Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4KalbachCrossSection.cc
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28// V.Ivanchenko 26.02.2018
29//
30
32#include "G4Exp.hh"
33#include "G4Pow.hh"
34
35//from subroutine sigpar of PRECO-2000 by Constance Kalbach Walker
36// Calculate optical model reaction cross sections
37// using the empirical parameterization
38// of Narasimha Murthy, Chaterjee, and Gupta
39// going over to the geometrical limit at high energy.
40//
41// Proton cross sections scaled down with signor for a<100
42// (appropriate for becchetti-greenlees potential).
43// p2 reduced and global red'n factor introduced below Bc
44// Neutron cross sections scaled down with signor for a<40
45// Scaled up for A>210 (added June '98 to conform with
46// my published papers)
47// (appropriate for Mani et al potential)
48//
49
50// index: 0-neutron, 1-proton, 2-deuteron, 3-triton, 4-He3, 5-He4
51// parameters: p0, p1, p2, lambda0, lambda1, mu0, mu1, nu0, nu1, nu2, ra
52
53static const G4double paramK[6][11] = {
54 // n from mani, melkanoff and iori
55 {-312., 0., 0., 12.10, -11.27, 234.1, 38.26, 1.55, -106.1, 1280.8, 0.0},
56 // p from becchetti and greenlees (but modified with sub-barrier
57 // correction function and p2 changed from -449)
58 {15.72, 9.65, -300., 0.00437,-16.58, 244.7, 0.503, 273.1, -182.4, -1.872, 0.0},
59 // d from o.m. of perey and perey
60 {0.798, 420.3,-1651., 0.00619, -7.54, 583.5, 0.337, 421.8, -474.5, -3.592, 0.8},
61 // t from o.m. of hafele, flynn et al
62 {-21.45,484.7,-1608., 0.0186, -8.9, 686.3, 0.325, 368.9, -522.2, -4.998, 0.8},
63 // 3he from o.m. of gibson et al
64 {-2.88,205.6, -1487.,0.00459,-8.93, 611.2, 0.35 , 473.8, -468.2, -2.225, 0.8},
65 // alpha from huizenga and igo
66 { 10.95,-85.2, 1146., 0.0643,-13.96, 781.2, 0.29, -304.7,-470.0, -8.580, 1.2}
67};
68
70{
71 return G4Pow::GetInstance()->powZ(resA, paramK[idx][6]);
72}
73
76 G4double resA13, G4double amu1,
77 G4int idx, G4int Z, G4int A,
78 G4int resA)
79{
80 G4double sig = 0.0;
81 G4double signor = 1.0;
82 G4double lambda, mu, nu;
83 G4double ec = 0.5;
84 if(0 < Z) { ec = cb; }
85 //JMQ 13.02.2009 tuning for improving cluster emission ddxs
86 // (spallation benchmark)
87 /*
88 G4double xx = 1.7;
89 if(1 == A) { xx = 1.5; }
90 ec = 1.44 * Z * resZ / (xx*resA13 + paramK[idx][10]);
91 }
92 */
93 G4double ecsq = ec*ec;
94 G4double elab = K * (A + resA) / G4double(resA);
95
96 if(idx == 0) { // parameterization for neutron
97
98 if(resA < 40) { signor =0.7 + resA*0.0075; }
99 else if(resA > 210) { signor = 1. + (resA-210)*0.004; }
100 lambda = paramK[idx][3]/resA13 + paramK[idx][4];
101 mu = (paramK[idx][5] + paramK[idx][6]*resA13)*resA13;
102 // JMQ 20.11.2008 very low energy behaviour corrected
103 // (problem for A (apprx.)>60) fix for avoiding
104 // neutron xs going to zero at very low energies
105 nu = std::abs((paramK[idx][7]*resA + paramK[idx][8]*resA13)*resA13
106 + paramK[idx][9]);
107
108 } else { // parameterization for charged
109 // proton correction
110 if(idx == 1) {
111 if (resA <= 60) { signor = 0.92; }
112 else if (resA < 100) { signor = 0.8 + resA*0.002; }
113 }
114 lambda = paramK[idx][3]*resA + paramK[idx][4];
115 mu = paramK[idx][5]*amu1;
116 nu = amu1* (paramK[idx][7] + paramK[idx][8]*ec + paramK[idx][9]*ecsq);
117 }
118 /*
119 G4cout << "## idx= " << idx << " K= " << K << " elab= " << elab << " ec= " << ec
120 << " lambda= " << lambda << " mu= " << mu << " nu= " << nu << G4endl;
121 */
122 // threashold cross section
123 if(elab < ec) {
124 G4double p = paramK[idx][0];
125 if(0 < Z) { p += paramK[idx][1]/ec + paramK[idx][2]/ecsq; }
126 G4double a = -2*p*ec + lambda - nu/ecsq;
127 G4double b = p*ecsq + mu + 2*nu/ec;
128 G4double ecut;
129 G4double det = a*a - 4*p*b;
130 if (det > 0.0) { ecut = (std::sqrt(det) - a)/(2*p); }
131 else { ecut = -a/(2*p); }
132
133 //G4cout << " elab= " << elab << " ecut= " << ecut << " sig= " << sig
134 // << " sig1= " << (p*elab*elab + a*elab + b)*signor << G4endl;
135 // If ecut>0, sig=0 at elab=ecut
136 if(0 == idx) {
137 sig = (lambda*ec + mu + nu/ec)*signor*std::sqrt(elab/ec);
138 } else if(elab >= ecut) {
139 sig = (p*elab*elab + a*elab + b)*signor;
140
141 // extra proton correction
142 if(1 == idx) {
143 // c and w are for global correction factor for
144 // they are scaled down for light targets where ec is low.
145 G4double cc = std::min(3.15, ec*0.5);
146 G4double signor2 = (ec - elab - cc) *3.15/ (0.7*cc);
147 sig /= (1. + G4Exp(signor2));
148 }
149 }
150 //G4cout << " ecut= " << ecut << " a= " << a << " b= " << b
151 // << " signor= " << signor << " sig= " << sig << G4endl;
152
153 // high energy cross section
154 } else {
155 // etest is the energy above which the rxn cross section is
156 // compared with the geometrical limit and the max taken.
157
158 // neutron parameters
159 G4double etest = 32.;
160 G4double xnulam = 1.0;
161
162 // parameters for charged
163 static const G4double flow = 1.e-18;
164 static const G4double spill= 1.e+18;
165 if(0 < Z) {
166 etest = 0.0;
167 xnulam = nu / lambda;
168 xnulam = std::min(xnulam, spill);
169 if (xnulam >= flow) {
170 if(1 == idx) { etest = std::sqrt(xnulam) + 7.; }
171 else { etest = 1.2 *std::sqrt(xnulam); }
172 }
173 }
174 // ** For xnulam.gt.0, sig reaches a maximum at sqrt(xnulam).
175 sig = (lambda*elab + mu + nu/elab)*signor;
176 if (xnulam >= flow && elab >= etest) {
177 G4double geom = std::sqrt(A*K);
178 geom = 1.23*resA13 + paramK[idx][10] + 4.573/geom;
179 geom = 31.416 * geom * geom;
180 sig = std::max(sig, geom);
181 }
182 }
183 sig = std::max(sig, 0.0);
184 //G4cout << " ---- sig= " << sig << G4endl;
185 return sig;
186}
double A(double temperature)
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
Definition: G4Exp.hh:179
double G4double
Definition: G4Types.hh:83
int G4int
Definition: G4Types.hh:85
static G4double ComputePowerParameter(G4int resA, G4int idx)
static G4double ComputeCrossSection(G4double K, G4double cb, G4double resA13, G4double amu1, G4int idx, G4int Z, G4int A, G4int resA)
static G4Pow * GetInstance()
Definition: G4Pow.cc:41
G4double powZ(G4int Z, G4double y) const
Definition: G4Pow.hh:225