Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
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G4XTRRegularRadModel.cc
Go to the documentation of this file.
1//
2// ********************************************************************
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18// * This code implementation is the result of the scientific and *
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24// ********************************************************************
25//
26
28
30
31////////////////////////////////////////////////////////////////////////////
32// Constructor, destructor
34 G4Material* foilMat,
35 G4Material* gasMat, G4double a,
36 G4double b, G4int n,
37 const G4String& processName)
38 : G4VXTRenergyLoss(anEnvelope, foilMat, gasMat, a, b, n, processName)
39{
40 G4cout << " XTR Regular discrete radiator model is called" << G4endl;
41
42 fExitFlux = true;
43}
44
45///////////////////////////////////////////////////////////////////////////
47
48///////////////////////////////////////////////////////////////////////////
49void G4XTRRegularRadModel::ProcessDescription(std::ostream& out) const
50{
51 out << "Describes X-ray transition radiation with thickness of gaps and "
52 "plates\n"
53 "fixed.\n";
54}
55
56///////////////////////////////////////////////////////////////////////////
58{
59 static constexpr G4double cofPHC = 4. * pi * hbarc;
60 G4double result, sum = 0., tmp, cof1, cof2, cofMin, theta2, theta2k;
61 G4double aMa, bMb, sigma, dump;
62 G4int k, kMax, kMin;
63
64 aMa = fPlateThick * GetPlateLinearPhotoAbs(energy);
65 bMb = fGasThick * GetGasLinearPhotoAbs(energy);
66 sigma = 0.5 * (aMa + bMb);
67 dump = std::exp(-fPlateNumber * sigma);
68 if(verboseLevel > 2)
69 G4cout << " dump = " << dump << G4endl;
70 tmp = (fSigma1 - fSigma2) / cofPHC / energy;
71 cof1 = fPlateThick * tmp;
72 cof2 = fGasThick * tmp;
73
74 cofMin = energy * (fPlateThick + fGasThick) / fGamma / fGamma;
75 cofMin += (fPlateThick * fSigma1 + fGasThick * fSigma2) / energy;
76 cofMin /= cofPHC;
77
78 theta2 = cofPHC / (energy * (fPlateThick + fGasThick));
79
80 kMin = G4int(cofMin);
81 if(cofMin > kMin)
82 kMin++;
83
84 kMax = kMin + 49;
85
86 if(verboseLevel > 2)
87 {
88 G4cout << cof1 << " " << cof2 << " " << cofMin << G4endl;
89 G4cout << "kMin = " << kMin << "; kMax = " << kMax << G4endl;
90 }
91 for(k = kMin; k <= kMax; ++k)
92 {
93 tmp = pi * fPlateThick * (k + cof2) / (fPlateThick + fGasThick);
94 result = (k - cof1) * (k - cof1) * (k + cof2) * (k + cof2);
95 if(k == kMin && kMin == G4int(cofMin))
96 {
97 sum +=
98 0.5 * std::sin(tmp) * std::sin(tmp) * std::abs(k - cofMin) / result;
99 }
100 else
101 {
102 sum += std::sin(tmp) * std::sin(tmp) * std::abs(k - cofMin) / result;
103 }
104 theta2k = std::sqrt(theta2 * std::abs(k - cofMin));
105
106 if(verboseLevel > 2)
107 {
108 G4cout << k << " " << theta2k << " "
109 << std::sin(tmp) * std::sin(tmp) * std::abs(k - cofMin) / result
110 << " " << sum << G4endl;
111 }
112 }
113 result = 2 * (cof1 + cof2) * (cof1 + cof2) * sum / energy;
114 result *= dump * (-1 + dump + 2 * fPlateNumber);
115
116 return result;
117}
118
119///////////////////////////////////////////////////////////////////////////
120// Approximation for radiator interference factor for the case of
121// fully Regular radiator. The plate and gas gap thicknesses are fixed.
122// The mean values of the plate and gas gap thicknesses
123// are supposed to be about XTR formation zones but much less than
124// mean absorption length of XTR photons in corresponding material.
126 G4double varAngle)
127{
128 G4double aZa = fPlateThick / GetPlateFormationZone(energy, gamma, varAngle);
129 G4double bZb = fGasThick / GetGasFormationZone(energy, gamma, varAngle);
130
133
134 G4double Qa = std::exp(-aMa);
135 G4double Qb = std::exp(-bMb);
136 G4double Q = Qa * Qb;
137
138 G4complex Ha(std::exp(-0.5 * aMa) * std::cos(aZa),
139 -std::exp(-0.5 * aMa) * std::sin(aZa));
140
141 G4complex Hb(std::exp(-0.5 * bMb) * std::cos(bZb),
142 -std::exp(-0.5 * bMb) * std::sin(bZb));
143
144 G4complex H = Ha * Hb;
145 G4complex Hs = std::conj(H);
146
147 G4complex F2 = (1.0 - Ha) * (Qa - Ha) * Hb * (1.0 - Hs) * (Q - Hs);
148 F2 *= std::pow(Q, G4double(fPlateNumber)) - std::pow(H, fPlateNumber);
149
150 G4double result = (1. - std::pow(Q, G4double(fPlateNumber))) / (1. - Q);
151 result *= (1. - Qa) * (1. + Qa - 2. * std::sqrt(Qa) * std::cos(aZa));
152 result /= (1. - std::sqrt(Q)) * (1. - std::sqrt(Q)) +
153 4. * std::sqrt(Q) * std::sin(0.5 * (aZa + bZb)) *
154 std::sin(0.5 * (aZa + bZb));
155
156 G4double I2 = 1.;
157 I2 /= (1. - std::sqrt(Q)) * (1. - std::sqrt(Q)) +
158 4. * std::sqrt(Q) * std::sin(0.5 * (aZa + bZb)) *
159 std::sin(0.5 * (aZa + bZb));
160
161 I2 /= Q * ((std::sqrt(Q) - std::cos(aZa + bZb)) *
162 (std::sqrt(Q) - std::cos(aZa + bZb)) +
163 std::sin(aZa + bZb) * std::sin(aZa + bZb));
164
165 G4complex stack = 2. * I2 * F2;
166 stack += result;
167 stack *= OneInterfaceXTRdEdx(energy, gamma, varAngle);
168
169 return std::real(stack);
170}
double G4double
Definition: G4Types.hh:83
std::complex< G4double > G4complex
Definition: G4Types.hh:88
int G4int
Definition: G4Types.hh:85
#define G4endl
Definition: G4ios.hh:57
G4GLOB_DLL std::ostream G4cout
G4int verboseLevel
Definition: G4VProcess.hh:360
G4double GetPlateLinearPhotoAbs(G4double)
G4double GetGasFormationZone(G4double, G4double, G4double)
G4complex OneInterfaceXTRdEdx(G4double energy, G4double gamma, G4double varAngle)
G4double GetPlateFormationZone(G4double, G4double, G4double)
G4double GetGasLinearPhotoAbs(G4double)
G4double SpectralXTRdEdx(G4double energy) override
void ProcessDescription(std::ostream &) const override
G4XTRRegularRadModel(G4LogicalVolume *anEnvelope, G4Material *, G4Material *, G4double, G4double, G4int, const G4String &processName="XTRegularModel")
G4double GetStackFactor(G4double energy, G4double gamma, G4double varAngle) override