DetectorBari05 Class Reference

#include <DetectorBari05.hh>

Public Member Functions
	DetectorBari05 ()
	~DetectorBari05 ()
G4VPhysicalVolume *	Construct ()
RadiatorDescription *	GetRadiatorDescription () const

Detailed Description

Definition at line 45 of file DetectorBari05.hh.

Constructor & Destructor Documentation

DetectorBari05::DetectorBari05

(

)

Definition at line 55 of file DetectorBari05.cc.

  : fRadiatorDescription(0) 
{}

DetectorBari05::~DetectorBari05

(

)

Definition at line 61 of file DetectorBari05.cc.

{
  // delete fRadiatorDescription;
        // the description is deleted in detector construction
}

Member Function Documentation

G4VPhysicalVolume * DetectorBari05::Construct

(

void

)

Definition at line 69 of file DetectorBari05.cc.

{
  // Geometry parameters
  //

  G4cout << "DetectorBari05 setup" << G4endl;

  G4double worldSizeZ = 600.*cm;
  G4double worldSizeR = 22.*cm;

  // Radiator and detector parameters

  G4double radThickness = 0.0055*mm; // Reg2
  G4double gasGap       = 0.23*mm; // Reg2
  G4double foilGasRatio = radThickness/(radThickness+gasGap);
  G4double foilNumber   = 191;      // Reg2

  G4double absorberThickness = 0.4*mm;
  G4double absorberRadius   = 100.*mm;

  G4double electrodeThick = 100.0*micrometer;
  G4double pipeLength     = 50.0*cm;
  G4double mylarThick     = 20.0*micrometer;
  G4double detGap         = 0.01*mm;

  G4double startZ = 100.0*mm;

  // Preparation of mixed radiator material


  // Materials
  //

  // Change to create materials using NIST
  G4Material* air   = Materials::GetInstance()->GetMaterial("Air");
  G4Material* ch2   = Materials::GetInstance()->GetMaterial("CH2");
  G4Material* he    = Materials::GetInstance()->GetMaterial("He");
  G4Material* si =  Materials::GetInstance()->GetMaterial("Si");

  G4double foilDensity =  ch2->GetDensity();
  G4double gasDensity  =  air->GetDensity(); 
  G4double totDensity  = foilDensity*foilGasRatio 
                       + gasDensity*(1.0-foilGasRatio);

  G4double fractionFoil =  foilDensity*foilGasRatio/totDensity;
  G4double fractionGas  =  gasDensity*(1.0-foilGasRatio)/totDensity;
  G4Material* radiatorMat = new G4Material("radiatorMat", totDensity, 2);
  radiatorMat->AddMaterial(ch2, fractionFoil);
  radiatorMat->AddMaterial(air, fractionGas);

  // Radiator description
  fRadiatorDescription = new RadiatorDescription;
  fRadiatorDescription->fFoilMaterial  = ch2; // CH2; // Kapton; // Mylar ; // Li ; // CH2 ;
  fRadiatorDescription->fGasMaterial   = air; // CO2; // He; //
  fRadiatorDescription->fFoilThickness = radThickness;
  fRadiatorDescription->fGasThickness  = gasGap;
  fRadiatorDescription->fFoilNumber = foilNumber;

  // pipe material is assumed to be He + small admixture of air
  foilGasRatio = 0.99999;
  foilDensity  = 1.2928*mg/cm3; // Air
  gasDensity   = 0.178*mg/cm3; // He
  totDensity   = foilDensity*foilGasRatio + gasDensity*(1.0-foilGasRatio);

  fractionFoil =  foilDensity*foilGasRatio/totDensity;
  fractionGas  =  gasDensity*(1.0-foilGasRatio)/totDensity;

  G4Material* pipeMat = new G4Material("pipeMat", totDensity, 2);
  pipeMat->AddMaterial(air, fractionFoil);
  pipeMat->AddMaterial(he, fractionGas);


  G4Material* worldMaterial    = air; // CO2;
  G4Material* absorberMaterial = si;

  // Volumes
  //
 
  G4VSolid* solidWorld 
    = new G4Box("World", worldSizeR, worldSizeR, worldSizeZ/2.);
 
  G4LogicalVolume* logicWorld 
    = new G4LogicalVolume(solidWorld,  worldMaterial,  "World");

  G4VPhysicalVolume* physicsWorld 
    = new G4PVPlacement(0, G4ThreeVector(), "World", logicWorld, 0,  false, 0);

  // TR radiator envelope

  G4double radThick = foilNumber*(radThickness + gasGap) - gasGap + detGap;
  G4double radZ = startZ + 0.5*radThick;

  G4VSolid* solidRadiator 
    = new G4Box("Radiator", 1.1*absorberRadius, 1.1*absorberRadius, 0.5*radThick);

  G4LogicalVolume* logicRadiator 
    = new G4LogicalVolume(solidRadiator, radiatorMat, "Radiator");
 
  new G4PVPlacement(0, G4ThreeVector(0, 0, radZ),
                    "Radiator", logicRadiator, physicsWorld, false, 0 );

  fRadiatorDescription->fLogicalVolume = logicRadiator;

  // create region for window inside windowR for

  G4Region* radRegion = new G4Region("XTRradiator");
  radRegion->AddRootLogicalVolume(logicRadiator);

  // Drift Electrode on both sides of Radiator:
  // (not placed)

  G4double zElectrode1 = radZ - radThick/2. - electrodeThick/2.;
  G4double zElectrode2 = radZ + radThick/2. + electrodeThick/2.;

  G4cout << "zElectrode1 = " << zElectrode1/mm << " mm" << G4endl;
  G4cout << "zElectrode2 = " << zElectrode2/mm << " mm" << G4endl;
  G4cout << "electrodeThick = " << electrodeThick/mm << " mm" << G4endl << G4endl;

  // Helium Pipe
  // (not placed)

  G4double pipeDist = 1.*cm;  //Distance between pipe and radiator / absorber
  G4double zPipe = zElectrode2 + electrodeThick/2. + pipeLength/2. + pipeDist/2.;

  G4cout << "zPipe = " << zPipe/mm << " mm" << G4endl;
  G4cout << "pipeLength = " << pipeLength/mm << " mm" << G4endl << G4endl;

  // Mylar Foil on both sides of helium pipe
  // (not placed)

  G4double zMylar1 = zPipe - pipeLength/2. - mylarThick/2 - 0.01*mm;
  G4double zMylar2 = zPipe + pipeLength/2. + mylarThick/2 + 0.01*mm;

  G4cout << "zMylar1 = " << zMylar1/mm << " mm" << G4endl;
  G4cout << "zMylar2 = " << zMylar2/mm << " mm" << G4endl;
  G4cout << "fMylarThick = " << mylarThick/mm << " mm" << G4endl << G4endl;
 
  // Mylar Foil on Chamber
  // (not placed)

  G4double zMylar = zElectrode2 + electrodeThick/2. + mylarThick/2. + 1.0*mm;
  zMylar += ( pipeLength + pipeDist );
 
  G4cout << "zMylar = " << zMylar/mm <<" mm" <<G4endl;
  G4cout << "mylarThick = " << mylarThick/mm << " mm" << G4endl << G4endl;

  // Absorber

  G4double absorberZ = zMylar + mylarThick/2. + absorberThickness/2.;

  G4VSolid* solidAbsorber 
    = new G4Box("Absorber", 10.*mm, 10.*mm, absorberThickness/2.);

  G4LogicalVolume* logicAbsorber 
    = new G4LogicalVolume(solidAbsorber, absorberMaterial, "Absorber");

  new G4PVPlacement(0, G4ThreeVector(0., 0., absorberZ),
                    "Absorber", logicAbsorber, physicsWorld, false, 0);

  // Create region for radiator

  G4Region* regGasDet = new G4Region("XTRdEdxDetector");
  regGasDet->AddRootLogicalVolume(logicAbsorber);

  // Sensitive Detectors: Absorber

  SensitiveDetector* sd = new SensitiveDetector("AbsorberSD");
  G4SDManager::GetSDMpointer()->AddNewDetector(sd );
  logicAbsorber->SetSensitiveDetector(sd);

  // Print geometry parameters

  G4cout << "\n The  WORLD   is made of "
         << worldSizeZ/mm << "mm of " << worldMaterial->GetName();
  G4cout << ", the transverse size (R) of the world is " 
         << worldSizeR/mm << " mm. " << G4endl;
  G4cout << " The ABSORBER is made of "
         << absorberThickness/mm << "mm of " << absorberMaterial->GetName();
  G4cout << ", the transverse size (R) is " 
         << absorberRadius/mm << " mm. " << G4endl;
  G4cout << " Z position of the (middle of the) absorber " 
         << absorberZ/mm << "  mm." << G4endl;

  G4cout << "radZ = " << radZ/mm << " mm" << G4endl;
  G4cout << "startZ = " << startZ/mm<< " mm" << G4endl;

  G4cout << "fRadThick = " << radThick/mm << " mm"<<G4endl;
  G4cout << "fFoilNumber = " << foilNumber << G4endl;
  G4cout << "fRadiatorMat = " << radiatorMat->GetName() << G4endl;
  G4cout << "WorldMaterial = " << worldMaterial->GetName() << G4endl;
  G4cout << G4endl;

  return physicsWorld;
}

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RadiatorDescription* DetectorBari05::GetRadiatorDescription ( ) const

inline

Definition at line 55 of file DetectorBari05.hh.

{ return fRadiatorDescription; }

---

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

• source/geant4.10.03.p03/examples/extended/electromagnetic/TestEm10/include/DetectorBari05.hh
• source/geant4.10.03.p03/examples/extended/electromagnetic/TestEm10/src/DetectorBari05.cc