dc/dcb/G4HadronPhysicsINCLXX_8cc_source.html

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

//

// ClassName:   G4HadronPhysicsINCLXX

//

// Author: 2011 P. Kaitaniemi

//

// Modified:

// 07.05.2020 A.Ribon: Use eventually QGSP for hyperons (and anti-hyperons)

//                     at high energies

// 05.05.2020 A.Ribon: Use eventually QGSP for antibaryons at high energies

// 22.05.2014 D. Mancusi: Extend INCL++ to 20 GeV

// 19.03.2013 A.Ribon: Replace LEP with FTFP and BERT

// 08.03.2013 D. Mancusi: Fix a problem with overlapping model ranges

// 01.03.2013 D. Mancusi: Rename to G4HadronPhysicsINCLXX and introduce

//                        parameters for FTFP and NeutronHP

// 31.10.2012 A.Ribon: Use G4MiscBuilder

// 23.03.2012 D. Mancusi: Extended INCL++ to incident heavy ions up to 16O

// 27.11.2011 P.Kaitaniemi: Created physics list for INCL++ using QGSP_INCL_ABLA as a template

//

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

//

#include <iomanip>


#include "G4HadronPhysicsINCLXX.hh"


#include "globals.hh"

#include "G4ios.hh"

#include "G4SystemOfUnits.hh"

#include "G4ParticleDefinition.hh"

#include "G4ParticleTable.hh"


#include "G4PionBuilder.hh"

#include "G4KaonBuilder.hh"

#include "G4QGSPPionBuilder.hh"

#include "G4FTFPPionBuilder.hh"

#include "G4QGSPKaonBuilder.hh"

#include "G4FTFPKaonBuilder.hh"

#include "G4INCLXXPionBuilder.hh"

#include "G4BertiniKaonBuilder.hh"


#include "G4ProtonBuilder.hh"

#include "G4QGSPProtonBuilder.hh"

#include "G4FTFPProtonBuilder.hh"

#include "G4INCLXXProtonBuilder.hh"


#include "G4NeutronBuilder.hh"

#include "G4QGSPNeutronBuilder.hh"

#include "G4FTFPNeutronBuilder.hh"

#include "G4INCLXXNeutronBuilder.hh"

#include "G4NeutronPHPBuilder.hh"


#include "G4HadronCaptureProcess.hh"

#include "G4NeutronRadCapture.hh"

#include "G4NeutronCaptureXS.hh"

#include "G4NeutronInelasticXS.hh"

#include "G4ParticleHPCaptureData.hh"

#include "G4LFission.hh"


#include "G4PhysListUtil.hh"

#include "G4HadParticles.hh"

#include "G4HadronicParameters.hh"

#include "G4HadronicBuilder.hh"


// factory

#include "G4PhysicsConstructorFactory.hh"

//

G4_DECLARE_PHYSCONSTR_FACTORY(G4HadronPhysicsINCLXX);


G4HadronPhysicsINCLXX::G4HadronPhysicsINCLXX(G4int)

    : G4HadronPhysicsINCLXX("hInelastic INCLXX")

{

}


G4HadronPhysicsINCLXX::G4HadronPhysicsINCLXX(const G4String& name, const G4bool quasiElastic, const G4bool neutronHP, const G4bool ftfp)

  : G4HadronPhysicsFTFP_BERT(name, quasiElastic),

    withNeutronHP(neutronHP),

    withFTFP(ftfp)

{

  QuasiElastic = withFTFP ? false : true;

  minBERT_neutron = withNeutronHP ? 19.9*MeV : 0.0;

}


void G4HadronPhysicsINCLXX::Neutron()

{

  G4HadronicParameters* param = G4HadronicParameters::Instance();

  G4bool useFactorXS = param->ApplyFactorXS();

  //General schema:

  // 1) Create a builder

  // 2) Call AddBuilder

  // 3) Configure the builder, possibly with sub-builders

  // 4) Call builder->Build()

  auto neu = new G4NeutronBuilder( withNeutronHP );

  AddBuilder(neu);

  G4PhysicsBuilderInterface* string = nullptr;

  if(withFTFP) {

    string = new G4FTFPNeutronBuilder(QuasiElastic);

  } else {

    string = new G4QGSPNeutronBuilder(QuasiElastic);

  }

  string->SetMinEnergy(15.*GeV);

  AddBuilder(string);

  neu->RegisterMe(string);


  auto inclxxn = new G4INCLXXNeutronBuilder;

  inclxxn->SetMaxEnergy(20.*GeV);

  AddBuilder(inclxxn);

  neu->RegisterMe(inclxxn);


  if(withNeutronHP) {

      inclxxn->UsePreCompound(false);

      inclxxn->SetMinEnergy(minBERT_neutron);

      auto hpn = new G4NeutronPHPBuilder;

      AddBuilder(hpn);

      neu->RegisterMe(hpn);

  } else {

      inclxxn->UsePreCompound(true);

      inclxxn->SetMinPreCompoundEnergy(0.0*MeV);

      inclxxn->SetMaxPreCompoundEnergy(2.0*MeV);

      inclxxn->SetMinEnergy(1.0*MeV);

  }


  neu->Build();


  const G4ParticleDefinition* neutron = G4Neutron::Neutron();

  G4HadronicProcess* inel = G4PhysListUtil::FindInelasticProcess(neutron);

  if(inel) {

    if( useFactorXS ) inel->MultiplyCrossSectionBy( param->XSFactorNucleonInelastic() );

  }

  G4HadronicProcess* capture = G4PhysListUtil::FindCaptureProcess(neutron);

  if (capture) {

    G4NeutronRadCapture* theNeutronRadCapture = new G4NeutronRadCapture();

    theNeutronRadCapture->SetMinEnergy( minBERT_neutron );

    capture->RegisterMe( theNeutronRadCapture );

  }

  G4HadronicProcess* fission = G4PhysListUtil::FindFissionProcess(neutron);

  if (fission) {

    G4LFission* theNeutronLEPFission = new G4LFission();

    theNeutronLEPFission->SetMinEnergy( minBERT_neutron );

    theNeutronLEPFission->SetMaxEnergy( G4HadronicParameters::Instance()->GetMaxEnergy() );

    fission->RegisterMe( theNeutronLEPFission );

  }

}


void G4HadronPhysicsINCLXX::Proton()

{

  G4HadronicParameters* param = G4HadronicParameters::Instance();

  G4bool useFactorXS = param->ApplyFactorXS();


  auto pro =new G4ProtonBuilder;

  AddBuilder(pro);

  G4PhysicsBuilderInterface* string = nullptr;

  if(withFTFP) {

    string = new G4FTFPProtonBuilder(QuasiElastic);

  } else {

    string = new G4QGSPProtonBuilder(QuasiElastic);

  }

  string->SetMinEnergy(15.*GeV);

  AddBuilder(string);

  pro->RegisterMe(string);


  auto inclxxp = new G4INCLXXProtonBuilder;

  AddBuilder(inclxxp);

  inclxxp->SetMinEnergy(1.0*MeV);

  inclxxp->SetMaxEnergy(20.0*GeV);

  pro->RegisterMe(inclxxp);

  pro->Build();


  const G4ParticleDefinition* proton = G4Proton::Proton();

  G4HadronicProcess* inel = G4PhysListUtil::FindInelasticProcess(proton);

  if(inel) {

    if( useFactorXS ) inel->MultiplyCrossSectionBy( param->XSFactorNucleonInelastic() );

  }

}


void G4HadronPhysicsINCLXX::Pion()

{

  G4HadronicParameters* param = G4HadronicParameters::Instance();

  G4bool useFactorXS = param->ApplyFactorXS();


  auto pi = new G4PionBuilder;

  AddBuilder(pi);

  G4PhysicsBuilderInterface* string = nullptr;

  if(withFTFP) {

    string = new G4FTFPPionBuilder(QuasiElastic);

  } else {

    string = new G4QGSPPionBuilder(QuasiElastic);

  }

  string->SetMinEnergy(15.*GeV);

  AddBuilder(string);

  pi->RegisterMe(string);


  auto inclxx = new G4INCLXXPionBuilder;

  inclxx->SetMinEnergy(0.0*GeV);

  inclxx->SetMaxEnergy(20.*GeV);

  AddBuilder(inclxx);

  pi->RegisterMe(inclxx);


  pi->Build();


  if( useFactorXS ) {

    const G4ParticleDefinition* pion = G4PionPlus::PionPlus();

    G4HadronicProcess* inel = G4PhysListUtil::FindInelasticProcess(pion);

    if(inel) {

      inel->MultiplyCrossSectionBy( param->XSFactorPionInelastic() );

    }

    pion = G4PionMinus::PionMinus();

    inel = G4PhysListUtil::FindInelasticProcess(pion);

    if(inel) {

      inel->MultiplyCrossSectionBy( param->XSFactorPionInelastic() );

    }

  }

}


void G4HadronPhysicsINCLXX::Kaon()

{

  G4HadronicParameters* param = G4HadronicParameters::Instance();

  G4bool useFactorXS = param->ApplyFactorXS();


  auto k = new G4KaonBuilder;

  AddBuilder(k);

  G4PhysicsBuilderInterface* string = nullptr;

  if(withFTFP) {

    string = new G4FTFPKaonBuilder(QuasiElastic);

  } else {

    string = new G4QGSPKaonBuilder(QuasiElastic);

  }

  string->SetMinEnergy(14.*GeV);

  AddBuilder(string);

  k->RegisterMe(string);


  auto bert = new G4BertiniKaonBuilder;

  bert->SetMinEnergy(0.0*GeV);

  bert->SetMaxEnergy(15.0*GeV);

  AddBuilder(bert);

  k->RegisterMe(bert);


  k->Build();


  if( useFactorXS ) {

    G4ParticleTable* table = G4ParticleTable::GetParticleTable();

    for( auto & pdg : G4HadParticles::GetKaons() ) {

      auto part = table->FindParticle( pdg );

      if ( part == nullptr ) { continue; }

      G4HadronicProcess* inel = G4PhysListUtil::FindInelasticProcess(part);

      if(inel) {

        inel->MultiplyCrossSectionBy( param->XSFactorHadronInelastic() );

      }

    }

  }

}


void G4HadronPhysicsINCLXX::Others()

{

  G4HadronicParameters* param = G4HadronicParameters::Instance();


  // high energy particles

  if( param->GetMaxEnergy() > param->EnergyThresholdForHeavyHadrons() ) {


    // anti light ions

    G4HadronicBuilder::BuildAntiLightIonsFTFP();


    if(withFTFP) {

      // hyperons

      G4HadronicBuilder::BuildHyperonsFTFP_BERT();


      // b-, c- baryons and mesons

      if( param->EnableBCParticles() ) {

    G4HadronicBuilder::BuildBCHadronsFTFP_BERT();

      }

    } else {

      // hyperons

      G4HadronicBuilder::BuildHyperonsQGSP_FTFP_BERT(true);


      // b-, c- baryons and mesons

      if( param->EnableBCParticles() ) {

    G4HadronicBuilder::BuildBCHadronsQGSP_FTFP_BERT(true);

      }

    }

  }

}


G4HadronPhysicsINCLXX::~G4HadronPhysicsINCLXX()

{}


void G4HadronPhysicsINCLXX::ConstructProcess()

{

  if(G4Threading::IsMasterThread()) {

      DumpBanner();

  }

  CreateModels();

}


G4BertiniKaonBuilder.hh

G4FTFPKaonBuilder.hh

G4FTFPNeutronBuilder.hh

G4FTFPPionBuilder.hh

G4FTFPProtonBuilder.hh

G4HadParticles.hh

G4HadronCaptureProcess.hh

G4HadronPhysicsINCLXX.hh

G4HadronicBuilder.hh

G4HadronicParameters.hh

G4INCLXXNeutronBuilder.hh

G4INCLXXPionBuilder.hh

G4INCLXXProtonBuilder.hh

G4KaonBuilder.hh

G4LFission.hh

G4NeutronBuilder.hh

G4NeutronCaptureXS.hh

G4NeutronInelasticXS.hh

G4NeutronPHPBuilder.hh

G4NeutronRadCapture.hh

G4ParticleDefinition.hh

G4ParticleHPCaptureData.hh

G4ParticleTable.hh

G4PhysListUtil.hh

G4PhysicsConstructorFactory.hh

G4_DECLARE_PHYSCONSTR_FACTORY
#define G4_DECLARE_PHYSCONSTR_FACTORY(physics_constructor)
Definition: G4PhysicsConstructorFactory.hh:59

G4PionBuilder.hh

G4ProtonBuilder.hh

G4QGSPKaonBuilder.hh

G4QGSPNeutronBuilder.hh

G4QGSPPionBuilder.hh

G4QGSPProtonBuilder.hh

G4SystemOfUnits.hh

G4bool
bool G4bool
Definition: G4Types.hh:86

G4int
int G4int
Definition: G4Types.hh:85

G4ios.hh

G4BertiniKaonBuilder
Definition: G4BertiniKaonBuilder.hh:53

G4BertiniKaonBuilder::SetMinEnergy
virtual void SetMinEnergy(G4double aM) final override
Definition: G4BertiniKaonBuilder.hh:65

G4FTFPKaonBuilder
Definition: G4FTFPKaonBuilder.hh:58

G4FTFPNeutronBuilder
Definition: G4FTFPNeutronBuilder.hh:58

G4FTFPPionBuilder
Definition: G4FTFPPionBuilder.hh:58

G4FTFPProtonBuilder
Definition: G4FTFPProtonBuilder.hh:57

G4HadParticles::GetKaons
static const std::vector< G4int > & GetKaons()
Definition: G4HadParticles.cc:122

G4HadronPhysicsFTFP_BERT
Definition: G4HadronPhysicsFTFP_BERT.hh:49

G4HadronPhysicsFTFP_BERT::QuasiElastic
G4bool QuasiElastic
Definition: G4HadronPhysicsFTFP_BERT.hh:82

G4HadronPhysicsFTFP_BERT::CreateModels
void CreateModels()
Definition: G4HadronPhysicsFTFP_BERT.cc:138

G4HadronPhysicsFTFP_BERT::minBERT_neutron
G4double minBERT_neutron
Definition: G4HadronPhysicsFTFP_BERT.hh:81

G4HadronPhysicsFTFP_BERT::DumpBanner
virtual void DumpBanner()
Definition: G4HadronPhysicsFTFP_BERT.cc:127

G4HadronPhysicsINCLXX
Definition: G4HadronPhysicsINCLXX.hh:63

G4HadronPhysicsINCLXX::Neutron
void Neutron() override
Definition: G4HadronPhysicsINCLXX.cc:109

G4HadronPhysicsINCLXX::Pion
void Pion() override
Definition: G4HadronPhysicsINCLXX.cc:201

G4HadronPhysicsINCLXX::Proton
void Proton() override
Definition: G4HadronPhysicsINCLXX.cc:170

G4HadronPhysicsINCLXX::~G4HadronPhysicsINCLXX
~G4HadronPhysicsINCLXX() override
Definition: G4HadronPhysicsINCLXX.cc:308

G4HadronPhysicsINCLXX::G4HadronPhysicsINCLXX
G4HadronPhysicsINCLXX(G4int verbose=1)
Definition: G4HadronPhysicsINCLXX.cc:95

G4HadronPhysicsINCLXX::Others
void Others() override
Definition: G4HadronPhysicsINCLXX.cc:278

G4HadronPhysicsINCLXX::ConstructProcess
void ConstructProcess() override
Definition: G4HadronPhysicsINCLXX.cc:311

G4HadronPhysicsINCLXX::Kaon
void Kaon() override
Definition: G4HadronPhysicsINCLXX.cc:240

G4HadronicBuilder::BuildBCHadronsFTFP_BERT
static void BuildBCHadronsFTFP_BERT()
Definition: G4HadronicBuilder.cc:259

G4HadronicBuilder::BuildHyperonsFTFP_BERT
static void BuildHyperonsFTFP_BERT()
Definition: G4HadronicBuilder.cc:216

G4HadronicBuilder::BuildHyperonsQGSP_FTFP_BERT
static void BuildHyperonsQGSP_FTFP_BERT(G4bool quasiElastic)
Definition: G4HadronicBuilder.cc:230

G4HadronicBuilder::BuildAntiLightIonsFTFP
static void BuildAntiLightIonsFTFP()
Definition: G4HadronicBuilder.cc:250

G4HadronicBuilder::BuildBCHadronsQGSP_FTFP_BERT
static void BuildBCHadronsQGSP_FTFP_BERT(G4bool quasiElastic)
Definition: G4HadronicBuilder.cc:279

G4HadronicInteraction::SetMinEnergy
void SetMinEnergy(G4double anEnergy)
Definition: G4HadronicInteraction.hh:89

G4HadronicInteraction::SetMaxEnergy
void SetMaxEnergy(const G4double anEnergy)
Definition: G4HadronicInteraction.hh:102

G4HadronicParameters
Definition: G4HadronicParameters.hh:48

G4HadronicParameters::ApplyFactorXS
G4bool ApplyFactorXS() const
Definition: G4HadronicParameters.hh:215

G4HadronicParameters::Instance
static G4HadronicParameters * Instance()
Definition: G4HadronicParameters.cc:52

G4HadronicParameters::EnableBCParticles
G4bool EnableBCParticles() const
Definition: G4HadronicParameters.hh:211

G4HadronicParameters::EnergyThresholdForHeavyHadrons
G4double EnergyThresholdForHeavyHadrons() const
Definition: G4HadronicParameters.hh:175

G4HadronicParameters::XSFactorHadronInelastic
G4double XSFactorHadronInelastic() const
Definition: G4HadronicParameters.hh:195

G4HadronicParameters::XSFactorPionInelastic
G4double XSFactorPionInelastic() const
Definition: G4HadronicParameters.hh:187

G4HadronicParameters::GetMaxEnergy
G4double GetMaxEnergy() const
Definition: G4HadronicParameters.hh:156

G4HadronicParameters::XSFactorNucleonInelastic
G4double XSFactorNucleonInelastic() const
Definition: G4HadronicParameters.hh:179

G4HadronicProcess
Definition: G4HadronicProcess.hh:69

G4HadronicProcess::MultiplyCrossSectionBy
void MultiplyCrossSectionBy(G4double factor)
Definition: G4HadronicProcess.cc:485

G4HadronicProcess::RegisterMe
void RegisterMe(G4HadronicInteraction *a)
Definition: G4HadronicProcess.cc:143

G4INCLXXNeutronBuilder
Definition: G4INCLXXNeutronBuilder.hh:55

G4INCLXXNeutronBuilder::SetMaxEnergy
virtual void SetMaxEnergy(G4double aM) final override
Definition: G4INCLXXNeutronBuilder.hh:67

G4INCLXXPionBuilder
Definition: G4INCLXXPionBuilder.hh:57

G4INCLXXPionBuilder::SetMinEnergy
virtual void SetMinEnergy(G4double aM) final override
Definition: G4INCLXXPionBuilder.hh:66

G4INCLXXProtonBuilder
Definition: G4INCLXXProtonBuilder.hh:55

G4KaonBuilder
Definition: G4KaonBuilder.hh:52

G4LFission
Definition: G4LFission.hh:65

G4NeutronBuilder
Definition: G4NeutronBuilder.hh:53

G4NeutronPHPBuilder
Definition: G4NeutronPHPBuilder.hh:47

G4NeutronRadCapture
Definition: G4NeutronRadCapture.hh:52

G4Neutron::Neutron
static G4Neutron * Neutron()
Definition: G4Neutron.cc:103

G4ParticleDefinition
Definition: G4ParticleDefinition.hh:60

G4ParticleTable
Definition: G4ParticleTable.hh:60

G4ParticleTable::FindParticle
G4ParticleDefinition * FindParticle(G4int PDGEncoding)
Definition: G4ParticleTable.cc:586

G4ParticleTable::GetParticleTable
static G4ParticleTable * GetParticleTable()
Definition: G4ParticleTable.cc:87

G4PhysListUtil::FindInelasticProcess
static G4HadronicProcess * FindInelasticProcess(const G4ParticleDefinition *)
Definition: G4PhysListUtil.cc:58

G4PhysListUtil::FindCaptureProcess
static G4HadronicProcess * FindCaptureProcess(const G4ParticleDefinition *)
Definition: G4PhysListUtil.cc:94

G4PhysListUtil::FindFissionProcess
static G4HadronicProcess * FindFissionProcess(const G4ParticleDefinition *)
Definition: G4PhysListUtil.cc:112

G4PhysicsBuilderInterface
Definition: G4PhysicsBuilderInterface.hh:43

G4PionBuilder
Definition: G4PionBuilder.hh:49

G4PionMinus::PionMinus
static G4PionMinus * PionMinus()
Definition: G4PionMinus.cc:97

G4PionPlus::PionPlus
static G4PionPlus * PionPlus()
Definition: G4PionPlus.cc:97

G4ProtonBuilder
Definition: G4ProtonBuilder.hh:52

G4Proton::Proton
static G4Proton * Proton()
Definition: G4Proton.cc:92

G4QGSPKaonBuilder
Definition: G4QGSPKaonBuilder.hh:58

G4QGSPNeutronBuilder
Definition: G4QGSPNeutronBuilder.hh:59

G4QGSPPionBuilder
Definition: G4QGSPPionBuilder.hh:59

G4QGSPProtonBuilder
Definition: G4QGSPProtonBuilder.hh:59

G4String
Definition: G4String.hh:53

G4VPhysicsConstructor::AddBuilder
void AddBuilder(G4PhysicsBuilderInterface *bld)
Definition: G4VPhysicsConstructor.cc:114

globals.hh

G4Threading::IsMasterThread
G4bool IsMasterThread()
Definition: G4Threading.cc:124