4double	ProbBBbar
G4double	ProbEta_b
G4double	ProbCB
G4double	MaxMass
G4bool	PastInitPhase
G4double	Kappa
std::vector< G4ParticleDefinition * >	NewParticles
Protected Attributes inherited from G4HadronicInteraction
G4HadFinalState	theParticleChange
G4int	verboseLevel
G4double	theMinEnergy
G4double	theMaxEnergy
G4bool	isBlocked

Detailed Description

Definition at line 46 of file G4VLongitudinalStringDecay.hh.

Member Typedef Documentation

Pcreate

G4ParticleDefinition *(G4HadronBuilder::*) G4VLongitudinalStringDecay::Pcreate(G4ParticleDefinition *, G4ParticleDefinition *)

protected

Definition at line 86 of file G4VLongitudinalStringDecay.hh.

pDefPair

std::pair<G4ParticleDefinition*, G4ParticleDefinition*> G4VLongitudinalStringDecay::pDefPair

protected

Definition at line 83 of file G4VLongitudinalStringDecay.hh.

Constructor & Destructor Documentation

G4VLongitudinalStringDecay()

G4VLongitudinalStringDecay::G4VLongitudinalStringDecay

(

const G4String &

name = "StringDecay"

)

Definition at line 67 of file G4VLongitudinalStringDecay.cc.

  : G4HadronicInteraction(name), ProbCCbar(0.0), ProbBBbar(0.0)
{
   MassCut = 210.0*MeV;   // Mpi + Delta
 
   StringLoopInterrupt  = 1000;
   ClusterLoopInterrupt =  500;
 
   // Changable Parameters below.
   SigmaQT = 0.5 * GeV;
   
   StrangeSuppress  = 0.44;    // =0.27/2.27 suppression of strange quark pair production, ie. u:d:s=1:1:0.27
   DiquarkSuppress  = 0.07;    // Probability of qq-qqbar pair production
   DiquarkBreakProb = 0.1;     // Probability of (qq)->h+(qq)'
   
   //... pspin_meson is probability to create pseudo-scalar meson 
   pspin_meson.resize(3);
   pspin_meson[0] = 0.5;  // u or d + anti-u or anti-d
   pspin_meson[1] = 0.4;  // one of the quark is strange, or charm, or bottom
   pspin_meson[2] = 0.3;  // both of the quark are strange, or charm, or bottom
   
   //... pspin_barion is probability to create 1/2 barion 
   pspin_barion = 0.5;
 
   //... vectorMesonMix[] is quark mixing parameters for vector mesons (Variable spin = 3)
   vectorMesonMix.resize(6);
   vectorMesonMix[0] = 0.0;
   vectorMesonMix[1] = 0.5;
   vectorMesonMix[2] = 0.0;
   vectorMesonMix[3] = 0.5;
   vectorMesonMix[4] = 1.0;
   vectorMesonMix[5] = 1.0;
 
   //... scalarMesonMix[] is quark mixing parameters for scalar mesons (Variable spin=1)
   scalarMesonMix.resize(6);
   scalarMesonMix[0] = 0.5;
   scalarMesonMix[1] = 0.25;
   scalarMesonMix[2] = 0.5;
   scalarMesonMix[3] = 0.25;
   scalarMesonMix[4] = 1.0;
   scalarMesonMix[5] = 0.5;
 
   SetProbCCbar(0.0);  // Probability of CCbar pair creation
   SetProbEta_c(0.1);  // Mixing of Eta_c and J/Psi
   SetProbBBbar(0.0);  // Probability of BBbar pair creation
   SetProbEta_b(0.0);  // Mixing of Eta_b and Upsilon_b
 
   // Parameters may be changed until the first fragmentation starts
   PastInitPhase=false;
   hadronizer = new G4HadronBuilder( pspin_meson, pspin_barion, scalarMesonMix, vectorMesonMix,
                                     ProbEta_c, ProbEta_b );
 
   MaxMass=-350.0*GeV;  // If there will be a particle with mass larger than Higgs the value must be changed.
 
   SetMinMasses();  // Re-calculation of minimal mass of strings and weights of particles in 2-part. decays
 
   Kappa = 1.0 * GeV/fermi;
   DecayQuark = NewQuark = 0;
}

~G4VLongitudinalStringDecay()

G4VLongitudinalStringDecay::~G4VLongitudinalStringDecay ( )

virtual

Definition at line 127 of file G4VLongitudinalStringDecay.cc.

{
   delete hadronizer;
}

Member Function Documentation

AddNewParticles()

void G4VLongitudinalStringDecay::AddNewParticles

(

)

ApplyYourself()

G4HadFinalState * G4VLongitudinalStringDecay::ApplyYourself ( const G4HadProjectile & , G4Nucleus &  )

finalvirtual

Reimplemented from G4HadronicInteraction.

Definition at line 133 of file G4VLongitudinalStringDecay.cc.

{
  return nullptr;
}

CalculateHadronTimePosition()

void G4VLongitudinalStringDecay::CalculateHadronTimePosition ( G4double theInitialStringMass, G4KineticTrackVector * Hadrons )

protected

Definition at line 437 of file G4VLongitudinalStringDecay.cc.

{
   //   `yo-yo` formation time
   //   const G4double kappa = 1.0 * GeV/fermi/4.;      
   G4double kappa = GetStringTensionParameter();
   for (size_t c1 = 0; c1 < Hadrons->size(); c1++)
   {
      G4double SumPz = 0; 
      G4double SumE  = 0;
      for (size_t c2 = 0; c2 < c1; c2++)
      {
         SumPz += Hadrons->operator[](c2)->Get4Momentum().pz();
         SumE  += Hadrons->operator[](c2)->Get4Momentum().e();   
      } 
      G4double HadronE  = Hadrons->operator[](c1)->Get4Momentum().e();
      G4double HadronPz = Hadrons->operator[](c1)->Get4Momentum().pz();
      Hadrons->operator[](c1)->SetFormationTime(
        (theInitialStringMass - 2.*SumPz + HadronE - HadronPz ) / (2.*kappa) / c_light ); 
      G4ThreeVector aPosition( 0, 0,
        (theInitialStringMass - 2.*SumE  - HadronE + HadronPz) / (2.*kappa) );
      Hadrons->operator[](c1)->SetPosition(aPosition);
   }
}

Referenced by G4QGSMFragmentation::FragmentString().

ConstructParticle()

void G4VLongitudinalStringDecay::ConstructParticle ( )

protected

CopyExcited()

G4ExcitedString * G4VLongitudinalStringDecay::CopyExcited ( const G4ExcitedString & string )

protected

Definition at line 328 of file G4VLongitudinalStringDecay.cc.

{
    G4Parton *Left=new G4Parton(*in.GetLeftParton());
    G4Parton *Right=new G4Parton(*in.GetRightParton());
    return new G4ExcitedString(Left,Right,in.GetDirection());
}

Referenced by G4QGSMFragmentation::FragmentString().

CreateHadron()

G4ParticleDefinition * G4VLongitudinalStringDecay::CreateHadron ( G4int id1, G4int id2, G4bool theGivenSpin, G4int theSpin )

protected

CreatePartonPair()

G4VLongitudinalStringDecay::pDefPair G4VLongitudinalStringDecay::CreatePartonPair ( G4int NeedParticle, G4bool AllowDiquarks = true )

protected

Definition at line 362 of file G4VLongitudinalStringDecay.cc.

{
    //  NeedParticle = +1 for Particle, -1 for Antiparticle
    if ( AllowDiquarks && G4UniformRand() < DiquarkSuppress )
    {
      // Create a Diquark - AntiDiquark pair , first in pair is anti to IsParticle
      #ifdef debug_VStringDecay
      G4cout<<"VlongSD Create a Diquark - AntiDiquark pair"<<G4endl;
      #endif
      G4int q1(0), q2(0), spin(0), PDGcode(0);
 
      q1  = SampleQuarkFlavor();
      q2  = SampleQuarkFlavor();
 
      spin = (q1 != q2 && G4UniformRand() <= 0.5)? 1 : 3;
                                     //   convention: quark with higher PDG number is first
      PDGcode = (std::max(q1,q2) * 1000 + std::min(q1,q2) * 100 + spin) * NeedParticle;
 
      return pDefPair (FindParticle(-PDGcode),FindParticle(PDGcode));
 
    } else {
      // Create a Quark - AntiQuark pair, first in pair  IsParticle
      #ifdef debug_VStringDecay
      G4cout<<"VlongSD Create a Quark - AntiQuark pair"<<G4endl; 
      #endif
      G4int PDGcode=SampleQuarkFlavor()*NeedParticle;
      return pDefPair (FindParticle(PDGcode),FindParticle(-PDGcode));
    }
}

Referenced by QuarkSplitup().

DiQuarkSplitup()

virtual G4ParticleDefinition * G4VLongitudinalStringDecay::DiQuarkSplitup ( G4ParticleDefinition * decay, G4ParticleDefinition *& created )

protectedpure virtual

EraseNewParticles()

void G4VLongitudinalStringDecay::EraseNewParticles

(

)

FindParticle()

G4ParticleDefinition * G4VLongitudinalStringDecay::FindParticle ( G4int Encoding )

protected

Definition at line 282 of file G4VLongitudinalStringDecay.cc.

{
  /*
  G4cout<<Encoding<<" G4VLongitudinalStringDecay::FindParticle Check di-quarks *******************"<<G4endl;
  for (G4int i=4; i<6;i++){
    for (G4int j=1;j<6;j++){
      G4cout<<i<<" "<<j<<" ";
      G4int Code = 1000 * i + 100 * j +1;
      G4ParticleDefinition* ptr1 = G4ParticleTable::GetParticleTable()->FindParticle(Code);
      Code +=2;
      G4ParticleDefinition* ptr2 = G4ParticleTable::GetParticleTable()->FindParticle(Code);
      G4cout<<"Code "<<Code - 2<<" ptr "<<ptr1<<" :: Code "<<Code<<" ptr "<<ptr2<<G4endl;
    }
    G4cout<<G4endl;
  }
  */
 
  G4ParticleDefinition* ptr = G4ParticleTable::GetParticleTable()->FindParticle(Encoding);
 
  if (ptr == nullptr)
  {
     for (size_t i=0; i < NewParticles.size(); i++)
     {
       if ( Encoding == NewParticles[i]->GetPDGEncoding() ) { ptr = NewParticles[i]; return ptr;}
     }
  }
 
  return ptr;    
}

Referenced by CreatePartonPair(), PossibleHadronMass(), and SetMinMasses().

FragmentString()

virtual G4KineticTrackVector * G4VLongitudinalStringDecay::FragmentString ( const G4ExcitedString & theString )

pure virtual

Implemented in G4LundStringFragmentation, and G4QGSMFragmentation.

GetClusterLoopInterrupt()

G4int G4VLongitudinalStringDecay::GetClusterLoopInterrupt ( )

inlineprotected

Definition at line 175 of file G4VLongitudinalStringDecay.hh.

{return ClusterLoopInterrupt;};

GetDiquarkBreakProb()

G4double G4VLongitudinalStringDecay::GetDiquarkBreakProb ( )

inlineprotected

Definition at line 173 of file G4VLongitudinalStringDecay.hh.

{return DiquarkBreakProb;};

GetDiquarkSuppress()

G4double G4VLongitudinalStringDecay::GetDiquarkSuppress ( )

inlineprotected

Definition at line 172 of file G4VLongitudinalStringDecay.hh.

{return DiquarkSuppress;};

GetLightConeZ()

virtual G4double G4VLongitudinalStringDecay::GetLightConeZ ( G4double zmin, G4double zmax, G4int PartonEncoding, G4ParticleDefinition * pHadron, G4double Px, G4double Py )

protectedpure virtual

GetMassCut()

G4double G4VLongitudinalStringDecay::GetMassCut ( )

protected

Definition at line 142 of file G4VLongitudinalStringDecay.cc.

{ return MassCut; }

Referenced by G4LundStringFragmentation::FragmentString().

GetProbBBbar()

G4double G4VLongitudinalStringDecay::GetProbBBbar ( )

inlineprotected

Definition at line 179 of file G4VLongitudinalStringDecay.hh.

{return ProbBBbar;};

GetProbCCbar()

G4double G4VLongitudinalStringDecay::GetProbCCbar ( )

inlineprotected

Definition at line 177 of file G4VLongitudinalStringDecay.hh.

{return ProbCCbar;};

GetProbEta_b()

G4double G4VLongitudinalStringDecay::GetProbEta_b ( )

inlineprotected

Definition at line 180 of file G4VLongitudinalStringDecay.hh.

{return ProbEta_b;};

GetProbEta_c()

G4double G4VLongitudinalStringDecay::GetProbEta_c ( )

inlineprotected

Definition at line 178 of file G4VLongitudinalStringDecay.hh.

{return ProbEta_c;};

GetStrangeSuppress()

G4double G4VLongitudinalStringDecay::GetStrangeSuppress ( )

inlineprotected

Definition at line 174 of file G4VLongitudinalStringDecay.hh.

{return StrangeSuppress;};

GetStringTensionParameter()

G4double G4VLongitudinalStringDecay::GetStringTensionParameter ( )

inlineprotected

Definition at line 182 of file G4VLongitudinalStringDecay.hh.

{return Kappa;};

Referenced by CalculateHadronTimePosition().

IsItFragmentable()

virtual G4bool G4VLongitudinalStringDecay::IsItFragmentable ( const G4FragmentingString *const string )

protectedpure virtual

PossibleHadronMass()

G4double G4VLongitudinalStringDecay::PossibleHadronMass ( const G4FragmentingString *const string, Pcreate build = 0, pDefPair * pdefs = 0 )

protected

Definition at line 204 of file G4VLongitudinalStringDecay.cc.

{
        G4double mass = 0.0;
 
    if ( build==0 ) build=&G4HadronBuilder::BuildLowSpin;
 
        G4ParticleDefinition* Hadron1 = nullptr;
    G4ParticleDefinition* Hadron2 = nullptr;
 
        if (!string->IsAFourQuarkString() )
        {
           // spin 0 meson or spin 1/2 barion will be built
 
           Hadron1 = (hadronizer->*build)(string->GetLeftParton(), string->GetRightParton());
           #ifdef debug_VStringDecay
       G4cout<<"VlongSD PossibleHadronMass"<<G4endl;
           G4cout<<"VlongSD Quarks at the string ends "<<string->GetLeftParton()->GetParticleName()
                 <<" "<<string->GetRightParton()->GetParticleName()<<G4endl;
           if ( Hadron1 != nullptr) {
             G4cout<<"(G4VLongitudinalStringDecay) Hadron "<<Hadron1->GetParticleName()
                   <<" "<<Hadron1->GetPDGMass()<<G4endl;
           }
           #endif
           if ( Hadron1 != nullptr) { mass = (Hadron1)->GetPDGMass();}
           else                  { mass = MaxMass;}
        } else
        {
           //... string is qq--qqbar: Build two stable hadrons,
 
           #ifdef debug_VStringDecay
           G4cout<<"VlongSD PossibleHadronMass"<<G4endl;
           G4cout<<"VlongSD string is qq--qqbar: Build two stable hadrons"<<G4endl; 
           #endif
 
           G4double StringMass   = string->Mass();
           G4int cClusterInterrupt = 0;
           do
           {
             if (cClusterInterrupt++ >= ClusterLoopInterrupt) return false;
 
             G4int LeftQuark1= string->GetLeftParton()->GetPDGEncoding()/1000;
             G4int LeftQuark2=(string->GetLeftParton()->GetPDGEncoding()/100)%10;
 
             G4int RightQuark1= string->GetRightParton()->GetPDGEncoding()/1000;
             G4int RightQuark2=(string->GetRightParton()->GetPDGEncoding()/100)%10;
 
             if (G4UniformRand()<0.5) {
               Hadron1 =hadronizer->Build(FindParticle(LeftQuark1), FindParticle(RightQuark1));
               Hadron2 =hadronizer->Build(FindParticle(LeftQuark2), FindParticle(RightQuark2));
             } else {
               Hadron1 =hadronizer->Build(FindParticle(LeftQuark1), FindParticle(RightQuark2));
               Hadron2 =hadronizer->Build(FindParticle(LeftQuark2), FindParticle(RightQuark1));
             }
             //... repeat procedure, if mass of cluster is too low to produce hadrons
             //... ClusterMassCut = 0.15*GeV model parameter
           }
           while ( Hadron1 == nullptr || Hadron2 == nullptr ||
                   ( StringMass <= Hadron1->GetPDGMass() + Hadron2->GetPDGMass() ) );
 
       mass = (Hadron1)->GetPDGMass() + (Hadron2)->GetPDGMass();
        }
 
        #ifdef debug_VStringDecay
        G4cout<<"VlongSD *Hadrons 1 and 2, proposed mass "<<Hadron1<<" "<<Hadron2<<" "<<mass<<G4endl; 
        #endif
    
    if ( pdefs != 0 ) 
    { // need to return hadrons as well....
       pdefs->first  = Hadron1;
       pdefs->second = Hadron2;
    }
       
        return mass;
}

Referenced by ProduceOneHadron().

ProduceOneHadron()

G4KineticTrackVector * G4VLongitudinalStringDecay::ProduceOneHadron ( const G4ExcitedString *const theString )

protected

Definition at line 148 of file G4VLongitudinalStringDecay.cc.

{
        G4KineticTrackVector* result = nullptr; 
        pDefPair hadrons( nullptr, nullptr );
        G4FragmentingString aString( *string );
 
        #ifdef debug_VStringDecay
        G4cout<<"G4VLongitudinalStringDecay::ProduceOneHadron: PossibleHmass StrMass "
              <<aString.Mass()<<" MassCut "<<MassCut<<G4endl;
        #endif
        
        SetMinimalStringMass( &aString );
        PossibleHadronMass( &aString, 0, &hadrons );
        result = new G4KineticTrackVector;
        if ( hadrons.first != nullptr ) {       
           if ( hadrons.second == nullptr ) {
               // Substitute string by light hadron, Note that Energy is not conserved here!
 
               #ifdef debug_VStringDecay
               G4cout << "VlongSD Warning replacing string by single hadron (G4VLongitudinalStringDecay)" <<G4endl;
               G4cout << hadrons.first->GetParticleName()<<G4endl
                      << "string .. " << string->Get4Momentum() << " " 
                      << string->Get4Momentum().m() << G4endl;
               #endif           
 
               G4ThreeVector   Mom3 = string->Get4Momentum().vect();
               G4LorentzVector Mom( Mom3, std::sqrt( Mom3.mag2() + sqr( hadrons.first->GetPDGMass() ) ) );
               result->push_back( new G4KineticTrack( hadrons.first, 0, string->GetPosition(), Mom ) );
           } else {
               //... string was qq--qqbar type: Build two stable hadrons,
 
               #ifdef debug_VStringDecay
               G4cout << "VlongSD Warning replacing qq-qqbar string by TWO hadrons (G4VLongitudinalStringDecay)" 
                      << hadrons.first->GetParticleName() << " / " 
                      << hadrons.second->GetParticleName()
                      << "string .. " << string->Get4Momentum() << " " 
                      << string->Get4Momentum().m() << G4endl;
               #endif
 
               G4LorentzVector  Mom1, Mom2;
               Sample4Momentum( &Mom1, hadrons.first->GetPDGMass(), 
                                &Mom2, hadrons.second->GetPDGMass(),
                                string->Get4Momentum().mag() );
 
               result->push_back( new G4KineticTrack( hadrons.first,  0, string->GetPosition(), Mom1 ) );
               result->push_back( new G4KineticTrack( hadrons.second, 0, string->GetPosition(), Mom2 ) );
 
               G4ThreeVector Velocity = string->Get4Momentum().boostVector();
               result->Boost(Velocity);          
           }
        }
        return result;
}

Referenced by G4LundStringFragmentation::FragmentString(), and G4QGSMFragmentation::FragmentString().

QuarkSplitup()

G4ParticleDefinition * G4VLongitudinalStringDecay::QuarkSplitup ( G4ParticleDefinition * decay, G4ParticleDefinition *& created )

protectedvirtual

Definition at line 337 of file G4VLongitudinalStringDecay.cc.

{
   #ifdef debug_VStringDecay
   G4cout<<"VlongSD QuarkSplitup: quark ID "<<decay->GetPDGEncoding()<<G4endl; 
   #endif
   
   G4int IsParticle=(decay->GetPDGEncoding()>0) ? -1 : +1;  // if we have a quark, we need antiquark (or diquark)
 
   pDefPair QuarkPair = CreatePartonPair(IsParticle);
   created = QuarkPair.second;
 
   DecayQuark = decay->GetPDGEncoding();
   NewQuark   = created->GetPDGEncoding();
 
   #ifdef debug_VStringDecay
   G4cout<<"VlongSD QuarkSplitup: "<<decay->GetPDGEncoding()<<" -> "<<QuarkPair.second->GetPDGEncoding()<<G4endl;
   G4cout<<"hadronizer->Build(QuarkPair.first, decay)"<<G4endl;
   #endif
   
   return hadronizer->Build(QuarkPair.first, decay);
}

Sample4Momentum()

virtual void G4VLongitudinalStringDecay::Sample4Momentum ( G4LorentzVector * Mom, G4double Mass, G4LorentzVector * AntiMom, G4double AntiMass, G4double InitialMass )

protectedpure virtual

Referenced by ProduceOneHadron().

SampleQuarkFlavor()

G4int G4VLongitudinalStringDecay::SampleQuarkFlavor

(

void

)

Definition at line 395 of file G4VLongitudinalStringDecay.cc.

{
   G4int  quark(1);
   G4double ksi = G4UniformRand();
   if ( ksi < ProbCB ) {
      if ( ksi < ProbCCbar ) {quark = 4;}   // c quark
      else                   {quark = 5;}   // b quark
      #ifdef debug_heavyHadrons
      G4cout << "G4VLongitudinalStringDecay::SampleQuarkFlavor : sampled from the vacuum HEAVY quark = "
         << quark << G4endl;
      #endif
   } else {
     quark = 1 + (int)(G4UniformRand()/StrangeSuppress);
   }
   #ifdef debug_VStringDecay
   G4cout<<"VlongSD SampleQuarkFlavor "<<quark<<" (ProbCB ProbCCbar ProbBBbar "<<ProbCB
         <<" "<<ProbCCbar<<" "<<ProbBBbar<<" )"<<G4endl; 
   #endif
   return quark;
}

Referenced by CreatePartonPair().

SampleQuarkPt()

G4ThreeVector G4VLongitudinalStringDecay::SampleQuarkPt

(

G4double

ptMax = -1.

)

Definition at line 418 of file G4VLongitudinalStringDecay.cc.

{
   G4double Pt;
   if ( ptMax < 0 ) {
      // sample full gaussian
      Pt = -G4Log(G4UniformRand());
   } else {
      // sample in limited range
      G4double q = ptMax/SigmaQT;
      G4double ymin = (q > 20.) ? 0.0 : G4Exp(-q*q); 
      Pt = -G4Log(G4RandFlat::shoot(ymin, 1.));
   }
   Pt = SigmaQT * std::sqrt(Pt);
   G4double phi = 2.*pi*G4UniformRand();
   return G4ThreeVector(Pt * std::cos(phi),Pt * std::sin(phi),0);
}

SetDiquarkBreakProbability()

void G4VLongitudinalStringDecay::SetDiquarkBreakProbability

(

G4double

aValue

)

Definition at line 490 of file G4VLongitudinalStringDecay.cc.

{
  if ( PastInitPhase ) {
    throw G4HadronicException(__FILE__, __LINE__, 
      "G4VLongitudinalStringDecay::SetDiquarkBreakProbability after FragmentString() not allowed");
  } else {
    DiquarkBreakProb = aValue;
  }
}

Referenced by G4LundStringFragmentation::G4LundStringFragmentation(), and G4QGSMFragmentation::G4QGSMFragmentation().

SetDiquarkSuppression()

void G4VLongitudinalStringDecay::SetDiquarkSuppression

(

G4double

aValue

)

Definition at line 483 of file G4VLongitudinalStringDecay.cc.

{
   DiquarkSuppress = aValue;
}

Referenced by G4LundStringFragmentation::G4LundStringFragmentation(), and G4QGSMFragmentation::G4QGSMFragmentation().

SetMassCut()

void G4VLongitudinalStringDecay::SetMassCut ( G4double aValue )

protectedvirtual

Definition at line 141 of file G4VLongitudinalStringDecay.cc.

{ MassCut=aValue; }

Referenced by G4LundStringFragmentation::FragmentString(), and G4LundStringFragmentation::G4LundStringFragmentation().

SetMinimalStringMass()

void G4VLongitudinalStringDecay::SetMinimalStringMass

(

const G4FragmentingString *const

string

)

Definition at line 946 of file G4VLongitudinalStringDecay.cc.

{
        //MaxMass = -350.0*GeV;
    G4double EstimatedMass=MaxMass;
 
        G4ParticleDefinition* LeftParton  = string->GetLeftParton();
        G4ParticleDefinition* RightParton = string->GetRightParton();
        if( LeftParton->GetParticleSubType() == RightParton->GetParticleSubType() ) { // q qbar, qq qqbar
          if( LeftParton->GetPDGEncoding() * RightParton->GetPDGEncoding() > 0 ) {
            // Not allowed combination of the partons
            throw G4HadronicException(__FILE__, __LINE__,
                      "G4VLongitudinalStringDecay::SetMinimalStringMass: Illegal quark content as input");
          }
        }
        if( LeftParton->GetParticleSubType() != RightParton->GetParticleSubType() ) { // q qq, qbar qqbar
          if( LeftParton->GetPDGEncoding() * RightParton->GetPDGEncoding() < 0 ) {
            // Not allowed combination of the partons
            throw G4HadronicException(__FILE__, __LINE__,
                      "G4VLongitudinalStringDecay::SetMinimalStringMass: Illegal quark content as input");
          }
        }
    
        G4int Qleft =std::abs(string->GetLeftParton()->GetPDGEncoding());
        G4int Qright=std::abs(string->GetRightParton()->GetPDGEncoding());
 
        if ((Qleft < 6) && (Qright < 6)) {   // Q-Qbar string
          EstimatedMass=minMassQQbarStr[Qleft-1][Qright-1];
          MinimalStringMass=EstimatedMass;
          SetMinimalStringMass2(EstimatedMass);
          return;
        }
 
        if ((Qleft < 6) && (Qright > 1000)) {   // Q - DiQ string
          G4int q1=Qright/1000;
          G4int q2=(Qright/100)%10;
          EstimatedMass=minMassQDiQStr[Qleft-1][q1-1][q2-1];
          MinimalStringMass=EstimatedMass;                    // It can be negative!
          SetMinimalStringMass2(EstimatedMass);
          return;
        }
 
        if ((Qleft > 1000) && (Qright < 6)) {   // DiQ - Q string   6 6 6
          G4int q1=Qleft/1000;
          G4int q2=(Qleft/100)%10;
          EstimatedMass=minMassQDiQStr[Qright-1][q1-1][q2-1];
          MinimalStringMass=EstimatedMass;                    // It can be negative!
          SetMinimalStringMass2(EstimatedMass);
          return;
        }
 
        // DiQuark - Anti DiQuark string -----------------
 
    G4double StringM=string->Get4Momentum().mag();
 
        #ifdef debug_LUNDfragmentation
        // G4cout<<"MinStringMass// Input String mass "<<string->Get4Momentum().mag()<<" Qleft "<<Qleft<<G4endl;
        #endif
 
        G4int q1= Qleft/1000    ;
        G4int q2=(Qleft/100)%10 ;
 
        G4int q3= Qright/1000   ;
        G4int q4=(Qright/100)%10;
 
        // -------------- 2 baryon production or 2 mesons production --------
 
        G4double EstimatedMass1 = minMassQDiQStr[q1-1][q2-1][0];
        G4double EstimatedMass2 = minMassQDiQStr[q3-1][q4-1][0];
        // Mass is negative if there is no corresponding particle.
 
        if ( (EstimatedMass1 > 0.) && (EstimatedMass2 > 0.)) {
           EstimatedMass = EstimatedMass1 + EstimatedMass2;
           if ( StringM > EstimatedMass ) {                     // 2 baryon production is possible.
              MinimalStringMass=EstimatedMass1 + EstimatedMass2;
              SetMinimalStringMass2(EstimatedMass);
              return;
          }
        }
 
        if ( (EstimatedMass1 < 0.) && (EstimatedMass2 > 0.)) {
           EstimatedMass = MaxMass;
           MinimalStringMass=EstimatedMass;
           SetMinimalStringMass2(EstimatedMass);
           return;
        }
 
        if ( (EstimatedMass1 > 0.) && (EstimatedMass2 < 0.)) {
           EstimatedMass = EstimatedMass1;
           MinimalStringMass=EstimatedMass;
           SetMinimalStringMass2(EstimatedMass);
           return;
        }
 
        //      if ( EstimatedMass >= StringM ) {
        // ------------- Re-orangement ---------------
        EstimatedMass=std::min(minMassQQbarStr[q1-1][q3-1] + minMassQQbarStr[q2-1][q4-1],
                               minMassQQbarStr[q1-1][q4-1] + minMassQQbarStr[q2-1][q3-1]);
 
        // In principle, re-arrangement and 2 baryon production can compete.
        // More physics consideration is needed.
 
        MinimalStringMass=EstimatedMass;
        SetMinimalStringMass2(EstimatedMass);
 
        return;
}

Referenced by G4LundStringFragmentation::FragmentString(), G4QGSMFragmentation::FragmentString(), and ProduceOneHadron().

SetMinimalStringMass2()

void G4VLongitudinalStringDecay::SetMinimalStringMass2

(

const G4double

aValue

)

Definition at line 1055 of file G4VLongitudinalStringDecay.cc.

{
    MinimalStringMass2=aValue * aValue;
}

Referenced by SetMinimalStringMass().

SetMinMasses()

void G4VLongitudinalStringDecay::SetMinMasses

(

)

Definition at line 600 of file G4VLongitudinalStringDecay.cc.

{
    // ------ For estimation of a minimal string mass ---------------
    Mass_of_light_quark =140.*MeV;
    Mass_of_s_quark     =500.*MeV;
    Mass_of_c_quark     =1600.*MeV;
    Mass_of_b_quark     =4500.*MeV;
    Mass_of_string_junction=720.*MeV;
 
    // ---------------- Determination of minimal mass of q-qbar strings -------------------
    G4ParticleDefinition * hadron1;    G4int Code1;
    G4ParticleDefinition * hadron2;    G4int Code2;
    for (G4int i=1; i < 6; i++) {
        Code1 = 100*i + 10*1 + 1;
        hadron1 = FindParticle(Code1);
 
        if (hadron1 != nullptr) {
           for (G4int j=1; j < 6; j++) {
               Code2 = 100*j + 10*1 + 1;
               hadron2 = FindParticle(Code2);
               if (hadron2 != nullptr) {
                 minMassQQbarStr[i-1][j-1] = hadron1->GetPDGMass() + hadron2->GetPDGMass() + 70.0 * MeV;
               }
           } 
        }
    }
 
    minMassQQbarStr[1][1] = minMassQQbarStr[0][0];   // u-ubar = 0.5 Pi0 + 0.24 Eta + 0.25 Eta'
 
    // ---------------- Determination of minimal mass of qq-q strings -------------------
    G4ParticleDefinition * hadron3;
    G4int kfla, kflb;
    //  MaxMass = -350.0*GeV;   // If there will be a particle with mass larger than Higgs the value must be changed.
 
    for (G4int i=1; i < 6; i++) {   //i=1
        Code1 = 100*i + 10*1 + 1;
        hadron1 = FindParticle(Code1);
        for (G4int j=1; j < 6; j++) {
            for (G4int k=1; k < 6; k++) {
                kfla = std::max(j,k);
                kflb = std::min(j,k);
 
        // Add d-quark
                Code2 = 1000*kfla + 100*kflb + 10*1 + 2;
        if ( (j == 1) && (k==1)) Code2 = 1000*2 + 100*1 + 10*1 + 2; // In the case - add u-quark.
 
                hadron2 = G4ParticleTable::GetParticleTable()->FindParticle(Code2);
                hadron3 = G4ParticleTable::GetParticleTable()->FindParticle(Code2 + 2);
 
                if ((hadron2 == nullptr) && (hadron3 == nullptr)) {minMassQDiQStr[i-1][j-1][k-1] = MaxMass; continue;};
 
                if ((hadron2 != nullptr) && (hadron3 != nullptr)) {
                   if (hadron2->GetPDGMass() > hadron3->GetPDGMass() ) { hadron2 = hadron3; }
                };
 
                if ((hadron2 != nullptr) && (hadron3 == nullptr)) {};
 
                if ((hadron2 == nullptr) && (hadron3 != nullptr)) {hadron2 = hadron3;};
 
                minMassQDiQStr[i-1][j-1][k-1] = hadron1->GetPDGMass() + hadron2->GetPDGMass() + 70.0 * MeV;
            }
        }
    }
 
    // ------ An estimated minimal string mass ----------------------
    MinimalStringMass  = 0.;
    MinimalStringMass2 = 0.;
    // q charges  d               u                s               c                b
    Qcharge[0] = -1; Qcharge[1] = 2; Qcharge[2] = -1; Qcharge[3] = 2; Qcharge[4] = -1;
 
    // For treating of small string decays
    for (G4int i=0; i<5; i++)
    {  for (G4int j=0; j<5; j++)
       {  for (G4int k=0; k<7; k++)
          {
            Meson[i][j][k]=0; MesonWeight[i][j][k]=0.;
          }
       }
    }
    //--------------------------
    G4int StrangeQ = 0;
    G4int StrangeAQ = 0;
    for (G4int i=0; i<5; i++)
    {
       if( i >= 2 ) StrangeQ=1;
       for (G4int j=0; j<5; j++)
       { 
         StrangeAQ = 0;
         if( j >= 2 ) StrangeAQ=1;
         Meson[i][j][0]       = 100 * (std::max(i,j)+1) + 10 * (std::min(i,j)+1) + 1; // Scalar meson
         MesonWeight[i][j][0] = (   pspin_meson[StrangeQ + StrangeAQ]);
         Meson[i][j][1]       = 100 * (std::max(i,j)+1) + 10 * (std::min(i,j)+1) + 3; // Vector meson
         MesonWeight[i][j][1] = (1.-pspin_meson[StrangeQ + StrangeAQ]);
       }
    }
 
    //qqs                                                                                                         indexes
    //dd1 -> scalarMesonMix[0] * 111 + (1-scalarMesonMix[0]-scalarMesonMix[1]) * 221 + scalarMesonMix[1] * 331     (000)
    //dd1 ->                     Pi0                                             Eta                       Eta'
 
    Meson[0][0][0] = 111; MesonWeight[0][0][0] = (   pspin_meson[0]) * (  scalarMesonMix[0]                  );  // Pi0
    Meson[0][0][2] = 221; MesonWeight[0][0][3] = (   pspin_meson[0]) * (1-scalarMesonMix[0]-scalarMesonMix[1]);  // Eta
    Meson[0][0][3] = 331; MesonWeight[0][0][4] = (   pspin_meson[0]) * (                    scalarMesonMix[1]);  // Eta'
 
    //dd3 -> (1-vectorMesonMix[1] * 113 + vectorMesonMix[1] * 223                                                  (001)
    //dd3 ->                       rho_0                     omega
 
    Meson[0][0][1] = 113; MesonWeight[0][0][1] = (1.-pspin_meson[0]) * (1-vectorMesonMix[1]);                    // Rho
    Meson[0][0][4] = 223; MesonWeight[0][0][4] = (1.-pspin_meson[0]) * (  vectorMesonMix[1]);                    // omega
 
    //uu1 -> scalarMesonMix[0] * 111 + (1-scalarMesonMix[0]-scalarMesonMix[1]) * 221 + scalarMesonMix[1] * 331     (110)
    //uu1 ->                     Pi0                                             Eta                       Eta'
 
    Meson[1][1][0] = 111; MesonWeight[1][1][0] = (   pspin_meson[0]) * (  scalarMesonMix[0]                  );  // Pi0
    Meson[1][1][2] = 221; MesonWeight[1][1][2] = (   pspin_meson[0]) * (1-scalarMesonMix[0]-scalarMesonMix[1]);  // Eta
    Meson[1][1][3] = 331; MesonWeight[1][1][3] = (   pspin_meson[0]) * (                    scalarMesonMix[1]);  // Eta'
 
    //uu3 -> (1-vectorMesonMix[1]) * 113 + vectorMesonMix[1] * 223                                                 (111)
    //uu3 ->                        rho_0                     omega
 
    Meson[1][1][1] = 113; MesonWeight[1][1][1] = (1.-pspin_meson[0]) * (1-vectorMesonMix[1]);                    // Rho
    Meson[1][1][4] = 223; MesonWeight[1][1][4] = (1.-pspin_meson[0]) * (  vectorMesonMix[1]);                    // omega
 
    //ss1     ->                                             (1-scalarMesonMix[5]) * 221 + scalarMesonMix[5] * 331   (220)
    //ss1     ->                                                                     Eta                       Eta'
 
    Meson[2][2][0] = 221; MesonWeight[2][2][0] = (   pspin_meson[2]) * (1-scalarMesonMix[5]                  );  // Eta
    Meson[2][2][2] = 331; MesonWeight[2][2][2] = (   pspin_meson[2]) * (                    scalarMesonMix[5]);  // Eta'
 
    //ss3     ->                                                                           vectorMesonMix[5] * 333   (221)
    //ss3     ->                                                                                               phi
 
    Meson[2][2][1] = 333; MesonWeight[2][2][1] = (1.-pspin_meson[2]) * (                 vectorMesonMix[5]);  // phi
 
    //cc1     ->    ProbEta_c /(1-pspin_meson) 441  (330) Probability of Eta_c
    //cc3     -> (1-ProbEta_c)/(  pspin_meson) 443  (331) Probability of J/Psi
 
    //bb1     ->    ProbEta_b /pspin_meson 551  (440) Probability of Eta_b
    //bb3     -> (1-ProbEta_b)/pspin_meson 553  (441) Probability of Upsilon
 
    if ( pspin_meson[2] != 0. ) {
       Meson[3][3][0] *= (    ProbEta_c)/(   pspin_meson[2]);   // Eta_c
       Meson[3][3][1] *= (1.0-ProbEta_c)/(1.-pspin_meson[2]);   // J/Psi
 
       Meson[4][4][0] *= (    ProbEta_b)/(   pspin_meson[2]);   // Eta_b
       Meson[4][4][1] *= (1.0-ProbEta_b)/(1.-pspin_meson[2]);   // Upsilon
    }
 
    //--------------------------
 
    for (G4int i=0; i<5; i++)
    {  for (G4int j=0; j<5; j++)
       {  for (G4int k=0; k<5; k++)
          {  for (G4int l=0; l<4; l++)
             { Baryon[i][j][k][l]=0; BaryonWeight[i][j][k][l]=0.;}
          }
       }
    }
 
          kfla =0;  kflb =0;
    G4int                   kflc(0), kfld(0), kfle(0), kflf(0);
    for (G4int i=0; i<5; i++)
    {  for (G4int j=0; j<5; j++)
       {  for (G4int k=0; k<5; k++)
          {  
           kfla = i+1; kflb = j+1; kflc = k+1;
       kfld = std::max(kfla,kflb);
       kfld = std::max(kfld,kflc);
 
       kflf = std::min(kfla,kflb);
       kflf = std::min(kflf,kflc);
 
           kfle = kfla + kflb + kflc - kfld - kflf;
 
           Baryon[i][j][k][0]       = 1000 * kfld + 100 * kfle + 10 * kflf + 2; // spin=1/2
           BaryonWeight[i][j][k][0] = (   pspin_barion);
           Baryon[i][j][k][1]       = 1000 * kfld + 100 * kfle + 10 * kflf + 4; // spin=3/2
           BaryonWeight[i][j][k][1] = (1.-pspin_barion);
          }
       }
    }
 
    // Delta-  ddd - only 1114
    Baryon[0][0][0][0] = 1114;    BaryonWeight[0][0][0][0] = 1.0; 
    Baryon[0][0][0][1] =    0;    BaryonWeight[0][0][0][1] = 0.0; 
 
    // Delta++ uuu - only 2224
    Baryon[1][1][1][0] = 2224;    BaryonWeight[1][1][1][0] = 1.0; 
    Baryon[1][1][1][1] =    0;    BaryonWeight[1][1][1][1] = 0.0; 
 
    // Omega- sss - only 3334
    Baryon[2][2][2][0] = 3334;    BaryonWeight[2][2][2][0] = 1.0; 
    Baryon[2][2][2][1] =    0;    BaryonWeight[2][2][2][1] = 0.0; 
 
    // Omega_cc++ ccc - only 4444
    Baryon[3][3][3][0] = 4444;    BaryonWeight[3][3][3][0] = 1.0; 
    Baryon[3][3][3][1] =    0;    BaryonWeight[3][3][3][1] = 0.0; 
 
    // Omega_bb-  bbb - only 5554
    Baryon[4][4][4][0] = 5554;    BaryonWeight[4][4][4][0] = 1.0; 
    Baryon[4][4][4][1] =    0;    BaryonWeight[4][4][4][1] = 0.0; 
 
    // Lambda/Sigma0 sud - 3122/3212
    Baryon[0][1][2][0] = 3122;    BaryonWeight[0][1][2][0] *= 0.5;                  // Lambda
    Baryon[0][2][1][0] = 3122;    BaryonWeight[0][2][1][0] *= 0.5;
    Baryon[1][0][2][0] = 3122;    BaryonWeight[1][0][2][0] *= 0.5;
    Baryon[1][2][0][0] = 3122;    BaryonWeight[1][2][0][0] *= 0.5;
    Baryon[2][0][1][0] = 3122;    BaryonWeight[2][0][1][0] *= 0.5;
    Baryon[2][1][0][0] = 3122;    BaryonWeight[2][1][0][0] *= 0.5;
 
    Baryon[0][1][2][2] = 3212;    BaryonWeight[0][1][2][2]  = 0.5 * pspin_barion;   // Sigma0
    Baryon[0][2][1][2] = 3212;    BaryonWeight[0][2][1][2]  = 0.5 * pspin_barion;
    Baryon[1][0][2][2] = 3212;    BaryonWeight[1][0][2][2]  = 0.5 * pspin_barion;
    Baryon[1][2][0][2] = 3212;    BaryonWeight[1][2][0][2]  = 0.5 * pspin_barion;
    Baryon[2][0][1][2] = 3212;    BaryonWeight[2][0][1][2]  = 0.5 * pspin_barion;
    Baryon[2][1][0][2] = 3212;    BaryonWeight[2][1][0][2]  = 0.5 * pspin_barion;
 
    // Lambda_c+/Sigma_c+ cud - 4122/4212
    Baryon[0][1][3][0] = 4122;    BaryonWeight[0][1][3][0] *= 0.5;                  // Lambda_c+
    Baryon[0][3][1][0] = 4122;    BaryonWeight[0][3][1][0] *= 0.5;
    Baryon[1][0][3][0] = 4122;    BaryonWeight[1][0][3][0] *= 0.5;
    Baryon[1][3][0][0] = 4122;    BaryonWeight[1][3][0][0] *= 0.5;
    Baryon[3][0][1][0] = 4122;    BaryonWeight[3][0][1][0] *= 0.5;
    Baryon[3][1][0][0] = 4122;    BaryonWeight[3][1][0][0] *= 0.5;
 
    Baryon[0][1][3][2] = 4212;    BaryonWeight[0][1][3][2]  = 0.5 * pspin_barion;   // SigmaC+
    Baryon[0][3][1][2] = 4212;    BaryonWeight[0][3][1][2]  = 0.5 * pspin_barion;
    Baryon[1][0][3][2] = 4212;    BaryonWeight[1][0][3][2]  = 0.5 * pspin_barion;
    Baryon[1][3][0][2] = 4212;    BaryonWeight[1][3][0][2]  = 0.5 * pspin_barion;
    Baryon[3][0][1][2] = 4212;    BaryonWeight[3][0][1][2]  = 0.5 * pspin_barion;
    Baryon[3][1][0][2] = 4212;    BaryonWeight[3][1][0][2]  = 0.5 * pspin_barion;
 
    // Xi_c+/Xi_c+' cus - 4232/4322
    Baryon[1][2][3][0] = 4232;    BaryonWeight[1][2][3][0] *= 0.5;                  // Xi_c+
    Baryon[1][3][2][0] = 4232;    BaryonWeight[1][3][2][0] *= 0.5;
    Baryon[2][1][3][0] = 4232;    BaryonWeight[2][1][3][0] *= 0.5;
    Baryon[2][3][1][0] = 4232;    BaryonWeight[2][3][1][0] *= 0.5;
    Baryon[3][1][2][0] = 4232;    BaryonWeight[3][1][2][0] *= 0.5;
    Baryon[3][2][1][0] = 4232;    BaryonWeight[3][2][1][0] *= 0.5;
 
    Baryon[1][2][3][2] = 4322;    BaryonWeight[1][2][3][2]  = 0.5 * pspin_barion;   // Xi_c+'
    Baryon[1][3][2][2] = 4322;    BaryonWeight[1][3][2][2]  = 0.5 * pspin_barion;
    Baryon[2][1][3][2] = 4322;    BaryonWeight[2][1][3][2]  = 0.5 * pspin_barion;
    Baryon[2][3][1][2] = 4322;    BaryonWeight[2][3][1][2]  = 0.5 * pspin_barion;
    Baryon[3][1][2][2] = 4322;    BaryonWeight[3][1][2][2]  = 0.5 * pspin_barion;
    Baryon[3][2][1][2] = 4322;    BaryonWeight[3][2][1][2]  = 0.5 * pspin_barion;
 
    // Xi_c0/Xi_c0' cus - 4132/4312
    Baryon[0][2][3][0] = 4132;    BaryonWeight[0][2][3][0] *= 0.5;                  // Xi_c0
    Baryon[0][3][2][0] = 4132;    BaryonWeight[0][3][2][0] *= 0.5;
    Baryon[2][0][3][0] = 4132;    BaryonWeight[2][0][3][0] *= 0.5;
    Baryon[2][3][0][0] = 4132;    BaryonWeight[2][3][0][0] *= 0.5;
    Baryon[3][0][2][0] = 4132;    BaryonWeight[3][0][2][0] *= 0.5;
    Baryon[3][2][0][0] = 4132;    BaryonWeight[3][2][0][0] *= 0.5;
 
    Baryon[0][2][3][2] = 4312;    BaryonWeight[0][2][3][2]  = 0.5 * pspin_barion;   // Xi_c0'
    Baryon[0][3][2][2] = 4312;    BaryonWeight[0][3][2][2]  = 0.5 * pspin_barion;
    Baryon[2][0][3][2] = 4312;    BaryonWeight[2][0][3][2]  = 0.5 * pspin_barion;
    Baryon[2][3][0][2] = 4312;    BaryonWeight[2][3][0][2]  = 0.5 * pspin_barion;
    Baryon[3][0][2][2] = 4312;    BaryonWeight[3][0][2][2]  = 0.5 * pspin_barion;
    Baryon[3][2][0][2] = 4312;    BaryonWeight[3][2][0][2]  = 0.5 * pspin_barion;
 
    // Lambda_b0/Sigma_b0 bud - 5122/5212
    Baryon[0][1][4][0] = 5122;    BaryonWeight[0][1][4][0] *= 0.5;                  // Lambda_b0
    Baryon[0][4][1][0] = 5122;    BaryonWeight[0][4][1][0] *= 0.5;
    Baryon[1][0][4][0] = 5122;    BaryonWeight[1][0][4][0] *= 0.5;
    Baryon[1][4][0][0] = 5122;    BaryonWeight[1][4][0][0] *= 0.5;
    Baryon[4][0][1][0] = 5122;    BaryonWeight[4][0][1][0] *= 0.5;
    Baryon[4][1][0][0] = 5122;    BaryonWeight[4][1][0][0] *= 0.5;
 
    Baryon[0][1][4][2] = 5212;    BaryonWeight[0][1][4][2]  = 0.5 * pspin_barion;   // Sigma_b0
    Baryon[0][4][1][2] = 5212;    BaryonWeight[0][4][1][2]  = 0.5 * pspin_barion;
    Baryon[1][0][4][2] = 5212;    BaryonWeight[1][0][4][2]  = 0.5 * pspin_barion;
    Baryon[1][4][0][2] = 5212;    BaryonWeight[1][4][0][2]  = 0.5 * pspin_barion;
    Baryon[4][0][1][2] = 5212;    BaryonWeight[4][0][1][2]  = 0.5 * pspin_barion;
    Baryon[4][1][0][2] = 5212;    BaryonWeight[4][1][0][2]  = 0.5 * pspin_barion;
 
    // Xi_b0/Xi_b0' bus - 5232/5322
    Baryon[1][2][4][0] = 5232;    BaryonWeight[1][2][4][0] *= 0.5;                  // Xi_b0
    Baryon[1][4][2][0] = 5232;    BaryonWeight[1][4][2][0] *= 0.5;
    Baryon[2][1][4][0] = 5232;    BaryonWeight[2][1][4][0] *= 0.5;
    Baryon[2][4][1][0] = 5232;    BaryonWeight[2][4][1][0] *= 0.5;
    Baryon[4][1][2][0] = 5232;    BaryonWeight[4][1][2][0] *= 0.5;
    Baryon[4][2][1][0] = 5232;    BaryonWeight[4][2][1][0] *= 0.5;
 
    Baryon[1][2][4][2] = 5322;    BaryonWeight[1][2][4][2]  = 0.5 * pspin_barion;   // Xi_b0'
    Baryon[1][4][2][2] = 5322;    BaryonWeight[1][4][2][2]  = 0.5 * pspin_barion;
    Baryon[2][1][4][2] = 5322;    BaryonWeight[2][1][4][2]  = 0.5 * pspin_barion;
    Baryon[2][4][1][2] = 5322;    BaryonWeight[2][4][1][2]  = 0.5 * pspin_barion;
    Baryon[4][1][2][2] = 5322;    BaryonWeight[4][1][2][2]  = 0.5 * pspin_barion;
    Baryon[4][2][1][2] = 5322;    BaryonWeight[4][2][1][2]  = 0.5 * pspin_barion;
 
    // Xi_b-/Xi_b-' bus - 5132/5312
    Baryon[0][2][4][0] = 5132;    BaryonWeight[0][2][4][0] *= 0.5;                  // Xi_b-
    Baryon[0][4][2][0] = 5132;    BaryonWeight[0][4][2][0] *= 0.5;
    Baryon[2][0][4][0] = 5132;    BaryonWeight[2][0][4][0] *= 0.5;
    Baryon[2][4][0][0] = 5132;    BaryonWeight[2][4][0][0] *= 0.5;
    Baryon[4][0][2][0] = 5132;    BaryonWeight[4][0][2][0] *= 0.5;
    Baryon[4][2][0][0] = 5132;    BaryonWeight[4][2][0][0] *= 0.5;
 
    Baryon[0][2][4][2] = 5312;    BaryonWeight[0][2][4][2]  = 0.5 * pspin_barion;   // Xi_b-'
    Baryon[0][4][2][2] = 5312;    BaryonWeight[0][4][2][2]  = 0.5 * pspin_barion;
    Baryon[2][0][4][2] = 5312;    BaryonWeight[2][0][4][2]  = 0.5 * pspin_barion;
    Baryon[2][4][0][2] = 5312;    BaryonWeight[2][4][0][2]  = 0.5 * pspin_barion;
    Baryon[4][0][2][2] = 5312;    BaryonWeight[4][0][2][2]  = 0.5 * pspin_barion;
    Baryon[4][2][0][2] = 5312;    BaryonWeight[4][2][0][2]  = 0.5 * pspin_barion;
 
    for (G4int i=0; i<5; i++)
    {  for (G4int j=0; j<5; j++)
      {  for (G4int k=0; k<5; k++)
         {  for (G4int l=0; l<4; l++)
            { 
                     G4ParticleDefinition * TestHadron=
                       G4ParticleTable::GetParticleTable()->FindParticle(Baryon[i][j][k][l]);
                     /*
                     G4cout<<i<<" "<<j<<" "<<k<<" "<<l<<" "<<Baryon[i][j][k][l]<<" "<<TestHadron<<" "<<BaryonWeight[i][j][k][l];
                     if (TestHadron != nullptr) G4cout<<" "<<TestHadron->GetParticleName();
                     if ((TestHadron == nullptr)&&(Baryon[i][j][k][l] != 0)) G4cout<<" *****";
                     if ((TestHadron == nullptr)&&(Baryon[i][j][k][l] == 0)) G4cout<<" ---------------";
                     G4cout<<G4endl;
                     */
                     if ((TestHadron == nullptr)&&(Baryon[i][j][k][l] != 0)) Baryon[i][j][k][l] = 0;
                    }
         }
      }
    }
 
    // --------- Probabilities of q-qbar pair productions for kink or gluons.
    G4double ProbUUbar = 0.33;
    Prob_QQbar[0]=ProbUUbar;         // Probability of ddbar production
    Prob_QQbar[1]=ProbUUbar;         // Probability of uubar production
    Prob_QQbar[2]=1.0-2.*ProbUUbar;  // Probability of ssbar production 
    Prob_QQbar[3]=0.0;               // Probability of ccbar production
    Prob_QQbar[4]=0.0;               // Probability of bbbar production
 
    for ( G4int i=0 ; i<350 ; i++ ) { // Must be checked
      FS_LeftHadron[i] = 0;
      FS_RightHadron[i] = 0;
      FS_Weight[i] = 0.0; 
    }
 
    NumberOf_FS = 0;
}

Referenced by G4LundStringFragmentation::G4LundStringFragmentation(), G4QGSMFragmentation::G4QGSMFragmentation(), and G4VLongitudinalStringDecay().

SetProbBBbar()

void G4VLongitudinalStringDecay::SetProbBBbar

(

G4double

aValue

)

Definition at line 578 of file G4VLongitudinalStringDecay.cc.

{
   ProbBBbar = aValue;
   ProbCB = ProbCCbar + ProbBBbar;
}

Referenced by G4LundStringFragmentation::G4LundStringFragmentation(), G4QGSMFragmentation::G4QGSMFragmentation(), and G4VLongitudinalStringDecay().

SetProbCCbar()

void G4VLongitudinalStringDecay::SetProbCCbar

(

G4double

aValue

)

Definition at line 563 of file G4VLongitudinalStringDecay.cc.

{
   ProbCCbar = aValue;
   ProbCB = ProbCCbar + ProbBBbar;
}

Referenced by G4LundStringFragmentation::G4LundStringFragmentation(), G4QGSMFragmentation::G4QGSMFragmentation(), and G4VLongitudinalStringDecay().

SetProbEta_b()

void G4VLongitudinalStringDecay::SetProbEta_b

(

G4double

aValue

)

Definition at line 586 of file G4VLongitudinalStringDecay.cc.

{
   ProbEta_b = aValue;
}

Referenced by G4VLongitudinalStringDecay().

SetProbEta_c()

void G4VLongitudinalStringDecay::SetProbEta_c

(

G4double

aValue

)

Definition at line 571 of file G4VLongitudinalStringDecay.cc.

{
   ProbEta_c = aValue;
}

Referenced by G4VLongitudinalStringDecay().

SetScalarMesonMixings()

void G4VLongitudinalStringDecay::SetScalarMesonMixings

(

std::vector< G4double >

aVector

)

Definition at line 517 of file G4VLongitudinalStringDecay.cc.

{
  if ( PastInitPhase ) {
    throw G4HadronicException(__FILE__, __LINE__, 
      "G4VLongitudinalStringDecay::SetScalarMesonMixings after FragmentString() not allowed");
  } else {
    if ( aVector.size() < 6 ) 
      throw G4HadronicException(__FILE__, __LINE__, 
        "G4VLongitudinalStringDecay::SetScalarMesonMixings( argument Vector too small");
    scalarMesonMix[0] = aVector[0];
    scalarMesonMix[1] = aVector[1];
    scalarMesonMix[2] = aVector[2];
    scalarMesonMix[3] = aVector[3];
    scalarMesonMix[4] = aVector[4];
    scalarMesonMix[5] = aVector[5];
    delete hadronizer;
    hadronizer = new G4HadronBuilder( pspin_meson, pspin_barion, scalarMesonMix, vectorMesonMix, 
                                      ProbEta_c, ProbEta_b );
  }
}

SetSigmaTransverseMomentum()

void G4VLongitudinalStringDecay::SetSigmaTransverseMomentum

(

G4double

aQT

)

Definition at line 464 of file G4VLongitudinalStringDecay.cc.

{
   if ( PastInitPhase ) {
     throw G4HadronicException(__FILE__, __LINE__, 
       "G4VLongitudinalStringDecay::SetSigmaTransverseMomentum after FragmentString() not allowed");
   } else {
     SigmaQT = aValue;
   }
}

SetSpinThreeHalfBarionProbability()

void G4VLongitudinalStringDecay::SetSpinThreeHalfBarionProbability

(

G4double

aValue

)

Definition at line 502 of file G4VLongitudinalStringDecay.cc.

{
  if ( PastInitPhase ) {
    throw G4HadronicException(__FILE__, __LINE__, 
      "G4VLongitudinalStringDecay::SetSpinThreeHalfBarionProbability after FragmentString() not allowed");
  } else {
    pspin_barion = aValue;
    delete hadronizer;
    hadronizer = new G4HadronBuilder( pspin_meson, pspin_barion, scalarMesonMix, vectorMesonMix, 
                                      ProbEta_c, ProbEta_b );
  }
}

SetStrangenessSuppression()

void G4VLongitudinalStringDecay::SetStrangenessSuppression

(

G4double

aValue

)

Definition at line 476 of file G4VLongitudinalStringDecay.cc.

{
   StrangeSuppress = aValue;
}

Referenced by G4LundStringFragmentation::G4LundStringFragmentation(), and G4QGSMFragmentation::G4QGSMFragmentation().

SetStringTensionParameter()

void G4VLongitudinalStringDecay::SetStringTensionParameter

(

G4double

aValue

)

Definition at line 593 of file G4VLongitudinalStringDecay.cc.

{
   Kappa = aValue * GeV/fermi;
}   

Referenced by G4LundStringFragmentation::G4LundStringFragmentation().

SetVectorMesonMixings()

void G4VLongitudinalStringDecay::SetVectorMesonMixings

(

std::vector< G4double >

aVector

)

Definition at line 540 of file G4VLongitudinalStringDecay.cc.

{
  if ( PastInitPhase ) {
    throw G4HadronicException(__FILE__, __LINE__, 
      "G4VLongitudinalStringDecay::SetVectorMesonMixings after FragmentString() not allowed");
  } else {
    if ( aVector.size() < 6 ) 
      throw G4HadronicException(__FILE__, __LINE__, 
        "G4VLongitudinalStringDecay::SetVectorMesonMixings( argument Vector too small");
    vectorMesonMix[0] = aVector[0];
    vectorMesonMix[1] = aVector[1];
    vectorMesonMix[2] = aVector[2];
    vectorMesonMix[3] = aVector[3];
    vectorMesonMix[4] = aVector[4];
    vectorMesonMix[5] = aVector[5];
    delete hadronizer;
    hadronizer = new G4HadronBuilder( pspin_meson, pspin_barion, scalarMesonMix, vectorMesonMix, 
                                      ProbEta_c, ProbEta_b );
  }
}

SplitEandP()

virtual G4LorentzVector * G4VLongitudinalStringDecay::SplitEandP ( G4ParticleDefinition * pHadron, G4FragmentingString * string, G4FragmentingString * newString )

protectedpure virtual

SplitLast()

virtual G4bool G4VLongitudinalStringDecay::SplitLast ( G4FragmentingString * string, G4KineticTrackVector * LeftVector, G4KineticTrackVector * RightVector )

protectedpure virtual

Splitup()

virtual G4KineticTrack * G4VLongitudinalStringDecay::Splitup ( G4FragmentingString * string, G4FragmentingString *& newString )

protectedpure virtual

StopFragmenting()

virtual G4bool G4VLongitudinalStringDecay::StopFragmenting ( const G4FragmentingString *const string )

protectedpure virtual

Member Data Documentation

Baryon

G4int G4VLongitudinalStringDecay::Baryon[5][5][5][4]

Definition at line 235 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

BaryonWeight

G4double G4VLongitudinalStringDecay::BaryonWeight[5][5][5][4]

Definition at line 236 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

ClusterLoopInterrupt

G4int G4VLongitudinalStringDecay::ClusterLoopInterrupt

protected

Definition at line 191 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), GetClusterLoopInterrupt(), and PossibleHadronMass().

DecayQuark

G4int G4VLongitudinalStringDecay::DecayQuark

Definition at line 240 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), and QuarkSplitup().

DiquarkBreakProb

G4double G4VLongitudinalStringDecay::DiquarkBreakProb

protected

Definition at line 188 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), GetDiquarkBreakProb(), and SetDiquarkBreakProbability().

DiquarkSuppress

G4double G4VLongitudinalStringDecay::DiquarkSuppress

protected

Definition at line 187 of file G4VLongitudinalStringDecay.hh.

Referenced by CreatePartonPair(), G4VLongitudinalStringDecay(), GetDiquarkSuppress(), and SetDiquarkSuppression().

FS_LeftHadron

G4ParticleDefinition* G4VLongitudinalStringDecay::FS_LeftHadron[350]

Definition at line 250 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

FS_RightHadron

G4ParticleDefinition * G4VLongitudinalStringDecay::FS_RightHadron[350]

Definition at line 250 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

FS_Weight

G4double G4VLongitudinalStringDecay::FS_Weight[350]

Definition at line 251 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

hadronizer

G4HadronBuilder* G4VLongitudinalStringDecay::hadronizer

protected

Definition at line 193 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), PossibleHadronMass(), QuarkSplitup(), SetScalarMesonMixings(), SetSpinThreeHalfBarionProbability(), SetVectorMesonMixings(), and ~G4VLongitudinalStringDecay().

Kappa

G4double G4VLongitudinalStringDecay::Kappa

protected

Definition at line 212 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), GetStringTensionParameter(), and SetStringTensionParameter().

Mass_of_b_quark

G4double G4VLongitudinalStringDecay::Mass_of_b_quark

Definition at line 221 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

Mass_of_c_quark

G4double G4VLongitudinalStringDecay::Mass_of_c_quark

Definition at line 220 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

Mass_of_light_quark

G4double G4VLongitudinalStringDecay::Mass_of_light_quark

Definition at line 218 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

Mass_of_s_quark

G4double G4VLongitudinalStringDecay::Mass_of_s_quark

Definition at line 219 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

Mass_of_string_junction

G4double G4VLongitudinalStringDecay::Mass_of_string_junction

Definition at line 222 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

MassCut

G4double G4VLongitudinalStringDecay::MassCut

protected

Definition at line 185 of file G4VLongitudinalStringDecay.hh.

Referenced by G4QGSMFragmentation::G4QGSMFragmentation(), G4VLongitudinalStringDecay(), GetMassCut(), ProduceOneHadron(), and SetMassCut().

MaxMass

G4double G4VLongitudinalStringDecay::MaxMass

protected

Definition at line 208 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), PossibleHadronMass(), SetMinimalStringMass(), and SetMinMasses().

Meson

G4int G4VLongitudinalStringDecay::Meson[5][5][7]

Definition at line 232 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

MesonWeight

G4double G4VLongitudinalStringDecay::MesonWeight[5][5][7]

Definition at line 233 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

MinimalStringMass

G4double G4VLongitudinalStringDecay::MinimalStringMass

Definition at line 228 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinimalStringMass(), and SetMinMasses().

MinimalStringMass2

G4double G4VLongitudinalStringDecay::MinimalStringMass2

Definition at line 229 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinimalStringMass2(), and SetMinMasses().

minMassQDiQStr

G4double G4VLongitudinalStringDecay::minMassQDiQStr[5][5][5]

Definition at line 225 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinimalStringMass(), and SetMinMasses().

minMassQQbarStr

G4double G4VLongitudinalStringDecay::minMassQQbarStr[5][5]

Definition at line 224 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinimalStringMass(), and SetMinMasses().

NewParticles

std::vector<G4ParticleDefinition *> G4VLongitudinalStringDecay::NewParticles

protected

Definition at line 214 of file G4VLongitudinalStringDecay.hh.

Referenced by FindParticle().

NewQuark

G4int G4VLongitudinalStringDecay::NewQuark

Definition at line 241 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), and QuarkSplitup().

NumberOf_FS

G4int G4VLongitudinalStringDecay::NumberOf_FS

Definition at line 252 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

PastInitPhase

G4bool G4VLongitudinalStringDecay::PastInitPhase

protected

Definition at line 210 of file G4VLongitudinalStringDecay.hh.

Referenced by G4LundStringFragmentation::FragmentString(), G4QGSMFragmentation::FragmentString(), G4VLongitudinalStringDecay(), SetDiquarkBreakProbability(), SetScalarMesonMixings(), SetSigmaTransverseMomentum(), SetSpinThreeHalfBarionProbability(), and SetVectorMesonMixings().

Prob_QQbar

G4double G4VLongitudinalStringDecay::Prob_QQbar[5]

Definition at line 238 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

ProbBBbar

G4double G4VLongitudinalStringDecay::ProbBBbar

protected

Definition at line 203 of file G4VLongitudinalStringDecay.hh.

Referenced by GetProbBBbar(), SampleQuarkFlavor(), SetProbBBbar(), and SetProbCCbar().

ProbCB

G4double G4VLongitudinalStringDecay::ProbCB

protected

Definition at line 206 of file G4VLongitudinalStringDecay.hh.

Referenced by SampleQuarkFlavor(), SetProbBBbar(), and SetProbCCbar().

ProbCCbar

G4double G4VLongitudinalStringDecay::ProbCCbar

protected

Definition at line 200 of file G4VLongitudinalStringDecay.hh.

Referenced by GetProbCCbar(), SampleQuarkFlavor(), SetProbBBbar(), and SetProbCCbar().

ProbEta_b

G4double G4VLongitudinalStringDecay::ProbEta_b

protected

Definition at line 204 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), GetProbEta_b(), SetMinMasses(), SetProbEta_b(), SetScalarMesonMixings(), SetSpinThreeHalfBarionProbability(), and SetVectorMesonMixings().

ProbEta_c

G4double G4VLongitudinalStringDecay::ProbEta_c

protected

Definition at line 201 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), GetProbEta_c(), SetMinMasses(), SetProbEta_c(), SetScalarMesonMixings(), SetSpinThreeHalfBarionProbability(), and SetVectorMesonMixings().

pspin_barion

G4double G4VLongitudinalStringDecay::pspin_barion

protected

Definition at line 196 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), SetMinMasses(), SetScalarMesonMixings(), SetSpinThreeHalfBarionProbability(), and SetVectorMesonMixings().

pspin_meson

std::vector<G4double> G4VLongitudinalStringDecay::pspin_meson

protected

Definition at line 195 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), SetMinMasses(), SetScalarMesonMixings(), SetSpinThreeHalfBarionProbability(), and SetVectorMesonMixings().

Qcharge

G4int G4VLongitudinalStringDecay::Qcharge[5]

Definition at line 231 of file G4VLongitudinalStringDecay.hh.

Referenced by SetMinMasses().

scalarMesonMix

std::vector<G4double> G4VLongitudinalStringDecay::scalarMesonMix

protected

Definition at line 198 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), SetMinMasses(), SetScalarMesonMixings(), SetSpinThreeHalfBarionProbability(), and SetVectorMesonMixings().

SigmaQT

G4double G4VLongitudinalStringDecay::SigmaQT

protected

Definition at line 186 of file G4VLongitudinalStringDecay.hh.

Referenced by G4LundStringFragmentation::G4LundStringFragmentation(), G4QGSMFragmentation::G4QGSMFragmentation(), G4VLongitudinalStringDecay(), SampleQuarkPt(), and SetSigmaTransverseMomentum().

StrangeSuppress

G4double G4VLongitudinalStringDecay::StrangeSuppress

protected

Definition at line 189 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), GetStrangeSuppress(), SampleQuarkFlavor(), and SetStrangenessSuppression().

StringLoopInterrupt

G4int G4VLongitudinalStringDecay::StringLoopInterrupt

protected

Definition at line 190 of file G4VLongitudinalStringDecay.hh.

Referenced by G4QGSMFragmentation::FragmentString(), and G4VLongitudinalStringDecay().

vectorMesonMix

std::vector<G4double> G4VLongitudinalStringDecay::vectorMesonMix

protected

Definition at line 197 of file G4VLongitudinalStringDecay.hh.

Referenced by G4VLongitudinalStringDecay(), SetMinMasses(), SetScalarMesonMixings(), SetSpinThreeHalfBarionProbability(), and SetVectorMesonMixings().

---

The documentation for this class was generated from the following files:

• G4VLongitudinalStringDecay.hh
• G4VLongitudinalStringDecay.cc