PENELOPE 2003 - OECD Nuclear Energy Agency

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234 Bibliography Berger M.J. and J.H. Hubbell (1987), “XCOM: Photon Cross Sections on a Personal Computer”, Report NBSIR 87-3597 (National Bureau of Standards, Gaithersburg, MD). Berger M.J. and S.M. Seltzer (1972), “Response functions for sodium iodide scintillation detectors”, Nucl. Instrum. Meth. 104, 317–332. Berger M.J. and S.M. Seltzer (1982), “Stopping Power of Electrons and Positrons”, Report NBSIR 82-2550 (National Bureau of Standards, Gaithersburg, MD). Berger M.J. and S.M. Seltzer (1988), chapters 7, 8 and 9, in Monte Carlo Transport of Electrons and Photons, eds. T.M. Jenkins, W.R. Nelson and A. Rindi (Plenum, New York). Bethe, H.A. (1930), “Zur Theorie des Durchgangs schneller Korpurkularstrahlen durch Materie”, Ann. Physik 5, 325–400. Bethe, H.A. (1932), “Bremsformel für Elektronen relativistischer Geschwindigkeit”, Z. Physik 76, 293–299. Bethe H.A. and W. Heitler (1934), “On the stopping of fast particles and on the creation of positive electrons”, Proc. R. Soc. (London) A 146, 83–112. Bhabha H.J. (1936), “The scattering of positrons by electrons with exchange on Dirac’s theory of the positron”, Proc. R. Soc. (London) A 154, 195–206. Bielajew A.F. (1988), “Electron transport in ⃗ E and ⃗ B fields”, in Monte Carlo Transport of Electrons and Photons, eds. T.M. Jenkins, W.R. Nelson and A. Rindi (Plenum, New York) pp. 421–434. Bielajew A.F. (1995), “HOWFAR and HOWNEAR: Geometry Modeling for Monte Carlo Particle Transport”, Report PIRS-0341 (National Research Council of Canada, Ottawa). Bielajew A.F. and D.W.O. Rogers (1987), “PRESTA: The parameter reduced electronstep transport algorithm for electron Monte Carlo transport”, Nucl. Instrum. Meth. B 18, 165–181. Bielajew A.F. and D.W.O. Rogers (1988), “Variance-reduction techniques”, in Monte Carlo Transport of Electrons and Photons, eds. T.M. Jenkins, W.R. Nelson and A. Rindi (Plenum, New York) pp. 407–419. Bielajew A.F. and F. Salvat (2001), “Improved electron transport mechanics in the <strong>PENELOPE</strong> Monte-Carlo model”, Nucl. Instrum. Meth. B 173, 332–343. Biggs F., L.B. Mendelsohn and J.B. Mann (1975), “Hartree-Fock Compton profiles for the elements”, At. Data Nucl. Data Tables 16, 201–309. Blunck O. and S. Leisegang (1950), “Zum Energieverlust schneller Elektronen in dünnen Schichten”, Z. Physik 128, 500–505. Born M. (1969), Atomic Physics (Blackie and Son, London). Bransden B.H. and C.J. Joachain (1983), Physics of Atoms and Molecules (Longman, Essex, England).
Bibliography 235 Briesmeister J.F. (1997), “MCNP—A general Monte Carlo N-particle transport code”, Report LA-12625-M Version 4B (Los Alamos National Laboratory, Los Alamos, NM). Brun R., F. Bruyant, M. Maire, A.C. McPherson and P. Zanarini (1986), “GEANT3”, Report DD/EE/84–1 (CERN, Geneva). Brusa D., G. Stutz, J.A. Riveros, J.M. Fernández-Varea and F. Salvat (1996), “Fast sampling algorithm for the simulation of photon Compton scattering”, Nucl. Instrum. Meth. A 379, 167–175. Chan H.-P. and K. Doi (1983), “The validity of Monte Carlo simulation in studies of scattered radiation in diagnostic radiology”, Phys. Med. Biol. 28, 109–129. Cooper M. (1971), “Compton scattering and electron momentum distributions”, Adv. Phys. 20, 453–491. Cullen D.E., M.H. Chen, J.H. Hubbell, S.T. Perkins, E.F. Plechaty, J.A. Rathkopf and J.H. Scofield (1989), “Tables and graphs of photon-interaction cross sections from 10 eV to 100 GeV derived from the LLNL evaluated photon data library (EPDL)”, Report UCRL-50400 vol. 6, rev. 4, parts A and B. (Lawrence Livermore National Laboratory, Livermore, CA). Cullen D.E., J.H. Hubbell and L. Kissel (1997), “EPDL97 The evaluated data library, ′ 97 version”, Report UCRL-50400 vol. 6, rev. 5 (Lawrence Livermore National Laboratory, Livermore, CA). Davies H., H.A. Bethe and L.C. Maximon (1954), “Theory of bremsstrahlung and pair production. II. Integral cross section for pair production” Phys. Rev. 93, 788–795. Desclaux J.P. (1975), “A multiconfiguration relativistic Dirac-Fock program”, Comput. Phys. Commun. 9, 31–45. Erratum: ibid. 13 (1977) 71. Doyle P.A. and P.S. Turner (1968), “Relativistic Hartree-Fock X-ray and electron scattering factors”, Acta Cryst. A 24, 390–397. Edmonds A.R. (1960), Angular Momentum in Quantum Mechanics, 2nd edition (Princeton University Press, Princeton, NJ). Fano U. (1954), “Inelastic collisions and the Molière theory of multiple scattering”, Phys. Rev. 93, 117–120. Fano U. (1963), “Penetration of protons, alpha particles and mesons”, Ann. Rev. Nucl. Sci. 13, 1–66. Fernández-Varea J.M., R. Mayol, D. Liljequist and F. Salvat (1993a) “Inelastic scattering of electrons in solids from a generalized oscillator strength model using optical and photoelectric data”, J. Phys: Condens. Matter 5, 3593–3610. Fernández-Varea J.M., R. Mayol, J. Baró and F. Salvat (1993b), “On the theory and simulation of multiple elastic scattering of electrons”, Nucl. Instrum. Meth. B 73, 447–473. Goudsmit S. and J.L. Saunderson (1940a), “Multiple scattering of electrons”, Phys. Rev. 57, 24–29.
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Data Bank ISBN 92-64-02145-0 PENELO
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FOREWORD The OECD/NEA Data Bank was
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TABLE OF CONTENTS Foreword ........
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4.3 Combined scattering and energy
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PREFACE Radiation transport in matt
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The present version of PENELOPE is
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Chapter 1 Monte Carlo simulation. B
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1.1. Elements of probability theory
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1.1. Elements of probability theory
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1.2. Random sampling methods 7 Tabl
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1.2. Random sampling methods 9 Nume
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1.2. Random sampling methods 11 whe
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1.2. Random sampling methods 13 can
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1.2. Random sampling methods 15 mus
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1.2. Random sampling methods 17 the
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1.3. Monte Carlo integration 19 Con
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1.4. Simulation of radiation transp
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¡ ¢ 1.4. Simulation of radiation
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1.5. Statistical averages and uncer
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1.6. Variance reduction 31 also imp
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1.6. Variance reduction 33 weight a
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Chapter 2 Photon interactions In th
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2.1. Coherent (Rayleigh) scattering
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2.1. Coherent (Rayleigh) scattering
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2.2. Photoelectric effect 41 ➤E E
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F 2.2. Photoelectric effect 43 1E+7
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2.3. Incoherent (Compton) scatterin
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C u 2.3. Incoherent (Compton) scatt
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2.4. Electron-positron pair product
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2.5. Attenuation coefficients 63 di
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2.6. Atomic relaxation 65 2.6 Atomi
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2.6. Atomic relaxation 67 two vacan
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Chapter 3 Electron and positron int
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3.1. Elastic collisions 71 nucleus
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3.1. Elastic collisions 73 1 E - 1
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ρ ρ ρ λ λ λ ρ ρ ρ λ λ λ
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3.1. Elastic collisions 77 becomes
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B ' B ' 3.1. Elastic collisions 79
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3.2. Inelastic collisions 81 where
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3.2. Inelastic collisions 83 global
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3.2. Inelastic collisions 85 plays
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3.2. Inelastic collisions 87 optica
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3.2. Inelastic collisions 89 The DC
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3.2. Inelastic collisions 91 In the
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3.2. Inelastic collisions 93 where
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c b c b 3.2. Inelastic collisions 9
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A l A u 3.2. Inelastic collisions 9
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3.2. Inelastic collisions 99 After
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3.2. Inelastic collisions 101 Table
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3.2. Inelastic collisions 103 In re
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3.2. Inelastic collisions 105 1Ε+4
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3.3. Bremsstrahlung emission 107 an
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3.3. Bremsstrahlung emission 109 1
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3.3. Bremsstrahlung emission 111 1
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3.3. Bremsstrahlung emission 113 wh
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3.3. Bremsstrahlung emission 115 Al
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3.3. Bremsstrahlung emission 117 Th
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3.4. Positron annihilation 119 (198
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3.4. Positron annihilation 121 It i
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Chapter 4 Electron/positron transpo
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4.1. Elastic scattering 125 Lewis (
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4.1. Elastic scattering 127 ⎡ ⎛
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4.1. Elastic scattering 129 simulat
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4.1. Elastic scattering 131 The sim
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4.2. Soft energy losses 133 soft in
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4.2. Soft energy losses 135 deviati
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4.2. Soft energy losses 137 scatter
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4.3. Combined scattering and energy
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4.4. Generation of random tracks 14
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Chapter 5 Constructive quadric geom
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5.1. Rotations and translations 155
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5.2. Quadric surfaces 157 Given a f
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5.2. Quadric surfaces 159 Table 5.1
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5.3. Constructive quadric geometry
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5.4. Geometry definition file 163 1
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5.4. Geometry definition file 165
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5.5. The subroutine package pengeom
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5.5. The subroutine package pengeom
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5.6. Debugging and viewing the geom
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5.7. A short tutorial 173 MODULE (
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5.7. A short tutorial 175 Writing a
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Chapter 6 Structure and operation o
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6.1. penelope 179 and/or numbers in
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6.1. penelope 181 1986). The format
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Page 197 and 198: 6.1. penelope 185 that has to be lo
Page 199 and 200: G y y y y y 6.1. penelope 187 CALL
Page 201 and 202: 6.1. penelope 189 It is the respons
Page 203 and 204: 6.2. Examples of MAIN programs 191
Page 213 and 214: 6.3. Selecting the simulation param
Page 215 and 216: ! 6.3. Selecting the simulation par
Page 217 and 218: 6.5. Installation 205 radiation is
Page 219 and 220: 6.5. Installation 207 To get the ex
Page 221 and 222: Appendix A Collision kinematics To
Page 223 and 224: A.1. Two-body reactions 211 Clearly
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Page 227 and 228: m A.2. Inelastic collisions of char
Page 229 and 230: Appendix B Numerical tools B.1 Cubi
Page 231 and 232: B.1. Cubic spline interpolation 219
Page 233 and 234: B.2. Numerical quadrature 221 B.2 N
Page 235 and 236: Appendix C Electron/positron transp
Page 237 and 238: C.1. Tracking particles in vacuum.
Page 239 and 240: C.1. Tracking particles in vacuum.
Page 241 and 242: C.2. Exact tracking in homogeneous
Page 243 and 244: C.2. Exact tracking in homogeneous
Page 245: Bibliography Abramowitz M. and I.A.
Page 249 and 250: Bibliography 237 James F. (1990),
Page 251 and 252: Bibliography 239 Reimer L. and E.R.
Page 253: Bibliography 241 Yates A.C. (1968),
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