#include <CMSEmStandardPhysics.h>

Inheritance diagram for CMSEmStandardPhysics:

Public Member Functions
	CMSEmStandardPhysics (G4int ver)

virtual void	ConstructParticle ()

virtual void	ConstructProcess ()

virtual	~CMSEmStandardPhysics ()

Private Attributes
G4int	verbose

Detailed Description

Definition at line 7 of file CMSEmStandardPhysics.h.

Constructor & Destructor Documentation

CMSEmStandardPhysics::CMSEmStandardPhysics ( G4int ver )

Definition at line 72 of file CMSEmStandardPhysics.cc.

                                                     :
   G4VPhysicsConstructor("CMSEmStandard_opt1"), verbose(ver) {
   G4LossTableManager::Instance();
   SetPhysicsType(bElectromagnetic);
 }

CMSEmStandardPhysics::~CMSEmStandardPhysics ( )

virtual

Definition at line 78 of file CMSEmStandardPhysics.cc.

78 {}

Member Function Documentation

void CMSEmStandardPhysics::ConstructParticle ( )

virtual

Definition at line 80 of file CMSEmStandardPhysics.cc.

References configurableAnalysis::Electron, and Gamma.

                                              {
   // gamma
   G4Gamma::Gamma();
 
   // leptons
   G4Electron::Electron();
   G4Positron::Positron();
   G4MuonPlus::MuonPlus();
   G4MuonMinus::MuonMinus();
   G4TauMinus::TauMinusDefinition();
   G4TauPlus::TauPlusDefinition();
 
   // mesons
   G4PionPlus::PionPlusDefinition();
   G4PionMinus::PionMinusDefinition();
   G4KaonPlus::KaonPlusDefinition();
   G4KaonMinus::KaonMinusDefinition();
   G4DMesonMinus::DMesonMinusDefinition();
   G4DMesonPlus::DMesonPlusDefinition();
   G4BMesonMinus::BMesonMinusDefinition();
   G4BMesonPlus::BMesonPlusDefinition();
 
   // barions
   G4Proton::Proton();
   G4AntiProton::AntiProton();
   G4SigmaMinus::SigmaMinusDefinition();
   G4AntiSigmaMinus::AntiSigmaMinusDefinition();
   G4SigmaPlus::SigmaPlusDefinition();
   G4AntiSigmaPlus::AntiSigmaPlusDefinition();
   G4XiMinus::XiMinusDefinition();
   G4AntiXiMinus::AntiXiMinusDefinition();
   G4OmegaMinus::OmegaMinusDefinition();
   G4AntiOmegaMinus::AntiOmegaMinusDefinition();
   G4LambdacPlus::LambdacPlusDefinition();
   G4AntiLambdacPlus::AntiLambdacPlusDefinition();
   G4XicPlus::XicPlusDefinition();
   G4AntiXicPlus::AntiXicPlusDefinition();
 
   // ions
   G4Deuteron::Deuteron();
   G4Triton::Triton();
   G4He3::He3();
   G4Alpha::Alpha();
   G4GenericIon::GenericIonDefinition();
 }

void CMSEmStandardPhysics::ConstructProcess ( )

virtual

Definition at line 126 of file CMSEmStandardPhysics.cc.

References kp, MeV, AnalysisDataFormats_SUSYBSMObjects::msc, pi, createTree::pp, and contentValuesCheck::ss.

                                             {
 
   if(verbose > 0) {
     G4cout << "### " << GetPhysicsName() << " Construct Processes " << G4endl;
   }
 
   // This EM builder takes default models of Geant4 10 EMV.
   // Multiple scattering by Urban for all particles
   // except e+e- below 100 MeV for which the Urban93 model is used
 
   G4PhysicsListHelper* ph = G4PhysicsListHelper::GetPhysicsListHelper();
 
   // muon & hadron bremsstrahlung and pair production
   G4MuBremsstrahlung* mub = new G4MuBremsstrahlung();
   G4MuPairProduction* mup = new G4MuPairProduction();
   G4hBremsstrahlung* pib = new G4hBremsstrahlung();
   G4hPairProduction* pip = new G4hPairProduction();
   G4hBremsstrahlung* kb = new G4hBremsstrahlung();
   G4hPairProduction* kp = new G4hPairProduction();
   G4hBremsstrahlung* pb = new G4hBremsstrahlung();
   G4hPairProduction* pp = new G4hPairProduction();
 
   // muon & hadron multiple scattering
   G4MuMultipleScattering* mumsc = new G4MuMultipleScattering();
   mumsc->AddEmModel(0, new G4WentzelVIModel());
   G4MuMultipleScattering* pimsc = new G4MuMultipleScattering();
   pimsc->AddEmModel(0, new G4WentzelVIModel());
   G4MuMultipleScattering* kmsc = new G4MuMultipleScattering();
   kmsc->AddEmModel(0, new G4WentzelVIModel());
   G4MuMultipleScattering* pmsc = new G4MuMultipleScattering();
   pmsc->AddEmModel(0, new G4WentzelVIModel());
   G4hMultipleScattering* hmsc = new G4hMultipleScattering("ionmsc");
 
   // high energy limit for e+- scattering models and bremsstrahlung
   G4double highEnergyLimit = 100*MeV;
 
   aParticleIterator->reset();
   while( (*aParticleIterator)() ){
     G4ParticleDefinition* particle = aParticleIterator->value();
     G4String particleName = particle->GetParticleName();
 
     if (particleName == "gamma") {
 
       ph->RegisterProcess(new G4PhotoElectricEffect(), particle);
       ph->RegisterProcess(new G4ComptonScattering(), particle);
       ph->RegisterProcess(new G4GammaConversion(), particle);
 
     } else if (particleName == "e-") {
 
       G4eIonisation* eioni = new G4eIonisation();
       eioni->SetStepFunction(0.8, 1.0*mm);
 
       G4eMultipleScattering* msc = new G4eMultipleScattering;
       msc->SetStepLimitType(fMinimal);
       UrbanMscModel93* msc1 = new UrbanMscModel93();
       G4WentzelVIModel* msc2 = new G4WentzelVIModel();
       msc1->SetHighEnergyLimit(highEnergyLimit);
       msc2->SetLowEnergyLimit(highEnergyLimit);
       msc->AddEmModel(0, msc1);
       msc->AddEmModel(0, msc2);
 
       G4eCoulombScatteringModel* ssm = new G4eCoulombScatteringModel(); 
       G4CoulombScattering* ss = new G4CoulombScattering();
       ss->SetEmModel(ssm, 1); 
       ss->SetMinKinEnergy(highEnergyLimit);
       ssm->SetLowEnergyLimit(highEnergyLimit);
       ssm->SetActivationLowEnergyLimit(highEnergyLimit);
 
       ph->RegisterProcess(msc, particle);
       ph->RegisterProcess(eioni, particle);
       ph->RegisterProcess(new G4eBremsstrahlung(), particle);
       ph->RegisterProcess(ss, particle);
 
     } else if (particleName == "e+") {
 
       G4eIonisation* eioni = new G4eIonisation();
       eioni->SetStepFunction(0.8, 1.0*mm);
 
       G4eMultipleScattering* msc = new G4eMultipleScattering;
       msc->SetStepLimitType(fMinimal);
       UrbanMscModel93* msc1 = new UrbanMscModel93();
       G4WentzelVIModel* msc2 = new G4WentzelVIModel();
       msc1->SetHighEnergyLimit(highEnergyLimit);
       msc2->SetLowEnergyLimit(highEnergyLimit);
       msc->AddEmModel(0, msc1);
       msc->AddEmModel(0, msc2);
 
       G4eCoulombScatteringModel* ssm = new G4eCoulombScatteringModel(); 
       G4CoulombScattering* ss = new G4CoulombScattering();
       ss->SetEmModel(ssm, 1); 
       ss->SetMinKinEnergy(highEnergyLimit);
       ssm->SetLowEnergyLimit(highEnergyLimit);
       ssm->SetActivationLowEnergyLimit(highEnergyLimit);
 
       ph->RegisterProcess(msc, particle);
       ph->RegisterProcess(eioni, particle);
       ph->RegisterProcess(new G4eBremsstrahlung(), particle);
       ph->RegisterProcess(new G4eplusAnnihilation(), particle);
       ph->RegisterProcess(ss, particle);
 
     } else if (particleName == "mu+" ||
                particleName == "mu-" ) {
 
       ph->RegisterProcess(mumsc, particle);
       ph->RegisterProcess(new G4MuIonisation(), particle);
       ph->RegisterProcess(mub, particle);
       ph->RegisterProcess(mup, particle);
       ph->RegisterProcess(new G4CoulombScattering(), particle);
 
     } else if (particleName == "alpha" || 
            particleName == "He3" ) {
 
       //ph->RegisterProcess(hmsc, particle);
       ph->RegisterProcess(new G4hMultipleScattering(), particle);
       ph->RegisterProcess(new G4ionIonisation(), particle);
 
     } else if (particleName == "GenericIon") {
 
       ph->RegisterProcess(hmsc, particle);
       ph->RegisterProcess(new G4ionIonisation(), particle);
 
     } else if (particleName == "pi+" || 
            particleName == "pi-" ) {
 
       //G4hMultipleScattering* pimsc = new G4hMultipleScattering();
       ph->RegisterProcess(pimsc, particle);
       ph->RegisterProcess(new G4hIonisation(), particle);
       ph->RegisterProcess(pib, particle);
       ph->RegisterProcess(pip, particle);
       ph->RegisterProcess(new G4CoulombScattering(), particle);
 
     } else if (particleName == "kaon+" ||
                particleName == "kaon-" ) {
 
       //G4hMultipleScattering* kmsc = new G4hMultipleScattering();
       ph->RegisterProcess(kmsc, particle);
       ph->RegisterProcess(new G4hIonisation(), particle);
       ph->RegisterProcess(kb, particle);
       ph->RegisterProcess(kp, particle);
       ph->RegisterProcess(new G4CoulombScattering(), particle);
 
       //    } else if (particleName == "proton" ) {
     } else if (particleName == "proton" ||
            particleName == "anti_proton") {
 
       //G4hMultipleScattering* pmsc = new G4hMultipleScattering();
       ph->RegisterProcess(pmsc, particle);
       ph->RegisterProcess(new G4hIonisation(), particle);
       ph->RegisterProcess(pb, particle);
       ph->RegisterProcess(pp, particle);
       ph->RegisterProcess(new G4CoulombScattering(), particle);
 
     } else if (particleName == "B+" ||
            particleName == "B-" ||
            particleName == "D+" ||
            particleName == "D-" ||
            particleName == "Ds+" ||
            particleName == "Ds-" ||
                particleName == "anti_He3" ||
                particleName == "anti_alpha" ||
                particleName == "anti_deuteron" ||
                particleName == "anti_lambda_c+" ||
                particleName == "anti_omega-" ||
                particleName == "anti_sigma_c+" ||
                particleName == "anti_sigma_c++" ||
                particleName == "anti_sigma+" ||
                particleName == "anti_sigma-" ||
                particleName == "anti_triton" ||
                particleName == "anti_xi_c+" ||
                particleName == "anti_xi-" ||
                particleName == "deuteron" ||
            particleName == "lambda_c+" ||
                particleName == "omega-" ||
                particleName == "sigma_c+" ||
                particleName == "sigma_c++" ||
                particleName == "sigma+" ||
                particleName == "sigma-" ||
                particleName == "tau+" ||
                particleName == "tau-" ||
                particleName == "triton" ||
                particleName == "xi_c+" ||
                particleName == "xi-" ) {
 
       ph->RegisterProcess(hmsc, particle);
       ph->RegisterProcess(new G4hIonisation(), particle);
     }
   }
   G4EmProcessOptions opt;
   opt.SetVerbose(verbose);
   opt.SetPolarAngleLimit(CLHEP::pi);
   opt.SetApplyCuts(true);
 }

Member Data Documentation

G4int CMSEmStandardPhysics::verbose

private

Definition at line 17 of file CMSEmStandardPhysics.h.

Public Member Functions

Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation