G4GammaXTRadiator.hh

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//
//
// Rough process describing a radiator of X-ray transition radiation.
// Thicknesses of plates and gas gaps are distributed according to gamma
// distribution. x are thicknesses of plates or gas gaps:
//
// p(x) = (alpha/<x>)^alpha * x^(alpha-1) * std::exp(-alpha*x/<x>) / G(alpha)
//
// G(alpha) is Euler's gamma function.
// Plates have mean <x> = fPlateThick > 0 and power alpha = fAlphaPlate > 0 :
// Gas gaps have mean <x> = fGasThick > 0 and power alpha = fAlphaGas > 0 :
// We suppose that:
// formation zone ~ mean thickness << absorption length
// for each material and in the range 1-100 keV. This allows us to simplify
// interference effects in radiator stack (GetStackFactor method).
//
// History:
// 21.01.02 V. Grichine, first version
//
 
#ifndef G4GammaXTRadiator_h
#define G4GammaXTRadiator_h 1
 
#include "G4LogicalVolume.hh"
#include "G4Material.hh"
#include "G4VXTRenergyLoss.hh"
 
class G4GammaXTRadiator : public G4VXTRenergyLoss
{
 public:
  explicit G4GammaXTRadiator(G4LogicalVolume* anEnvelope, G4double, G4double,
                             G4Material*, G4Material*, G4double, G4double,
                             G4int,
                             const G4String& processName = "XTRgammaRadiator");
  ~G4GammaXTRadiator();
 
  void ProcessDescription(std::ostream&) const override;
  void DumpInfo() const override { ProcessDescription(G4cout); };
 
  G4double GetStackFactor(G4double energy, G4double gamma,
                          G4double varAngle) override;
};
 
#endif