#include <HadronPhysicsQGSPCMS_FTFP_BERT.h>

Inheritance diagram for HadronPhysicsQGSPCMS_FTFP_BERT:

Classes
struct	ThreadPrivate

Public Member Functions
virtual void	ConstructParticle ()

virtual void	ConstructProcess ()

	HadronPhysicsQGSPCMS_FTFP_BERT (G4int verbose)

virtual	~HadronPhysicsQGSPCMS_FTFP_BERT ()

Private Member Functions
void	CreateModels ()

Static Private Attributes
static G4ThreadLocal ThreadPrivate *	tpdata = 0

Detailed Description

Definition at line 28 of file HadronPhysicsQGSPCMS_FTFP_BERT.h.

Constructor & Destructor Documentation

HadronPhysicsQGSPCMS_FTFP_BERT::HadronPhysicsQGSPCMS_FTFP_BERT ( G4int verbose )

Definition at line 25 of file HadronPhysicsQGSPCMS_FTFP_BERT.cc.

26 : G4VPhysicsConstructor("hInelasticQGSPCMS_FTFP_BERT")

27 {}

HadronPhysicsQGSPCMS_FTFP_BERT::~HadronPhysicsQGSPCMS_FTFP_BERT ( )

virtual

Definition at line 95 of file HadronPhysicsQGSPCMS_FTFP_BERT.cc.

 {
    delete tpdata->theQGSPNeutron;
    delete tpdata->theFTFPNeutron;
    delete tpdata->theBertiniNeutron;
    delete tpdata->theNeutrons;
 
    delete tpdata->theQGSPPro;
    delete tpdata->theFTFPPro;
    delete tpdata->thePro;
    delete tpdata->theBertiniPro;
 
    delete tpdata->theQGSPPiK;
    delete tpdata->theFTFPPiK;
    delete tpdata->theBertiniPiK;
    delete tpdata->thePiK;
 
    delete tpdata->theHyperon;
    delete tpdata->theAntiBaryon;
    delete tpdata->theFTFPAntiBaryon;
 
    delete tpdata->xsNeutronInelasticXS;
    delete tpdata->xsNeutronCaptureXS; 
    
    delete tpdata;
 }

Member Function Documentation

void HadronPhysicsQGSPCMS_FTFP_BERT::ConstructParticle ( )

virtual

Definition at line 122 of file HadronPhysicsQGSPCMS_FTFP_BERT.cc.

 {
   G4MesonConstructor pMesonConstructor;
   pMesonConstructor.ConstructParticle();
 
   G4BaryonConstructor pBaryonConstructor;
   pBaryonConstructor.ConstructParticle();
 
   G4ShortLivedConstructor pShortLivedConstructor;
   pShortLivedConstructor.ConstructParticle();  
 
   G4IonConstructor pIonConstructor;
   pIonConstructor.ConstructParticle();
 }

void HadronPhysicsQGSPCMS_FTFP_BERT::ConstructProcess ( )

virtual

Definition at line 138 of file HadronPhysicsQGSPCMS_FTFP_BERT.cc.

References ztee::capture(), CreateModels(), i, MetAnalyzer::pv(), HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate::theAntiBaryon, HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate::theHyperon, HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate::theNeutrons, HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate::thePiK, HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate::thePro, tpdata, HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate::xsNeutronCaptureXS, and HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate::xsNeutronInelasticXS.

 {
   if ( tpdata == 0 ) tpdata = new ThreadPrivate;
   CreateModels();
   tpdata->theNeutrons->Build();
   tpdata->thePro->Build();
   tpdata->thePiK->Build();
   tpdata->theHyperon->Build(); 
   tpdata->theAntiBaryon->Build(); 
 
   // --- Neutrons ---
   tpdata->xsNeutronInelasticXS = new G4NeutronInelasticXS();  
   G4PhysListUtil::FindInelasticProcess(G4Neutron::Neutron())
     ->AddDataSet(tpdata->xsNeutronInelasticXS);
 
   G4HadronicProcess* capture = 0;
   G4ProcessManager* pmanager = G4Neutron::Neutron()->GetProcessManager();
   G4ProcessVector*  pv = pmanager->GetProcessList();
   for ( size_t i=0; i < static_cast<size_t>(pv->size()); ++i ) {
     if ( fCapture == ((*pv)[i])->GetProcessSubType() ) {
       capture = static_cast<G4HadronicProcess*>((*pv)[i]);
     }
   }
   if ( ! capture ) {
     capture = new G4HadronCaptureProcess("nCapture");
     pmanager->AddDiscreteProcess(capture);
   }
   tpdata->xsNeutronCaptureXS = new G4NeutronCaptureXS();
   capture->AddDataSet(tpdata->xsNeutronCaptureXS);
   capture->RegisterMe(new G4NeutronRadCapture());
 }

void HadronPhysicsQGSPCMS_FTFP_BERT::CreateModels ( )

private

Definition at line 29 of file HadronPhysicsQGSPCMS_FTFP_BERT.cc.

Referenced by ConstructProcess().

 {
   // First transition, between BERT and FTF/P
   G4double minFTFP= 6.0 * GeV;     // Was 9.5 for LEP   (in FTFP_BERT 6.0 * GeV);
   G4double maxBERT= 8.0 * GeV;     // Was 9.9 for LEP   (in FTFP_BERT 8.0 * GeV);
   // Second transition, between FTF/P and QGS/P
   G4double minQGSP= 12.0 * GeV;
   G4double maxFTFP= 25.0 * GeV; 
 
   G4bool   quasiElasFTF= false;   // Use built-in quasi-elastic (not add-on)
   G4bool   quasiElasQGS= true;    // For QGS, it must use it.
 
   G4cout << " New QGSPCMS_FTFP_BERT hadronic inealstic physics" << G4endl;
   G4cout << "   Thresholds: " << G4endl;
   G4cout << "     1) between BERT  and FTFP over the interval " 
      << minFTFP/GeV << " to " << maxBERT/GeV << " GeV. " << G4endl;
   G4cout << "     2) between FTFP and QGSP over the interval " 
      << minQGSP/GeV << " to " << maxFTFP/GeV << " GeV. " << G4endl;
   G4cout << "   QuasiElastic: " << quasiElasQGS << " for QGS "
      << " and " << quasiElasFTF << " for FTF " << G4endl;
 
   tpdata->theNeutrons=new G4NeutronBuilder;
   tpdata->theNeutrons->RegisterMe(
     tpdata->theQGSPNeutron=new G4QGSPNeutronBuilder(quasiElasQGS));
   tpdata->theQGSPNeutron->SetMinEnergy(minQGSP);   
   tpdata->theNeutrons->RegisterMe(
     tpdata->theFTFPNeutron=new G4FTFPNeutronBuilder(quasiElasFTF));
   tpdata->theFTFPNeutron->SetMinEnergy(minFTFP);   
   tpdata->theFTFPNeutron->SetMaxEnergy(maxFTFP);   
 
   tpdata->theNeutrons->RegisterMe(
     tpdata->theBertiniNeutron=new G4BertiniNeutronBuilder);
   tpdata->theBertiniNeutron->SetMinEnergy(0.0*GeV);
   tpdata->theBertiniNeutron->SetMaxEnergy(maxBERT);  
 
   tpdata->thePro=new G4ProtonBuilder;
   tpdata->thePro->RegisterMe(
     tpdata->theQGSPPro=new G4QGSPProtonBuilder(quasiElasQGS));
   tpdata->theQGSPPro->SetMinEnergy(minQGSP);   
   tpdata->thePro->RegisterMe(
     tpdata->theFTFPPro=new G4FTFPProtonBuilder(quasiElasFTF));
   tpdata->theFTFPPro->SetMinEnergy(minFTFP);   
   tpdata->theFTFPPro->SetMaxEnergy(maxFTFP);   
   tpdata->thePro->RegisterMe(
     tpdata->theBertiniPro=new G4BertiniProtonBuilder);
   tpdata->theBertiniPro->SetMaxEnergy(maxBERT); 
   
   tpdata->thePiK=new G4PiKBuilder;
   tpdata->thePiK->RegisterMe(
     tpdata->theQGSPPiK=new G4QGSPPiKBuilder(quasiElasQGS));
   tpdata->theQGSPPiK->SetMinEnergy(minQGSP);   
   tpdata->thePiK->RegisterMe(
     tpdata->theFTFPPiK=new G4FTFPPiKBuilder(quasiElasFTF));
   tpdata->theFTFPPiK->SetMaxEnergy(maxFTFP);  
   tpdata->theFTFPPiK->SetMinEnergy(minFTFP); 
   tpdata->thePiK->RegisterMe(tpdata->theBertiniPiK=new G4BertiniPiKBuilder);
   tpdata->theBertiniPiK->SetMaxEnergy(maxBERT); 
   
   // Hyperons use FTF
   tpdata->theHyperon=new G4HyperonFTFPBuilder;
 
   tpdata->theAntiBaryon=new G4AntiBarionBuilder;
   tpdata->theAntiBaryon->RegisterMe(
     tpdata->theFTFPAntiBaryon=new G4FTFPAntiBarionBuilder(quasiElasFTF));
 }

Member Data Documentation

G4ThreadLocal HadronPhysicsQGSPCMS_FTFP_BERT::ThreadPrivate * HadronPhysicsQGSPCMS_FTFP_BERT::tpdata = 0

staticprivate

Definition at line 64 of file HadronPhysicsQGSPCMS_FTFP_BERT.h.

Referenced by ConstructProcess(), CreateModels(), and ~HadronPhysicsQGSPCMS_FTFP_BERT().

Classes

Public Member Functions

Private Member Functions

Static Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation