Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4XTRGammaRadModel.hh
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1//
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25//
26//
27//
28///////////////////////////////////////////////////////////////////////////
29//
30// Rough model describing a gamma function distributed radiator of X-ray
31// transition radiation. XTR is considered to flux after radiator!
32// Thicknesses of plates and gas gaps are distributed according to gamma
33// distribution. x are thicknesses of plates or gas gaps:
34//
35// p(x) = (alpha/<x>)^alpha * x^(alpha-1) * std::exp(-alpha*x/<x>) / G(alpha)
36//
37// G(alpha) is Euler's gamma function.
38// Plates have mean <x> = fPlateThick > 0 and power alpha = fAlphaPlate > 0 :
39// Gas gaps have mean <x> = fGasThick > 0 and power alpha = fAlphaGas > 0 :
40// We suppose that:
41// formation zone ~ mean thickness << absorption length
42// for each material and in the range 1-100 keV. This allows us to simplify
43// interference effects in radiator stack (GetStackFactor method).
44//
45//
46// History:
47//
48// 03.10.05 V. Grichine, first version
49//
50
51#ifndef G4XTRGammaRadModel_h
52#define G4XTRGammaRadModel_h 1
53
54#include "G4VXTRenergyLoss.hh"
55
57{
58public:
59
60 explicit G4XTRGammaRadModel (G4LogicalVolume *anEnvelope,
64 const G4String & processName = "XTRgammaRadiator" );
65 virtual ~G4XTRGammaRadModel ();
66
67 // Pure virtual function from base class
68
70 G4double varAngle) override;
71
72private:
73
74 // G4double fAlphaPlate, fAlphaGas ;
75};
76
77#endif
double G4double
Definition: G4Types.hh:83
int G4int
Definition: G4Types.hh:85
G4double GetStackFactor(G4double energy, G4double gamma, G4double varAngle) override