| Geant4 Cross Reference |
1 Environment variable "G4FORCE_RUN_MANAGER_TYPE <<
2 1
3 ###################################### << 2 *************************************************************
4 !!! WARNING - FPE detection is activat << 3 Geant4 version Name: geant4-09-00-patch-01-ref (28-August-2007)
5 ###################################### << 4 Copyright : Geant4 Collaboration
6 << 5 Reference : NIM A 506 (2003), 250-303
7 << 6 WWW : http://cern.ch/geant4
8 ################################ << 7 *************************************************************
9 !!! G4Backtrace is activated !!! << 8
10 ################################ << 9 B01PhysicsList::SetCuts:CutLength : 1 (mm)
11 <<
12 <<
13 ********************************************** <<
14 Geant4 version Name: geant4-11-03-ref-00 ( <<
15 Copyright : Geant4 Coll <<
16 References : NIM A 506 ( <<
17 : IEEE-TNS 53 <<
18 : NIM A 835 ( <<
19 WWW : http://gean <<
20 ********************************************** <<
21 <<
22 <<< Geant4 Physics List simulation engine: FTF <<
23 <<
24 <<
25 hInelastic FTFP_BERT : threshold between BERT <<
26 for pions : 3 to 6 GeV <<
27 for kaons : 3 to 6 GeV <<
28 for proton : 3 to 6 GeV <<
29 for neutron : 3 to 6 GeV <<
30 <<
31 ### Adding tracking cuts for neutron TimeCut( <<
32 paraFlag: 0 <<
33 Preparing Importance Sampling <<
34 G4IStore:: Creating new MASS IStore <<
35 G4GeometrySampler:: preparing importance sampl <<
36 G4ImportanceConfigurator:: setting world name <<
37 G4ImportanceConfigurator:: entering importance <<
38 ### G4ImportanceProcess:: Creating <<
39 G4ImportanceProcess:: importance process paraf <<
40 === G4ProcessPlacer::AddProcessAsSecondDoIt: f <<
41 Modifying Process Order for ProcessName: Imp <<
42 The initial AlongStep Vectors: <<
43 GPIL Vector: <<
44 Transportation <<
45 DoIt Vector: <<
46 Transportation <<
47 The initial PostStep Vectors: <<
48 GPIL Vector: <<
49 nKiller <<
50 nCapture <<
51 neutronInelastic <<
52 hadElastic <<
53 Decay <<
54 Transportation <<
55 DoIt Vector: <<
56 Transportation <<
57 Decay <<
58 hadElastic <<
59 neutronInelastic <<
60 nCapture <<
61 nKiller <<
62 The final AlongStep Vectors: <<
63 GPIL Vector: <<
64 ImportanceProcess <<
65 Transportation <<
66 DoIt Vector: <<
67 Transportation <<
68 ImportanceProcess <<
69 The final PostStep Vectors: <<
70 GPIL Vector: <<
71 nKiller <<
72 nCapture <<
73 neutronInelastic <<
74 hadElastic <<
75 Decay <<
76 ImportanceProcess <<
77 Transportation <<
78 DoIt Vector: <<
79 Transportation <<
80 ImportanceProcess <<
81 Decay <<
82 hadElastic <<
83 neutronInelastic <<
84 nCapture <<
85 nKiller <<
86 ============================================== <<
87 B01DetectorConstruction:: Creating Importance <<
88 Going to assign importance: 1, to volume: cell 10 Going to assign importance: 1, to volume: cell_01
89 Going to assign importance: 2, to volume: cell 11 Going to assign importance: 2, to volume: cell_02
90 Going to assign importance: 4, to volume: cell 12 Going to assign importance: 4, to volume: cell_03
91 Going to assign importance: 8, to volume: cell 13 Going to assign importance: 8, to volume: cell_04
92 Going to assign importance: 16, to volume: cel 14 Going to assign importance: 16, to volume: cell_05
93 Going to assign importance: 32, to volume: cel 15 Going to assign importance: 32, to volume: cell_06
94 Going to assign importance: 64, to volume: cel 16 Going to assign importance: 64, to volume: cell_07
95 Going to assign importance: 128, to volume: ce 17 Going to assign importance: 128, to volume: cell_08
96 Going to assign importance: 256, to volume: ce 18 Going to assign importance: 256, to volume: cell_09
97 Going to assign importance: 512, to volume: ce 19 Going to assign importance: 512, to volume: cell_10
98 Going to assign importance: 1024, to volume: c 20 Going to assign importance: 1024, to volume: cell_11
99 Going to assign importance: 2048, to volume: c 21 Going to assign importance: 2048, to volume: cell_12
100 Going to assign importance: 4096, to volume: c 22 Going to assign importance: 4096, to volume: cell_13
101 Going to assign importance: 8192, to volume: c 23 Going to assign importance: 8192, to volume: cell_14
102 Going to assign importance: 16384, to volume: 24 Going to assign importance: 16384, to volume: cell_15
103 Going to assign importance: 32768, to volume: 25 Going to assign importance: 32768, to volume: cell_16
104 Going to assign importance: 65536, to volume: 26 Going to assign importance: 65536, to volume: cell_17
105 Going to assign importance: 131072, to volume: 27 Going to assign importance: 131072, to volume: cell_18
106 ============================================== << 28 preparing importance sampling
107 ====== Electromagnetic Physics << 29 creating istore
108 ============================================== << 30 creating importance configurator
109 LPM effect enabled << 31 entering configure
110 Enable creation and use of sampling tables << 32 importance configurator push_back
111 Apply cuts on all EM processes << 33 pushed
112 Use combined TransportationWithMsc << 34 vsampler configurator loop
113 Use general process << 35 looping 1
114 Enable linear polarisation for gamma << 36 sampler configurator
115 Enable photoeffect sampling below K-shell << 37 entering importance configure, paraflag 0
116 Enable sampling of quantum entanglement << 38 creating importance process, paraflag is: 0
117 X-section factor for integral approach << 39 importance process paraflag is: 0
118 Min kinetic energy for tables << 40 === G4ProcessPlacer::AddProcessAsSecondDoIt: for: neutron
119 Max kinetic energy for tables << 41 ProcessName: ImportanceProcess
120 Number of bins per decade of a table << 42 The initial Vectors:
121 Verbose level << 43 GPIL Vector:
122 Verbose level for worker thread << 44 Decay
123 Bremsstrahlung energy threshold above which << 45 HadronCapture
124 primary e+- is added to the list of secondar << 46 HadronFission
125 Bremsstrahlung energy threshold above which pr << 47 inelastic
126 muon/hadron is added to the list of secondar << 48 HadronElastic
127 Positron annihilation at rest model << 49 Transportation
128 Enable 3 gamma annihilation on fly << 50 DoIt Vector:
129 Lowest triplet kinetic energy << 51 Transportation
130 Enable sampling of gamma linear polarisation << 52 HadronElastic
131 5D gamma conversion model type << 53 inelastic
132 5D gamma conversion model on isolated ion << 54 HadronFission
133 Use Ricardo-Gerardo pair production model << 55 HadronCapture
134 Livermore data directory << 56 Decay
135 ============================================== << 57 The final Vectors:
136 ====== Ionisation Parameters << 58 GPIL Vector:
137 ============================================== << 59 Decay
138 Step function for e+- << 60 HadronCapture
139 Step function for muons/hadrons << 61 HadronFission
140 Step function for light ions << 62 inelastic
141 Step function for general ions << 63 HadronElastic
142 Lowest e+e- kinetic energy << 64 ImportanceProcess
143 Lowest muon/hadron kinetic energy << 65 Transportation
144 Use ICRU90 data << 66 DoIt Vector:
145 Fluctuations of dE/dx are enabled << 67 Transportation
146 Type of fluctuation model for leptons and hadr << 68 ImportanceProcess
147 Use built-in Birks satuaration << 69 HadronElastic
148 Build CSDA range enabled << 70 inelastic
149 Use cut as a final range enabled << 71 HadronFission
150 Enable angular generator interface << 72 HadronCapture
151 Max kinetic energy for CSDA tables << 73 Decay
152 Max kinetic energy for NIEL computation << 74 ================================================
153 Linear loss limit << 75 configure preconf
154 Read data from file for e+e- pair production b << 76
155 ============================================== << 77 conv: Total cross sections has a good parametrisation from 1.5 MeV to 100 GeV for all Z;
156 ====== Multiple Scattering Par << 78 sampling secondary e+e- according Bethe-Heitler model
157 ============================================== << 79 tables are built for gamma
158 Type of msc step limit algorithm for e+- << 80 Lambda tables from 1.022 MeV to 100 GeV in 100 bins.
159 Type of msc step limit algorithm for muons/had << 81
160 Msc lateral displacement for e+- enabled << 82 compt: Total cross sections has a good parametrisation from 10 KeV to (100/Z) GeV
161 Msc lateral displacement for muons and hadrons << 83 Sampling according Klein-Nishina model
162 Urban msc model lateral displacement alg96 << 84 tables are built for gamma
163 Range factor for msc step limit for e+- << 85 Lambda tables from 100 eV to 100 GeV in 90 bins.
164 Range factor for msc step limit for muons/hadr << 86
165 Geometry factor for msc step limitation of e+- << 87 phot: Total cross sections from Sandia parametrisation.
166 Safety factor for msc step limit for e+- << 88 Sampling according PhotoElectric model
167 Skin parameter for msc step limitation of e+- << 89
168 Lambda limit for msc step limit for e+- << 90 msc: Model variant of multiple scattering for e-
169 Use Mott correction for e- scattering << 91 Lambda tables from 100 eV to 100 TeV in 120 bins.
170 Factor used for dynamic computation of angular << 92 LateralDisplacementFlag= 1 Skin= 0
171 limit between single and multiple scattering << 93 Boundary/stepping algorithm is active with RangeFactor= 0.02 Step limit type 1
172 Fixed angular limit between single << 94
173 and multiple scattering << 95 eIoni: tables are built for e-
174 Upper energy limit for e+- multiple scattering << 96 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
175 Type of electron single scattering model << 97 Lambda tables from threshold to 100 TeV in 120 bins.
176 Type of nuclear form-factor << 98 Delta cross sections and sampling from MollerBhabha model
177 Screening factor << 99 Good description from 1 KeV to 100 GeV.
178 ============================================== << 100 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
179 << 101
180 phot: for gamma SubType=12 BuildTable=0 << 102 eBrem: tables are built for e-
181 LambdaPrime table from 200 keV to 100 Te << 103 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
182 ===== EM models for the G4Region Defaul << 104 Lambda tables from threshold to 100 TeV in 120 bins.
183 LivermorePhElectric : Emin= 0 eV Emax= 1 << 105 Total cross sections and sampling from StandBrem model (based on the EEDL data library)
184 << 106 Good description from 1 KeV to 100 GeV, log scale extrapolation above 100 GeV. LPM flag 1
185 compt: for gamma SubType=13 BuildTable=1 << 107
186 Lambda table from 100 eV to 1 MeV, 7 bi << 108 eIoni: tables are built for e+
187 LambdaPrime table from 1 MeV to 100 TeV << 109 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
188 ===== EM models for the G4Region Defaul << 110 Lambda tables from threshold to 100 TeV in 120 bins.
189 Klein-Nishina : Emin= 0 eV Emax= 1 << 111 Delta cross sections and sampling from MollerBhabha model
190 << 112 Good description from 1 KeV to 100 GeV.
191 conv: for gamma SubType=14 BuildTable=1 << 113 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
192 Lambda table from 1.022 MeV to 100 TeV, << 114
193 ===== EM models for the G4Region Defaul << 115 eBrem: tables are built for e+
194 BetheHeitlerLPM : Emin= 0 eV Emax= 1 << 116 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
195 << 117 Lambda tables from threshold to 100 TeV in 120 bins.
196 Rayl: for gamma SubType=11 BuildTable=1 << 118 Total cross sections and sampling from StandBrem model (based on the EEDL data library)
197 Lambda table from 100 eV to 150 keV, 7 << 119 Good description from 1 KeV to 100 GeV, log scale extrapolation above 100 GeV. LPM flag 1
198 LambdaPrime table from 150 keV to 100 Te << 120
199 ===== EM models for the G4Region Defaul << 121 annihil: Sampling according eplus2gg model
200 LivermoreRayleigh : Emin= 0 eV Emax= 1 << 122 tables are built for e+
201 << 123 Lambda tables from 100 eV to 100 TeV in 120 bins.
202 msc: for e- SubType= 10 << 124
203 ===== EM models for the G4Region Defaul << 125 msc: Model variant of multiple scattering for proton
204 UrbanMsc : Emin= 0 eV Emax= 1 << 126 Lambda tables from 100 eV to 100 TeV in 120 bins.
205 StepLim=UseSafety Rfact=0.04 Gfact=2 << 127 LateralDisplacementFlag= 1 Skin= 0
206 WentzelVIUni : Emin= 100 MeV Emax= 1 << 128 Boundary/stepping algorithm is active with RangeFactor= 0.02 Step limit type 1
207 StepLim=UseSafety Rfact=0.04 Gfact=2 << 129
208 << 130 hIoni: tables are built for proton
209 eIoni: for e- XStype:3 SubType=2 << 131 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
210 dE/dx and range tables from 100 eV to 1 << 132 Lambda tables from threshold to 100 TeV in 120 bins.
211 Lambda tables from threshold to 100 TeV, << 133 Scaling relation is used from proton dE/dx and range.
212 StepFunction=(0.2, 1 mm), integ: 3, fluc << 134 Delta cross sections and sampling from BetheBloch model for scaled energy > 2 MeV
213 ===== EM models for the G4Region Defaul << 135 Parametrisation from Bragg for protons below.
214 MollerBhabha : Emin= 0 eV Emax= 1 << 136 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
215 << 137
216 eBrem: for e- XStype:4 SubType=3 << 138 msc: Model variant of multiple scattering for GenericIon
217 dE/dx and range tables from 100 eV to 1 << 139 LateralDisplacementFlag= 0 Skin= 0
218 Lambda tables from threshold to 100 TeV, << 140 Boundary/stepping algorithm is active with RangeFactor= 0.2 Step limit type 1
219 LPM flag: 1 for E > 1 GeV, VertexHighEn << 141
220 ===== EM models for the G4Region Defaul << 142 hIoni: tables are built for anti_proton
221 eBremSB : Emin= 0 eV Emax= << 143 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
222 eBremLPM : Emin= 1 GeV Emax= 1 << 144 Lambda tables from threshold to 100 TeV in 120 bins.
223 << 145 Scaling relation is used from proton dE/dx and range.
224 CoulombScat: for e- XStype:1 SubType=1 BuildT << 146 Delta cross sections and sampling from BetheBloch model for scaled energy > 2 MeV
225 Lambda table from 100 MeV to 100 TeV, 7 << 147 Parametrisation from Bragg for protons below.
226 ThetaMin(p) < Theta(degree) < 180, pLimi << 148 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
227 ===== EM models for the G4Region Defaul << 149
228 eCoulombScattering : Emin= 100 MeV Emax= 1 << 150 msc: Model variant of multiple scattering for mu+
229 << 151 Lambda tables from 100 eV to 100 TeV in 120 bins.
230 msc: for e+ SubType= 10 << 152 LateralDisplacementFlag= 1 Skin= 0
231 ===== EM models for the G4Region Defaul << 153 Boundary/stepping algorithm is active with RangeFactor= 0.02 Step limit type 1
232 UrbanMsc : Emin= 0 eV Emax= 1 << 154
233 StepLim=UseSafety Rfact=0.04 Gfact=2 << 155 muIoni: tables are built for mu+
234 WentzelVIUni : Emin= 100 MeV Emax= 1 << 156 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
235 StepLim=UseSafety Rfact=0.04 Gfact=2 << 157 Lambda tables from threshold to 100 TeV in 120 bins.
236 << 158 Bether-Bloch model for E > 0.2 MeV, parametrisation of Bragg peak below,
237 eIoni: for e+ XStype:3 SubType=2 << 159 radiative corrections for E > 1 GeV
238 dE/dx and range tables from 100 eV to 1 << 160 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
239 Lambda tables from threshold to 100 TeV, << 161
240 StepFunction=(0.2, 1 mm), integ: 3, fluc << 162 muBrems: tables are built for mu+
241 ===== EM models for the G4Region Defaul << 163 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
242 MollerBhabha : Emin= 0 eV Emax= 1 << 164 Lambda tables from threshold to 100 TeV in 120 bins.
243 << 165 Parametrised model
244 eBrem: for e+ XStype:4 SubType=3 << 166
245 dE/dx and range tables from 100 eV to 1 << 167 muPairProd: tables are built for mu+
246 Lambda tables from threshold to 100 TeV, << 168 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
247 LPM flag: 1 for E > 1 GeV, VertexHighEn << 169 Lambda tables from threshold to 100 TeV in 120 bins.
248 ===== EM models for the G4Region Defaul << 170 Parametrised model
249 eBremSB : Emin= 0 eV Emax= << 171
250 eBremLPM : Emin= 1 GeV Emax= 1 << 172 muIoni: tables are built for mu-
251 << 173 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
252 annihil: for e+ XStype:2 SubType=5 AtRestMode << 174 Lambda tables from threshold to 100 TeV in 120 bins.
253 ===== EM models for the G4Region Defaul << 175 Bether-Bloch model for E > 0.2 MeV, parametrisation of Bragg peak below,
254 eplus2gg : Emin= 0 eV Emax= 1 << 176 radiative corrections for E > 1 GeV
255 << 177 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
256 CoulombScat: for e+ XStype:1 SubType=1 BuildT << 178
257 Lambda table from 100 MeV to 100 TeV, 7 << 179 muBrems: tables are built for mu-
258 ThetaMin(p) < Theta(degree) < 180, pLimi << 180 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
259 ===== EM models for the G4Region Defaul << 181 Lambda tables from threshold to 100 TeV in 120 bins.
260 eCoulombScattering : Emin= 100 MeV Emax= 1 << 182 Parametrised model
261 << 183
262 msc: for proton SubType= 10 << 184 muPairProd: tables are built for mu-
263 ===== EM models for the G4Region Defaul << 185 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
264 WentzelVIUni : Emin= 0 eV Emax= 1 << 186 Lambda tables from threshold to 100 TeV in 120 bins.
265 StepLim=Minimal Rfact=0.2 Gfact=2.5 << 187 Parametrised model
266 << 188
267 hIoni: for proton XStype:3 SubType=2 << 189 hIoni: tables are built for pi+
268 dE/dx and range tables from 100 eV to 1 << 190 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
269 Lambda tables from threshold to 100 TeV, << 191 Lambda tables from threshold to 100 TeV in 120 bins.
270 StepFunction=(0.2, 0.1 mm), integ: 3, fl << 192 Scaling relation is used from proton dE/dx and range.
271 ===== EM models for the G4Region Defaul << 193 Delta cross sections and sampling from BetheBloch model for scaled energy > 0.297504 MeV
272 Bragg : Emin= 0 eV Emax= << 194 Parametrisation from Bragg for protons below.
273 BetheBloch : Emin= 2 MeV Emax= 1 << 195 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
274 << 196
275 hBrems: for proton XStype:1 SubType=3 << 197 msc: Model variant of multiple scattering for pi-
276 dE/dx and range tables from 100 eV to 1 << 198 Lambda tables from 100 eV to 100 TeV in 120 bins.
277 Lambda tables from threshold to 100 TeV, << 199 LateralDisplacementFlag= 1 Skin= 0
278 ===== EM models for the G4Region Defaul << 200 Boundary/stepping algorithm is active with RangeFactor= 0.02 Step limit type 1
279 hBrem : Emin= 0 eV Emax= 1 << 201
280 << 202 hIoni: tables are built for pi-
281 hPairProd: for proton XStype:1 SubType=4 << 203 dE/dx and range tables from 100 eV to 100 TeV in 120 bins.
282 dE/dx and range tables from 100 eV to 1 << 204 Lambda tables from threshold to 100 TeV in 120 bins.
283 Lambda tables from threshold to 100 TeV, << 205 Scaling relation is used from proton dE/dx and range.
284 Sampling table 17x1001 from 7.50618 GeV << 206 Delta cross sections and sampling from BetheBloch model for scaled energy > 0.297504 MeV
285 ===== EM models for the G4Region Defaul << 207 Parametrisation from Bragg for protons below.
286 hPairProd : Emin= 0 eV Emax= 1 << 208 Step function: finalRange(mm)= 1, dRoverRange= 0.2, integral: 1
287 <<
288 CoulombScat: for proton XStype:1 SubType=1 Bu <<
289 Lambda table from threshold to 100 TeV, <<
290 ThetaMin(p) < Theta(degree) < 180, pLimi <<
291 ===== EM models for the G4Region Defaul <<
292 eCoulombScattering : Emin= 0 eV Emax= 1 <<
293 <<
294 msc: for GenericIon SubType= 10 <<
295 ===== EM models for the G4Region Defaul <<
296 UrbanMsc : Emin= 0 eV Emax= 1 <<
297 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
298 <<
299 ionIoni: for GenericIon XStype:3 SubType=2 <<
300 dE/dx and range tables from 100 eV to 1 <<
301 Lambda tables from threshold to 100 TeV, <<
302 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
303 ===== EM models for the G4Region Defaul <<
304 Bragg : Emin= 0 eV Emax= <<
305 BetheBloch : Emin= 2 MeV Emax= 1 <<
306 <<
307 msc: for alpha SubType= 10 <<
308 ===== EM models for the G4Region Defaul <<
309 UrbanMsc : Emin= 0 eV Emax= 1 <<
310 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
311 <<
312 ionIoni: for alpha XStype:3 SubType=2 <<
313 dE/dx and range tables from 100 eV to 1 <<
314 Lambda tables from threshold to 100 TeV, <<
315 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
316 ===== EM models for the G4Region Defaul <<
317 BraggIon : Emin= 0 eV Emax=7.9 <<
318 BetheBloch : Emin=7.9452 MeV Emax= <<
319 <<
320 msc: for anti_proton SubType= 10 <<
321 ===== EM models for the G4Region Defaul <<
322 WentzelVIUni : Emin= 0 eV Emax= 1 <<
323 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
324 <<
325 hIoni: for anti_proton XStype:3 SubType=2 <<
326 dE/dx and range tables from 100 eV to 1 <<
327 Lambda tables from threshold to 100 TeV, <<
328 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
329 ===== EM models for the G4Region Defaul <<
330 ICRU73QO : Emin= 0 eV Emax= <<
331 BetheBloch : Emin= 2 MeV Emax= 1 <<
332 <<
333 hBrems: for anti_proton XStype:1 SubType=3 <<
334 dE/dx and range tables from 100 eV to 1 <<
335 Lambda tables from threshold to 100 TeV, <<
336 ===== EM models for the G4Region Defaul <<
337 hBrem : Emin= 0 eV Emax= 1 <<
338 <<
339 hPairProd: for anti_proton XStype:1 SubType <<
340 dE/dx and range tables from 100 eV to 1 <<
341 Lambda tables from threshold to 100 TeV, <<
342 Sampling table 17x1001 from 7.50618 GeV <<
343 ===== EM models for the G4Region Defaul <<
344 hPairProd : Emin= 0 eV Emax= 1 <<
345 <<
346 CoulombScat: for anti_proton XStype:1 SubType <<
347 Lambda table from threshold to 100 TeV, <<
348 ThetaMin(p) < Theta(degree) < 180, pLimi <<
349 ===== EM models for the G4Region Defaul <<
350 eCoulombScattering : Emin= 0 eV Emax= 1 <<
351 <<
352 msc: for kaon+ SubType= 10 <<
353 ===== EM models for the G4Region Defaul <<
354 WentzelVIUni : Emin= 0 eV Emax= 1 <<
355 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
356 <<
357 hIoni: for kaon+ XStype:3 SubType=2 <<
358 dE/dx and range tables from 100 eV to 1 <<
359 Lambda tables from threshold to 100 TeV, <<
360 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
361 ===== EM models for the G4Region Defaul <<
362 Bragg : Emin= 0 eV Emax=1.0 <<
363 BetheBloch : Emin=1.05231 MeV Emax= <<
364 <<
365 hBrems: for kaon+ XStype:1 SubType=3 <<
366 dE/dx and range tables from 100 eV to 1 <<
367 Lambda tables from threshold to 100 TeV, <<
368 ===== EM models for the G4Region Defaul <<
369 hBrem : Emin= 0 eV Emax= 1 <<
370 <<
371 hPairProd: for kaon+ XStype:1 SubType=4 <<
372 dE/dx and range tables from 100 eV to 1 <<
373 Lambda tables from threshold to 100 TeV, <<
374 Sampling table 18x1001 from 3.94942 GeV <<
375 ===== EM models for the G4Region Defaul <<
376 hPairProd : Emin= 0 eV Emax= 1 <<
377 <<
378 CoulombScat: for kaon+ XStype:1 SubType=1 Bui <<
379 Lambda table from threshold to 100 TeV, <<
380 ThetaMin(p) < Theta(degree) < 180, pLimi <<
381 ===== EM models for the G4Region Defaul <<
382 eCoulombScattering : Emin= 0 eV Emax= 1 <<
383 <<
384 msc: for kaon- SubType= 10 <<
385 ===== EM models for the G4Region Defaul <<
386 WentzelVIUni : Emin= 0 eV Emax= 1 <<
387 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
388 <<
389 hIoni: for kaon- XStype:3 SubType=2 <<
390 dE/dx and range tables from 100 eV to 1 <<
391 Lambda tables from threshold to 100 TeV, <<
392 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
393 ===== EM models for the G4Region Defaul <<
394 ICRU73QO : Emin= 0 eV Emax=1.0 <<
395 BetheBloch : Emin=1.05231 MeV Emax= <<
396 <<
397 hBrems: for kaon- XStype:1 SubType=3 <<
398 dE/dx and range tables from 100 eV to 1 <<
399 Lambda tables from threshold to 100 TeV, <<
400 ===== EM models for the G4Region Defaul <<
401 hBrem : Emin= 0 eV Emax= 1 <<
402 <<
403 hPairProd: for kaon- XStype:1 SubType=4 <<
404 dE/dx and range tables from 100 eV to 1 <<
405 Lambda tables from threshold to 100 TeV, <<
406 Sampling table 18x1001 from 3.94942 GeV <<
407 ===== EM models for the G4Region Defaul <<
408 hPairProd : Emin= 0 eV Emax= 1 <<
409 <<
410 CoulombScat: for kaon- XStype:1 SubType=1 Bui <<
411 Used Lambda table of kaon+ <<
412 ThetaMin(p) < Theta(degree) < 180, pLimi <<
413 ===== EM models for the G4Region Defaul <<
414 eCoulombScattering : Emin= 0 eV Emax= 1 <<
415 <<
416 msc: for mu+ SubType= 10 <<
417 ===== EM models for the G4Region Defaul <<
418 WentzelVIUni : Emin= 0 eV Emax= 1 <<
419 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
420 <<
421 muIoni: for mu+ XStype:3 SubType=2 <<
422 dE/dx and range tables from 100 eV to 1 <<
423 Lambda tables from threshold to 100 TeV, <<
424 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
425 ===== EM models for the G4Region Defaul <<
426 Bragg : Emin= 0 eV Emax= 2 <<
427 MuBetheBloch : Emin= 200 keV Emax= 1 <<
428 <<
429 muBrems: for mu+ XStype:1 SubType=3 <<
430 dE/dx and range tables from 100 eV to 1 <<
431 Lambda tables from threshold to 100 TeV, <<
432 ===== EM models for the G4Region Defaul <<
433 MuBrem : Emin= 0 eV Emax= 1 <<
434 <<
435 muPairProd: for mu+ XStype:1 SubType=4 <<
436 dE/dx and range tables from 100 eV to 1 <<
437 Lambda tables from threshold to 100 TeV, <<
438 Sampling table 21x1001 from 0.85 GeV to <<
439 ===== EM models for the G4Region Defaul <<
440 muPairProd : Emin= 0 eV Emax= 1 <<
441 <<
442 CoulombScat: for mu+ XStype:1 SubType=1 Build <<
443 Lambda table from threshold to 100 TeV, <<
444 ThetaMin(p) < Theta(degree) < 180, pLimi <<
445 ===== EM models for the G4Region Defaul <<
446 eCoulombScattering : Emin= 0 eV Emax= 1 <<
447 <<
448 msc: for mu- SubType= 10 <<
449 ===== EM models for the G4Region Defaul <<
450 WentzelVIUni : Emin= 0 eV Emax= 1 <<
451 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
452 <<
453 muIoni: for mu- XStype:3 SubType=2 <<
454 dE/dx and range tables from 100 eV to 1 <<
455 Lambda tables from threshold to 100 TeV, <<
456 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
457 ===== EM models for the G4Region Defaul <<
458 ICRU73QO : Emin= 0 eV Emax= 2 <<
459 MuBetheBloch : Emin= 200 keV Emax= 1 <<
460 <<
461 muBrems: for mu- XStype:1 SubType=3 <<
462 dE/dx and range tables from 100 eV to 1 <<
463 Lambda tables from threshold to 100 TeV, <<
464 ===== EM models for the G4Region Defaul <<
465 MuBrem : Emin= 0 eV Emax= 1 <<
466 <<
467 muPairProd: for mu- XStype:1 SubType=4 <<
468 dE/dx and range tables from 100 eV to 1 <<
469 Lambda tables from threshold to 100 TeV, <<
470 Sampling table 21x1001 from 0.85 GeV to <<
471 ===== EM models for the G4Region Defaul <<
472 muPairProd : Emin= 0 eV Emax= 1 <<
473 <<
474 CoulombScat: for mu- XStype:1 SubType=1 Build <<
475 Used Lambda table of mu+ <<
476 ThetaMin(p) < Theta(degree) < 180, pLimi <<
477 ===== EM models for the G4Region Defaul <<
478 eCoulombScattering : Emin= 0 eV Emax= 1 <<
479 <<
480 msc: for pi+ SubType= 10 <<
481 ===== EM models for the G4Region Defaul <<
482 WentzelVIUni : Emin= 0 eV Emax= 1 <<
483 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
484 <<
485 hIoni: for pi+ XStype:3 SubType=2 <<
486 dE/dx and range tables from 100 eV to 1 <<
487 Lambda tables from threshold to 100 TeV, <<
488 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
489 ===== EM models for the G4Region Defaul <<
490 Bragg : Emin= 0 eV Emax=297 <<
491 BetheBloch : Emin=297.505 keV Emax= <<
492 <<
493 hBrems: for pi+ XStype:1 SubType=3 <<
494 dE/dx and range tables from 100 eV to 1 <<
495 Lambda tables from threshold to 100 TeV, <<
496 ===== EM models for the G4Region Defaul <<
497 hBrem : Emin= 0 eV Emax= 1 <<
498 <<
499 hPairProd: for pi+ XStype:1 SubType=4 <<
500 dE/dx and range tables from 100 eV to 1 <<
501 Lambda tables from threshold to 100 TeV, <<
502 Sampling table 20x1001 from 1.11656 GeV <<
503 ===== EM models for the G4Region Defaul <<
504 hPairProd : Emin= 0 eV Emax= 1 <<
505 <<
506 CoulombScat: for pi+ XStype:1 SubType=1 Build <<
507 Lambda table from threshold to 100 TeV, <<
508 ThetaMin(p) < Theta(degree) < 180, pLimi <<
509 ===== EM models for the G4Region Defaul <<
510 eCoulombScattering : Emin= 0 eV Emax= 1 <<
511 <<
512 msc: for pi- SubType= 10 <<
513 ===== EM models for the G4Region Defaul <<
514 WentzelVIUni : Emin= 0 eV Emax= 1 <<
515 StepLim=Minimal Rfact=0.2 Gfact=2.5 <<
516 <<
517 hIoni: for pi- XStype:3 SubType=2 <<
518 dE/dx and range tables from 100 eV to 1 <<
519 Lambda tables from threshold to 100 TeV, <<
520 StepFunction=(0.2, 0.1 mm), integ: 3, fl <<
521 ===== EM models for the G4Region Defaul <<
522 ICRU73QO : Emin= 0 eV Emax=297 <<
523 BetheBloch : Emin=297.505 keV Emax= <<
524 <<
525 hBrems: for pi- XStype:1 SubType=3 <<
526 dE/dx and range tables from 100 eV to 1 <<
527 Lambda tables from threshold to 100 TeV, <<
528 ===== EM models for the G4Region Defaul <<
529 hBrem : Emin= 0 eV Emax= 1 <<
530 <<
531 hPairProd: for pi- XStype:1 SubType=4 <<
532 dE/dx and range tables from 100 eV to 1 <<
533 Lambda tables from threshold to 100 TeV, <<
534 Sampling table 20x1001 from 1.11656 GeV <<
535 ===== EM models for the G4Region Defaul <<
536 hPairProd : Emin= 0 eV Emax= 1 <<
537 <<
538 CoulombScat: for pi- XStype:1 SubType=1 Build <<
539 Used Lambda table of pi+ <<
540 ThetaMin(p) < Theta(degree) < 180, pLimi <<
541 ===== EM models for the G4Region Defaul <<
542 eCoulombScattering : Emin= 0 eV Emax= 1 <<
543 <<
544 ============================================== <<
545 HADRONIC PROCESSES SUMMARY ( <<
546 ---------------------------------------------- <<
547 Hadronic Processes <<
548 Process: hadElastic <<
549 Model: hElasticCHIPS: 0 eV <<
550 Cr_sctns: G4NeutronElasticXS: 0 eV <<
551 Process: neutronInelastic <<
552 Model: FTFP: 3 Ge <<
553 Model: BertiniCascade: 0 eV <<
554 Cr_sctns: G4NeutronInelasticXS: 0 eV <<
555 Process: nCapture <<
556 Model: nRadCapture: 0 eV <<
557 Cr_sctns: G4NeutronCaptureXS: 0 eV <<
558 Process: nKiller <<
559 ---------------------------------------------- <<
560 Hadronic Processes <<
561 Process: hadElastic <<
562 Model: hElasticLHEP: 0 eV <<
563 Cr_sctns: Glauber-Gribov: 0 eV <<
564 Process: B-Inelastic <<
565 Model: FTFP: 0 eV <<
566 Cr_sctns: Glauber-Gribov: 0 eV <<
567 ---------------------------------------------- <<
568 Hadronic Processes <<
569 Process: hadElastic <<
570 Model: hElasticLHEP: 0 eV <<
571 Cr_sctns: Glauber-Gribov: 0 eV <<
572 Process: D-Inelastic <<
573 Model: FTFP: 0 eV <<
574 Cr_sctns: Glauber-Gribov: 0 eV <<
575 ---------------------------------------------- <<
576 Hadronic Processes <<
577 Process: ionInelastic <<
578 Model: Binary Light Ion Cascade: 0 eV <<
579 Model: FTFP: 3 Ge <<
580 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
581 ---------------------------------------------- <<
582 Hadronic Processes <<
583 Process: hadElastic <<
584 Model: hElasticLHEP: 0 eV <<
585 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
586 Process: He3Inelastic <<
587 Model: Binary Light Ion Cascade: 0 eV <<
588 Model: FTFP: 3 Ge <<
589 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
590 ---------------------------------------------- <<
591 Hadronic Processes <<
592 Process: hadElastic <<
593 Model: hElasticLHEP: 0 eV <<
594 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
595 Process: alphaInelastic <<
596 Model: Binary Light Ion Cascade: 0 eV <<
597 Model: FTFP: 3 Ge <<
598 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
599 ---------------------------------------------- <<
600 Hadronic Processes <<
601 Process: hadElastic <<
602 Model: hElasticLHEP: 0 eV <<
603 Model: AntiAElastic: 100 <<
604 Cr_sctns: AntiAGlauber: 0 eV <<
605 Process: anti_He3Inelastic <<
606 Model: FTFP: 0 eV <<
607 Cr_sctns: AntiAGlauber: 0 eV <<
608 Process: hFritiofCaptureAtRest <<
609 ---------------------------------------------- <<
610 Hadronic Processes <<
611 Process: hadElastic <<
612 Model: hElasticLHEP: 0 eV <<
613 Model: AntiAElastic: 100 <<
614 Cr_sctns: AntiAGlauber: 0 eV <<
615 Process: anti_alphaInelastic <<
616 Model: FTFP: 0 eV <<
617 Cr_sctns: AntiAGlauber: 0 eV <<
618 Process: hFritiofCaptureAtRest <<
619 ---------------------------------------------- <<
620 Hadronic Processes <<
621 Process: hadElastic <<
622 Model: hElasticLHEP: 0 eV <<
623 Model: AntiAElastic: 100 <<
624 Cr_sctns: AntiAGlauber: 0 eV <<
625 Process: anti_deuteronInelastic <<
626 Model: FTFP: 0 eV <<
627 Cr_sctns: AntiAGlauber: 0 eV <<
628 Process: hFritiofCaptureAtRest <<
629 ---------------------------------------------- <<
630 Hadronic Processes <<
631 Process: hFritiofCaptureAtRest <<
632 ---------------------------------------------- <<
633 Hadronic Processes <<
634 Process: hadElastic <<
635 Model: hElasticLHEP: 0 eV <<
636 Cr_sctns: Glauber-Gribov: 0 eV <<
637 Process: anti_lambdaInelastic <<
638 Model: FTFP: 0 eV <<
639 Cr_sctns: Glauber-Gribov: 0 eV <<
640 Process: hFritiofCaptureAtRest <<
641 ---------------------------------------------- <<
642 Hadronic Processes <<
643 Process: hadElastic <<
644 Model: hElasticLHEP: 0 eV <<
645 Model: AntiAElastic: 100 <<
646 Cr_sctns: AntiAGlauber: 0 eV <<
647 Process: anti_neutronInelastic <<
648 Model: FTFP: 0 eV <<
649 Cr_sctns: AntiAGlauber: 0 eV <<
650 Process: hFritiofCaptureAtRest <<
651 ---------------------------------------------- <<
652 Hadronic Processes <<
653 Process: hadElastic <<
654 Model: hElasticLHEP: 0 eV <<
655 Model: AntiAElastic: 100 <<
656 Cr_sctns: AntiAGlauber: 0 eV <<
657 Process: anti_protonInelastic <<
658 Model: FTFP: 0 eV <<
659 Cr_sctns: AntiAGlauber: 0 eV <<
660 Process: hFritiofCaptureAtRest <<
661 ---------------------------------------------- <<
662 Hadronic Processes <<
663 Process: hadElastic <<
664 Model: hElasticLHEP: 0 eV <<
665 Model: AntiAElastic: 100 <<
666 Cr_sctns: AntiAGlauber: 0 eV <<
667 Process: anti_tritonInelastic <<
668 Model: FTFP: 0 eV <<
669 Cr_sctns: AntiAGlauber: 0 eV <<
670 Process: hFritiofCaptureAtRest <<
671 ---------------------------------------------- <<
672 Hadronic Processes <<
673 Process: hadElastic <<
674 Model: hElasticLHEP: 0 eV <<
675 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
676 Process: dInelastic <<
677 Model: Binary Light Ion Cascade: 0 eV <<
678 Model: FTFP: 3 Ge <<
679 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
680 ---------------------------------------------- <<
681 Hadronic Processes <<
682 Process: positronNuclear <<
683 Model: G4ElectroVDNuclearModel: 0 eV <<
684 Cr_sctns: ElectroNuclearXS: 0 eV <<
685 ---------------------------------------------- <<
686 Hadronic Processes <<
687 Process: electronNuclear <<
688 Model: G4ElectroVDNuclearModel: 0 eV <<
689 Cr_sctns: ElectroNuclearXS: 0 eV <<
690 ---------------------------------------------- <<
691 Hadronic Processes <<
692 Process: photonNuclear <<
693 Model: GammaNPreco: 0 eV <<
694 Model: BertiniCascade: 199 <<
695 Model: TheoFSGenerator: 3 Ge <<
696 Cr_sctns: GammaNuclearXS: 0 eV <<
697 ---------------------------------------------- <<
698 Hadronic Processes <<
699 Process: hadElastic <<
700 Model: hElasticLHEP: 0 eV <<
701 Cr_sctns: Glauber-Gribov: 0 eV <<
702 Process: kaon+Inelastic <<
703 Model: FTFP: 3 Ge <<
704 Model: BertiniCascade: 0 eV <<
705 Cr_sctns: Glauber-Gribov: 0 eV <<
706 ---------------------------------------------- <<
707 Hadronic Processes <<
708 Process: hadElastic <<
709 Model: hElasticLHEP: 0 eV <<
710 Cr_sctns: Glauber-Gribov: 0 eV <<
711 Process: kaon-Inelastic <<
712 Model: FTFP: 3 Ge <<
713 Model: BertiniCascade: 0 eV <<
714 Cr_sctns: Glauber-Gribov: 0 eV <<
715 Process: hBertiniCaptureAtRest <<
716 ---------------------------------------------- <<
717 Hadronic Processes <<
718 Process: hadElastic <<
719 Model: hElasticLHEP: 0 eV <<
720 Cr_sctns: Glauber-Gribov: 0 eV <<
721 Process: lambdaInelastic <<
722 Model: FTFP: 3 Ge <<
723 Model: BertiniCascade: 0 eV <<
724 Cr_sctns: Glauber-Gribov: 0 eV <<
725 ---------------------------------------------- <<
726 Hadronic Processes <<
727 Process: muonNuclear <<
728 Model: G4MuonVDNuclearModel: 0 eV <<
729 Cr_sctns: KokoulinMuonNuclearXS: 0 eV <<
730 ---------------------------------------------- <<
731 Hadronic Processes <<
732 Process: muonNuclear <<
733 Model: G4MuonVDNuclearModel: 0 eV <<
734 Cr_sctns: KokoulinMuonNuclearXS: 0 eV <<
735 Process: muMinusCaptureAtRest <<
736 ---------------------------------------------- <<
737 Hadronic Processes <<
738 Process: hadElastic <<
739 Model: hElasticGlauber: 0 eV <<
740 Cr_sctns: BarashenkovGlauberGribov: 0 eV <<
741 Process: pi+Inelastic <<
742 Model: FTFP: 3 Ge <<
743 Model: BertiniCascade: 0 eV <<
744 Cr_sctns: BarashenkovGlauberGribov: 0 eV <<
745 ---------------------------------------------- <<
746 Hadronic Processes <<
747 Process: hadElastic <<
748 Model: hElasticGlauber: 0 eV <<
749 Cr_sctns: BarashenkovGlauberGribov: 0 eV <<
750 Process: pi-Inelastic <<
751 Model: FTFP: 3 Ge <<
752 Model: BertiniCascade: 0 eV <<
753 Cr_sctns: BarashenkovGlauberGribov: 0 eV <<
754 Process: hBertiniCaptureAtRest <<
755 ---------------------------------------------- <<
756 Hadronic Processes <<
757 Process: hadElastic <<
758 Model: hElasticCHIPS: 0 eV <<
759 Cr_sctns: BarashenkovGlauberGribov: 0 eV <<
760 Process: protonInelastic <<
761 Model: FTFP: 3 Ge <<
762 Model: BertiniCascade: 0 eV <<
763 Cr_sctns: BarashenkovGlauberGribov: 0 eV <<
764 ---------------------------------------------- <<
765 Hadronic Processes <<
766 Process: hadElastic <<
767 Model: hElasticLHEP: 0 eV <<
768 Cr_sctns: Glauber-Gribov: 0 eV <<
769 Process: sigma-Inelastic <<
770 Model: FTFP: 3 Ge <<
771 Model: BertiniCascade: 0 eV <<
772 Cr_sctns: Glauber-Gribov: 0 eV <<
773 Process: hBertiniCaptureAtRest <<
774 ---------------------------------------------- <<
775 Hadronic Processes <<
776 Process: hadElastic <<
777 Model: hElasticLHEP: 0 eV <<
778 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
779 Process: tInelastic <<
780 Model: Binary Light Ion Cascade: 0 eV <<
781 Model: FTFP: 3 Ge <<
782 Cr_sctns: Glauber-Gribov Nucl-nucl: 0 eV <<
783 ============================================== <<
784 ====== Geant4 Native Pre-compound Model <<
785 ============================================== <<
786 Type of pre-compound inverse x-section <<
787 Pre-compound model active <<
788 Pre-compound excitation low energy <<
789 Pre-compound excitation high energy <<
790 Angular generator for pre-compound model <<
791 Use NeverGoBack option for pre-compound model <<
792 Use SoftCutOff option for pre-compound model <<
793 Use CEM transitions for pre-compound model <<
794 Use GNASH transitions for pre-compound model <<
795 Use HETC submodel for pre-compound model <<
796 ============================================== <<
797 ====== Nuclear De-excitation Module Para <<
798 ============================================== <<
799 Type of de-excitation inverse x-section <<
800 Type of de-excitation factory <<
801 Number of de-excitation channels <<
802 Min excitation energy <<
803 Min energy per nucleon for multifragmentation <<
804 Limit excitation energy for Fermi BreakUp <<
805 Level density (1/MeV) <<
806 Use simple level density model <<
807 Use discrete excitation energy of the residual <<
808 Time limit for long lived isomeres <<
809 Isomer production flag <<
810 Internal e- conversion flag <<
811 Store e- internal conversion data <<
812 Correlated gamma emission flag <<
813 Max 2J for sampling of angular correlations <<
814 ============================================== <<
815 ++ ConcreteSD/Collisions id 0 209 ++ ConcreteSD/Collisions id 0
816 ++ ConcreteSD/CollWeight id 1 210 ++ ConcreteSD/CollWeight id 1
817 ++ ConcreteSD/Population id 2 211 ++ ConcreteSD/Population id 2
818 ++ ConcreteSD/TrackEnter id 3 212 ++ ConcreteSD/TrackEnter id 3
819 ++ ConcreteSD/SL id 4 213 ++ ConcreteSD/SL id 4
820 ++ ConcreteSD/SLW id 5 214 ++ ConcreteSD/SLW id 5
821 ++ ConcreteSD/SLWE id 6 215 ++ ConcreteSD/SLWE id 6
822 ++ ConcreteSD/SLW_V id 7 216 ++ ConcreteSD/SLW_V id 7
823 ++ ConcreteSD/SLWE_V id 8 217 ++ ConcreteSD/SLWE_V id 8
824 ### Run 0 start. 218 ### Run 0 start.
825 ###### EndOfRunAction 219 ###### EndOfRunAction
826 <<
827 --------------------End of Global Run--------- <<
828 Number of event processed : 100 <<
829 ============================================== 220 =============================================================
>> 221 Number of event processed : 100
830 ============================================== 222 =============================================================
831 Volume | Tr.Entering | Population 223 Volume | Tr.Entering | Population | Collisions | Coll*WGT | NumWGTedE | FluxWGTedE | Av.Tr.WGT | SL | SLW | SLW_v | SLWE | SLWE_v |
832 cell_00 | 32 | 127 << 224 cell_00 | 7 | 106 | 0 | 0 | 4.8570632 | 6.394919 | 1 | 1113.0539 | 1113.0539 | 39.997852 | 7117.8892 | 194.27209 |
833 cell_01 | 139 | 179 << 225 cell_01 | 107 | 126 | 160 | 160 | 7.245862 | 8.6524027 | 1 | 12127.588 | 12127.588 | 350.85037 | 104932.77 | 2542.2133 |
834 cell_02 | 174 | 270 << 226 cell_02 | 72 | 171 | 216 | 108 | 6.1900176 | 8.0820959 | 0.5 | 16630.552 | 8315.2759 | 269.99556 | 67204.857 | 1671.2773 |
835 cell_03 | 229 | 334 << 227 cell_03 | 84 | 188 | 199 | 49.75 | 7.3393396 | 8.7216156 | 0.25 | 19277.93 | 4819.4826 | 139.36705 | 42033.675 | 1022.8621 |
836 cell_04 | 254 | 381 << 228 cell_04 | 107 | 249 | 314 | 39.25 | 6.2237328 | 8.0359115 | 0.125 | 25982.232 | 3247.779 | 105.22726 | 26098.865 | 654.90636 |
837 cell_05 | 291 | 420 << 229 cell_05 | 119 | 274 | 350 | 21.875 | 5.8304001 | 7.7473901 | 0.0625 | 29050.14 | 1815.6337 | 61.166969 | 14066.423 | 356.6279 |
838 cell_06 | 327 | 472 << 230 cell_06 | 138 | 314 | 483 | 15.09375 | 5.061069 | 7.4461955 | 0.03125 | 33710.715 | 1053.4598 | 39.851437 | 7844.2679 | 201.69087 |
839 cell_07 | 296 | 437 << 231 cell_07 | 138 | 312 | 458 | 7.15625 | 5.2852313 | 7.2039361 | 0.015625 | 35495.11 | 554.6111 | 19.756546 | 3995.3829 | 104.41791 |
840 cell_08 | 262 | 372 << 232 cell_08 | 170 | 390 | 654 | 5.109375 | 4.9015271 | 6.698322 | 0.0078125 | 45936.052 | 358.8754 | 13.198783 | 2403.863 | 64.694191 |
841 cell_09 | 260 | 356 << 233 cell_09 | 186 | 431 | 655 | 2.5585938 | 4.5999796 | 6.2994019 | 0.00390625 | 45880.729 | 179.2216 | 6.788147 | 1128.9889 | 31.225338 |
842 cell_10 | 229 | 331 << 234 cell_10 | 205 | 461 | 802 | 1.5664062 | 4.0725245 | 5.9959975 | 0.001953125 | 52001.934 | 101.56628 | 4.2218939 | 608.99115 | 17.193766 |
843 cell_11 | 186 | 270 << 235 cell_11 | 232 | 512 | 857 | 0.83691406 | 0.75577079 | 5.6832231 | 0.0009765625 | 58106.748 | 56.744871 | 12.259625 | 322.49376 | 9.2654668 |
844 cell_12 | 154 | 220 << 236 cell_12 | 271 | 584 | 1056 | 0.515625 | 3.0370662 | 5.2506271 | 0.00048828125 | 67467.473 | 32.943102 | 1.6912862 | 172.97195 | 5.136548 |
845 cell_13 | 123 | 185 << 237 cell_13 | 311 | 675 | 1216 | 0.296875 | 3.2604017 | 4.9243062 | 0.00024414062 | 75024.488 | 18.316525 | 0.84787155 | 90.196179 | 2.7644018 |
846 cell_14 | 109 | 157 << 238 cell_14 | 329 | 758 | 1419 | 0.17321777 | 3.4451656 | 4.769336 | 0.00012207031 | 84584.636 | 10.325273 | 0.4478539 | 49.244695 | 1.5429309 |
847 cell_15 | 79 | 112 << 239 cell_15 | 364 | 783 | 1540 | 0.093994141 | 0.40940195 | 4.4470643 | 6.1035156e-05 | 91736.425 | 5.599147 | 1.9622683 | 24.899767 | 0.80335646 |
848 cell_16 | 68 | 99 << 240 cell_16 | 398 | 858 | 1703 | 0.051971436 | 0.25175739 | 4.2259526 | 3.0517578e-05 | 98797.986 | 3.0150753 | 1.6715126 | 12.741565 | 0.42081564 |
849 cell_17 | 53 | 82 << 241 cell_17 | 413 | 932 | 1881 | 0.028701782 | 2.8791199 | 4.1895463 | 1.5258789e-05 | 107543.85 | 1.6409889 | 0.079050326 | 6.874999 | 0.22759537 |
850 cell_18 | 32 | 57 << 242 cell_18 | 383 | 889 | 1706 | 0.013015747 | 2.8292119 | 4.1307913 | 7.6293945e-06 | 100556.11 | 0.76718227 | 0.037287182 | 3.1690698 | 0.10549334 |
851 cell_19 | 25 | 25 << 243 cell_19 | 440 | 440 | 0 | 0 | 2.8202313 | 4.1847543 | 7.6293945e-06 | 63345.904 | 0.48329089 | 0.023651264 | 2.0224537 | 0.066702034 |
852 ============================================= 244 =============================================
>> 245 === G4ProcessPlacer::RemoveProcess: for: neutron
>> 246 ProcessName: ImportanceProcess, will be removed!
>> 247 The initial Vectors:
>> 248 GPIL Vector:
>> 249 Decay
>> 250 HadronCapture
>> 251 HadronFission
>> 252 inelastic
>> 253 HadronElastic
>> 254 ImportanceProcess
>> 255 Transportation
>> 256 DoIt Vector:
>> 257 Transportation
>> 258 ImportanceProcess
>> 259 HadronElastic
>> 260 inelastic
>> 261 HadronFission
>> 262 HadronCapture
>> 263 Decay
>> 264 The final Vectors:
>> 265 GPIL Vector:
>> 266 Decay
>> 267 HadronCapture
>> 268 HadronFission
>> 269 inelastic
>> 270 HadronElastic
>> 271 Transportation
>> 272 DoIt Vector:
>> 273 Transportation
>> 274 HadronElastic
>> 275 inelastic
>> 276 HadronFission
>> 277 HadronCapture
>> 278 Decay
>> 279 ================================================