Geant4-11
source
processes
hadronic
models
de_excitation
gem_evaporation
src
G4Na22GEMProbability.cc
Go to the documentation of this file.
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//
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// ********************************************************************
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// * License and Disclaimer *
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// * *
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// * The Geant4 software is copyright of the Copyright Holders of *
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// * the Geant4 Collaboration. It is provided under the terms and *
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// * conditions of the Geant4 Software License, included in the file *
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// * LICENSE and available at http://cern.ch/geant4/license . These *
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// * include a list of copyright holders. *
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// * *
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// * Neither the authors of this software system, nor their employing *
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// * institutes,nor the agencies providing financial support for this *
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// * work make any representation or warranty, express or implied, *
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// * regarding this software system or assume any liability for its *
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// * use. Please see the license in the file LICENSE and URL above *
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// * for the full disclaimer and the limitation of liability. *
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// * *
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// * This code implementation is the result of the scientific and *
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// * technical work of the GEANT4 collaboration. *
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// * By using, copying, modifying or distributing the software (or *
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// * any work based on the software) you agree to acknowledge its *
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// * use in resulting scientific publications, and indicate your *
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// * acceptance of all terms of the Geant4 Software license. *
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// ********************************************************************
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//
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//
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// Hadronic Process: Nuclear De-excitations
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// by V. Lara (Nov 1999)
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//
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#include "
G4Na22GEMProbability.hh
"
32
#include "
G4SystemOfUnits.hh
"
33
34
G4Na22GEMProbability::G4Na22GEMProbability
() :
35
G4GEMProbability
(22,11,3.0)
// A,Z,Spin
36
{
37
38
ExcitEnergies
.push_back(583.11*
keV
);
39
ExcitSpins
.push_back(1.0);
40
ExcitLifetimes
.push_back(244.0e-3*
picosecond
);
41
42
ExcitEnergies
.push_back(657.16*
keV
);
43
ExcitSpins
.push_back(0.0);
44
ExcitLifetimes
.push_back(14.0*
picosecond
);
45
46
ExcitEnergies
.push_back(890.81*
keV
);
47
ExcitSpins
.push_back(4.0);
48
ExcitLifetimes
.push_back(10.4*
picosecond
);
49
50
ExcitEnergies
.push_back(1528.14*
keV
);
51
ExcitSpins
.push_back(5.0);
52
ExcitLifetimes
.push_back(3.40*
picosecond
);
53
54
ExcitEnergies
.push_back(1936.45*
keV
);
55
ExcitSpins
.push_back(1.0);
56
ExcitLifetimes
.push_back(3.0e-3*
picosecond
);
57
58
ExcitEnergies
.push_back(1952.13*
keV
);
59
ExcitSpins
.push_back(2.0);
60
ExcitLifetimes
.push_back(6.0e-3*
picosecond
);
61
62
ExcitEnergies
.push_back(1983.8*
keV
);
63
ExcitSpins
.push_back(3.0);
64
ExcitLifetimes
.push_back(1.59*
picosecond
);
65
66
ExcitEnergies
.push_back(2211.5*
keV
);
67
ExcitSpins
.push_back(1.0);
68
ExcitLifetimes
.push_back(14.9*
picosecond
);
69
70
ExcitEnergies
.push_back(2571.5*
keV
);
71
ExcitSpins
.push_back(2.0);
72
ExcitLifetimes
.push_back(5.6*
picosecond
);
73
74
ExcitEnergies
.push_back(2968.7*
keV
);
75
ExcitSpins
.push_back(3.0);
76
ExcitLifetimes
.push_back(42.0e-3*
picosecond
);
77
78
ExcitEnergies
.push_back(3059.6*
keV
);
79
ExcitSpins
.push_back(2.0);
80
ExcitLifetimes
.push_back(28.0e-3*
picosecond
);
81
82
ExcitEnergies
.push_back(3519.2*
keV
);
83
ExcitSpins
.push_back(3.0);
84
ExcitLifetimes
.push_back(464.0e-3*
picosecond
);
85
86
ExcitEnergies
.push_back(3706.6*
keV
);
87
ExcitSpins
.push_back(6.0);
88
ExcitLifetimes
.push_back(76.0e-3*
picosecond
);
89
90
ExcitEnergies
.push_back(3943.5*
keV
);
91
ExcitSpins
.push_back(1.0);
92
ExcitLifetimes
.push_back(6.0e-3*
picosecond
);
93
94
ExcitEnergies
.push_back(4071.3*
keV
);
95
ExcitSpins
.push_back(4.0);
96
ExcitLifetimes
.push_back(3.0e-3*
picosecond
);
97
98
ExcitEnergies
.push_back(4296.1*
keV
);
99
ExcitSpins
.push_back(0.0);
100
ExcitLifetimes
.push_back(3.5*
picosecond
);
101
102
ExcitEnergies
.push_back(4319.0*
keV
);
103
ExcitSpins
.push_back(1.0);
104
ExcitLifetimes
.push_back(30.0e-3*
picosecond
);
105
106
ExcitEnergies
.push_back(4360.0*
keV
);
107
ExcitSpins
.push_back(2.0);
108
ExcitLifetimes
.push_back(11.0e-3*
picosecond
);
109
110
ExcitEnergies
.push_back(4468.3*
keV
);
111
ExcitSpins
.push_back(4.0);
112
ExcitLifetimes
.push_back(104.0e-3*
picosecond
);
113
114
ExcitEnergies
.push_back(4523.8*
keV
);
115
ExcitSpins
.push_back(7.0);
116
ExcitLifetimes
.push_back(69.0e-3*
picosecond
);
117
118
ExcitEnergies
.push_back(4582.8*
keV
);
119
ExcitSpins
.push_back(2.0);
120
ExcitLifetimes
.push_back(69.0e-3*
picosecond
);
121
122
ExcitEnergies
.push_back(4621.7*
keV
);
123
ExcitSpins
.push_back(1.0);
124
ExcitLifetimes
.push_back(69.0e-3*
picosecond
);
125
126
ExcitEnergies
.push_back(4710.0*
keV
);
127
ExcitSpins
.push_back(5.0);
128
ExcitLifetimes
.push_back(42.0e-3*
picosecond
);
129
130
ExcitEnergies
.push_back(4771.0*
keV
);
131
ExcitSpins
.push_back(3.0);
132
ExcitLifetimes
.push_back(69.0*
picosecond
);
133
134
ExcitEnergies
.push_back(5062.4*
keV
);
135
ExcitSpins
.push_back(2.0);
136
ExcitLifetimes
.push_back(14.0e-3*
picosecond
);
137
138
ExcitEnergies
.push_back(5100.6*
keV
);
139
ExcitSpins
.push_back(4.0);
140
ExcitLifetimes
.push_back(38.0e-3*
picosecond
);
141
142
ExcitEnergies
.push_back(5167.0*
keV
);
143
ExcitSpins
.push_back(1.0);
144
ExcitLifetimes
.push_back(69.0*
picosecond
);
145
146
147
ExcitEnergies
.push_back(7153.0*
keV
);
148
ExcitSpins
.push_back(3.0);
149
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
150
151
ExcitEnergies
.push_back(7221.0*
keV
);
152
ExcitSpins
.push_back(2.0);
153
ExcitLifetimes
.push_back(
fPlanck
/(0.4*
keV
));
154
155
ExcitEnergies
.push_back(7241.0*
keV
);
156
ExcitSpins
.push_back(2.0);
157
ExcitLifetimes
.push_back(
fPlanck
/(0.3*
keV
));
158
159
ExcitEnergies
.push_back(7279.0*
keV
);
160
ExcitSpins
.push_back(1.0);
161
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
162
163
ExcitEnergies
.push_back(7280.0*
keV
);
164
ExcitSpins
.push_back(4.0);
165
ExcitLifetimes
.push_back(
fPlanck
/(1.5*
keV
));
166
167
ExcitEnergies
.push_back(7361.0*
keV
);
168
ExcitSpins
.push_back(3.0);
169
ExcitLifetimes
.push_back(
fPlanck
/(1.0*
keV
));
170
171
ExcitEnergies
.push_back(7373.0*
keV
);
172
ExcitSpins
.push_back(2.0);
173
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
174
175
ExcitEnergies
.push_back(7379.2*
keV
);
176
ExcitSpins
.push_back(2.0);
177
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
178
179
ExcitEnergies
.push_back(7402.0*
keV
);
180
ExcitSpins
.push_back(1.0);
181
ExcitLifetimes
.push_back(
fPlanck
/(1.5*
keV
));
182
183
ExcitEnergies
.push_back(7409.6*
keV
);
184
ExcitSpins
.push_back(1.0);
185
ExcitLifetimes
.push_back(
fPlanck
/(3.5*
keV
));
186
187
ExcitEnergies
.push_back(7472.6*
keV
);
188
ExcitSpins
.push_back(2.0);
189
ExcitLifetimes
.push_back(
fPlanck
/(3.5*
keV
));
190
191
ExcitEnergies
.push_back(7516.2*
keV
);
192
ExcitSpins
.push_back(3.0);
193
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
194
195
ExcitEnergies
.push_back(7547.9*
keV
);
196
ExcitSpins
.push_back(2.0);
197
ExcitLifetimes
.push_back(
fPlanck
/(0.6*
keV
));
198
199
ExcitEnergies
.push_back(7574.4*
keV
);
200
ExcitSpins
.push_back(5.0);
201
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
202
203
ExcitEnergies
.push_back(7600.0*
keV
);
204
ExcitSpins
.push_back(2.0);
205
ExcitLifetimes
.push_back(
fPlanck
/(1.9*
keV
));
206
207
ExcitEnergies
.push_back(7606.0*
keV
);
208
ExcitSpins
.push_back(1.0);
209
ExcitLifetimes
.push_back(
fPlanck
/(0.6*
keV
));
210
211
ExcitEnergies
.push_back(7637.0*
keV
);
212
ExcitSpins
.push_back(2.0);
213
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
214
215
ExcitEnergies
.push_back(7684.0*
keV
);
216
ExcitSpins
.push_back(2.0);
217
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
218
219
ExcitEnergies
.push_back(7779.0*
keV
);
220
ExcitSpins
.push_back(1.0);
221
ExcitLifetimes
.push_back(
fPlanck
/(2.8*
keV
));
222
223
ExcitEnergies
.push_back(7801.5*
keV
);
224
ExcitSpins
.push_back(1.0);
225
ExcitLifetimes
.push_back(
fPlanck
/(2.4*
keV
));
226
227
ExcitEnergies
.push_back(7821.9*
keV
);
228
ExcitSpins
.push_back(1.0);
229
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
230
231
ExcitEnergies
.push_back(7890.0*
keV
);
232
ExcitSpins
.push_back(3.0);
233
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
234
235
ExcitEnergies
.push_back(7920.0*
keV
);
236
ExcitSpins
.push_back(2.0);
237
ExcitLifetimes
.push_back(
fPlanck
/(17.0*
keV
));
238
239
ExcitEnergies
.push_back(7978.0*
keV
);
240
ExcitSpins
.push_back(1.0);
241
ExcitLifetimes
.push_back(
fPlanck
/(10.0*
keV
));
242
243
ExcitEnergies
.push_back(8019.0*
keV
);
244
ExcitSpins
.push_back(4.0);
245
ExcitLifetimes
.push_back(
fPlanck
/(1.0*
keV
));
246
247
ExcitEnergies
.push_back(8041.0*
keV
);
248
ExcitSpins
.push_back(2.0);
249
ExcitLifetimes
.push_back(
fPlanck
/(0.5*
keV
));
250
251
ExcitEnergies
.push_back(8102.0*
keV
);
252
ExcitSpins
.push_back(1.0);
253
ExcitLifetimes
.push_back(
fPlanck
/(3.8*
keV
));
254
255
ExcitEnergies
.push_back(8108.0*
keV
);
256
ExcitSpins
.push_back(3.0);
257
ExcitLifetimes
.push_back(
fPlanck
/(1.5*
keV
));
258
259
ExcitEnergies
.push_back(8115.0*
keV
);
260
ExcitSpins
.push_back(3.0);
261
ExcitLifetimes
.push_back(
fPlanck
/(3.1*
keV
));
262
263
ExcitEnergies
.push_back(8166.0*
keV
);
264
ExcitSpins
.push_back(3.0);
265
ExcitLifetimes
.push_back(
fPlanck
/(22.5*
keV
));
266
267
ExcitEnergies
.push_back(8198.0*
keV
);
268
ExcitSpins
.push_back(2.0);
269
ExcitLifetimes
.push_back(
fPlanck
/(0.6*
keV
));
270
271
ExcitEnergies
.push_back(8212.0*
keV
);
272
ExcitSpins
.push_back(1.0);
273
ExcitLifetimes
.push_back(
fPlanck
/(5.1*
keV
));
274
275
ExcitEnergies
.push_back(8234.0*
keV
);
276
ExcitSpins
.push_back(1.0);
277
ExcitLifetimes
.push_back(
fPlanck
/(11.0*
keV
));
278
279
ExcitEnergies
.push_back(8288.0*
keV
);
280
ExcitSpins
.push_back(0.0);
281
ExcitLifetimes
.push_back(
fPlanck
/(4.5*
keV
));
282
283
ExcitEnergies
.push_back(8329.0*
keV
);
284
ExcitSpins
.push_back(0.0);
285
ExcitLifetimes
.push_back(
fPlanck
/(2.7*
keV
));
286
287
ExcitEnergies
.push_back(8436.0*
keV
);
288
ExcitSpins
.push_back(0.0);
289
ExcitLifetimes
.push_back(
fPlanck
/(5.4*
keV
));
290
291
ExcitEnergies
.push_back(8497.0*
keV
);
292
ExcitSpins
.push_back(1.0);
293
ExcitLifetimes
.push_back(
fPlanck
/(44.0*
keV
));
294
295
ExcitEnergies
.push_back(8538.0*
keV
);
296
ExcitSpins
.push_back(0.0);
297
ExcitLifetimes
.push_back(
fPlanck
/(13.2*
keV
));
298
299
ExcitEnergies
.push_back(8602.0*
keV
);
300
ExcitSpins
.push_back(0.0);
301
ExcitLifetimes
.push_back(
fPlanck
/(11.2*
keV
));
302
303
ExcitEnergies
.push_back(8637.0*
keV
);
304
ExcitSpins
.push_back(0.0);
305
ExcitLifetimes
.push_back(
fPlanck
/(11.0*
keV
));
306
307
}
308
309
G4Na22GEMProbability::~G4Na22GEMProbability
()
310
{}
G4Na22GEMProbability.hh
keV
static constexpr double keV
Definition:
G4SIunits.hh:202
picosecond
static constexpr double picosecond
Definition:
G4SIunits.hh:141
G4SystemOfUnits.hh
G4GEMProbability
Definition:
G4GEMProbability.hh:54
G4GEMProbability::ExcitSpins
std::vector< G4double > ExcitSpins
Definition:
G4GEMProbability.hh:117
G4GEMProbability::ExcitEnergies
std::vector< G4double > ExcitEnergies
Definition:
G4GEMProbability.hh:114
G4GEMProbability::fPlanck
G4double fPlanck
Definition:
G4GEMProbability.hh:111
G4GEMProbability::ExcitLifetimes
std::vector< G4double > ExcitLifetimes
Definition:
G4GEMProbability.hh:120
G4Na22GEMProbability::G4Na22GEMProbability
G4Na22GEMProbability()
Definition:
G4Na22GEMProbability.cc:34
G4Na22GEMProbability::~G4Na22GEMProbability
~G4Na22GEMProbability()
Definition:
G4Na22GEMProbability.cc:309
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