THE EGS5 CODE SYSTEM

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[44] E. Casnati, A. Tartari, and C. Baraldi. An empirical approach to K-shell ionisation cross section by electrons. J. Phys. B, 16:505, 1983. [45] A. Clark (Lawrence Berkeley Laboratory). Private communication with W. R. Nelson and R. L. Ford, August 1977. [46] H. M. Colbert. SANDYL: A computer program for calculating combined photon-electron transport in complex systems. Report SCL-DR-720109, Sandia Laboratories, Livermore, CA, 1973. [47] M. Conti, A. Del Guerra, D. Mazzei, P. Russo, W. Bencivelli, E. Bartolucci, A. Messineo, V. Rosso, A. Stefanini, U. Bottigli, P. Randaccio, and W. R. Nelson. Use of the EGS4 Monte Carlo code to evaluate the response of HgI 2 and CdTe detectors for photons in the diagnostic energy range. Nucl. Instrum. Meth. A, 322:591–595, 1992. [48] A. J. Cook. Mortran3 user’s guide. Technical Memorandum CGTM 209, SLAC Computation Research Group, 1983. [49] H. Davies, H. A. Bethe, and L. C. Maximon. Theory of bremsstrahlung and pair production. II. Integral cross section for pair production. Phys. Rev., 92:788, 1954. [50] C. M. Davisson and R. D. Evans. Gamma-ray absorption coefficients. Rev. Mod. Phys., 24:79–107, 1952. [51] A. Del Guerra, W. R. Nelson, and P. Russo. A simple method to introduce K-edge sampling for compounds in the code EGS4 for X-ray element analysis. Nucl. Instrum. Meth. A, 306:378– 385, 1991. [52] S. Duane, A. F. Bielajew, and D. W. O. Rogers. Use of ICRU-37/NBS collision stopping powers in the EGS4 system. Report PIRS-0173, National Research Council of Canada, 1989. [53] R. D. Evans. The Atomic Nucleus. McGraw-Hill, New York, 1955. [54] B. A. Faddegon, C. K. Ross, and D. W. O. Rogers. Angular distribution of bremsstrahlung from 15 MeV electrons incident on thick targets of Be, Al and Pb. Med. Phys., 18:727–739, 1991. [55] E. L. Feinberg and I. Pomeranchuk. High energy inelastic diffraction phenomena. Nuovo Cimento, 3:652, 1956. [56] J. M. Fernández-Varea, R. Mayol, J. Baró, and F. Salvat. On the theory and simulation of multiple elastic scattering of electrons. Nucl. Instrum. Meth. B, 73:447–473, 1993. [57] R. B. Firestone and V. S. Shirley, editors. Table of Isotopes. Wiley & Sons, New York, 8th edition, 1996. [58] J. Fischer. Beiträge zur Theorie der Absorption von Röntgenstrahlen. Ann. Physik, 8:821– 850, 1931. 412
[59] K. Flöttmann. Investigations toward the development of polarized and unpolarized high intensity positron sources for linear colliders . Report DESY-93-161, Deutsches Elektronen- Synchrotron, 1993. Dissertation zur Erlangung des Doktorgrades des Fachbereichs Physik der Universität Hamburg. [60] R. L. Ford, B. L. Beron, R. L. Carrington, R. Hofstadter, E. B. Hughes, G. I. Kirkbridge, L. H. O’Neill, and J. W. Simpson. Performance of large, modularized NaI(Tl) detectors . Report HEPL-789, Stanford University High Energy Physics Laboratory, 1976. [61] R. L. Ford and W. R. Nelson. The EGS code system: Computer programs for the Monte Carlo simulation of electromagnetic cascade showers (version 3). Report SLAC-210, Stanford Linear Accelerator Center, 1978. [62] M. L. Goldberger. The interaction of high energy neutrons and heavy nuclei. Phys. Rev., 74:1269–1277, 1948. [63] S. A. Goudsmit and J. L. Saunderson. Multiple scattering of electrons. Phys. Rev., 57:24–29, 1940. [64] S. A. Goudsmit and J. L. Saunderson. Multiple scattering of electrons. II. Phys. Rev., 58:36–42, 1940. [65] M. Gryziński. Classical theory of atomic collisions. I. Theory of inelastic collisions. Phys. Rev. A, 138:336–358, 1965. [66] M. Gryziński. Two-particle collisions. I. General relations for collisions in the laboratory system. Phys. Rev. A, 138:305–321, 1965. [67] M. Gryziński. Two-particle collisions. II. Coulomb collisions in the laboratory system of coordinates. Phys. Rev. A, 138:322–335, 1965. [68] J. A. Halbleib, Sr., and W. H. Vandevender. CYLTRAN. Nucl. Sci. Eng., 61:288–289, 1976. [69] P. R. Halmos. Measure Theory. Van Nostrand Co., Princeton, NJ, 1950. [70] J. H. Hammersley and D. C. Handscomb. Monte Carlo Methods. Wiley & Sons, New York, 1964. [71] W. Heitler. The Quantum Theory of Radiation. Clarendon Press, Oxford, 1954. [72] H. Hirayama and Y. Namito. Implementation of a general treatment of photoelectric-related phenomena for compounds or mixtures in EGS4. KEK Internal 2000-3, High Energy Accelerator Research Organization, Japan, 2000. [73] H. Hirayama and Y. Namito. Implementation of a general treatment of photoelectric-related phenomena for compounds or mixtures in EGS4 (revised version). KEK Internal 2004-6, High Energy Accelerator Research Organization, Japan, 2004. [74] H. Hirayama, Y. Namito, and S. Ban. Effects of linear polarisation and Doppler broadening on the exposure buildup factors of low-energy gamma rays. KEK Preprint 93-186, National Laboratory for High Energy Physics, Japan, 1994. 413
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THE EGS5 CODE SYSTEM 1 Hideo Hiraya
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Contents 1 INTRODUCTION 1 1.1 Inten
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2.15.6 Electron Step-Size Selection
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B.4.9 Output of Results (Step 9) .
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List of Figures 2.1 Program flow an
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C.4 Subprogram relationships in PEG
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B.5 Variable descriptions for COMMO
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PREFACE In the nineteen years since
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Chapter 1 INTRODUCTION 1.1 Intent o
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“shower book”. For various reas
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1.2.2 EGS1 About this time Nelson b
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MSCAT. These versions of EGS, PEGS,
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ten for energies less than 100 MeV
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- Molière multiple scattering (i.e
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EGS5. The primary advantages of thi
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ICRU37-compliant using the NIST dat
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high Z materials. Del Guerra et al.
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One of these six cross sections is
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at low energies. The latter, couple
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If E 1 and E 2 are expressions invo
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The result of this algorithm is tha
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2.4 Particle Transport Simulation T
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from appropriate distribution funct
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parameters which may be needed. The
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arrived at their values in a very m
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Math FORTRAN Program Table 2.1 (con
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Figure 2.2: Feynman diagrams for br
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defined by δ ij = 1 if i = j, 0 ot
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Davies, Bethe and Maximon[49] (e.g.
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cross section given in Equation 2.4
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and use this as the variable to be
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we have Now define δ ′ = ∆ C
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This agrees with formula (10) of Bu
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That is, using Equations 2.122 and
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d˘Σ P air, Run−time dE = [ 2 3
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Angular distribution formulas The f
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at either x = 0, x = (πE 0 ) 2 (i.
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The following table, derived from t
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Figure 2.3: Feynman diagrams for tw
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where X 0 = radiation length (cm),
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where α ′ 1 = α ′ 2 = k 0 ′
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+ 1 E 2 ′ − 1 E 1 ′ − C 2 l
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PEGS functions BHABDM, BHABRM, and
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To find the limits of E, we first c
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Figure 2.5: Feynman diagram for sin
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Ī adj = average adjusted mean ioni
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Table 2.2 (cont.) Z Symbol Atomic D
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Table 2.3 (cont.) LABEL a m s x 0 x
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(c) If 10.5 ≤ −C < 11.0 then x
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obtain the real scattering angle. E
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ρ = material mass density (g/cm 3
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Hence, so that ln [1.13 + 3.76(αZ
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g 3 (θ) = θ4 ( ) λf (0) (θ) + f
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Actually, b = 0 does not correspond
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Assume that an electron starts off
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At small path lengths t, a very lar
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x Final Direction φ Θ ∆x t Init
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shown that this version of the rand
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and as we noted earlier, they are d
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Final Direction x Energy Hinges φ
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Transport Steps, ∆ E = E x ESTEPE
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tranport step 1 DEINITIAL1 DERESID1
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= ∆E ( ∣ ∣∣∣ dE −1 ∣
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Since the CSDA range is uniquely de
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short steps accurate, but slow step
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Table 2.4: Materials used in refere
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Average Lateral Displacement (cm) 0
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100 MeV Electrons 0.01 0.001 Li C L
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actions involving photons with ener
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Cu 40 keV Counts (/keV/sr/source) 1
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Table 2.6: Data sources for general
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2.16.2 Photoelectron Angular Distri
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where r 0 is the classical electron
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second term on the right-hand side
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Z θ k Y O φ e 0 X k 0 Figure 2.23
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Note the similarities and differenc
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X Z ω k 0 O e 0 Y Figure 2.25: Dir
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W = Atomic, molecular and mixture w
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In order to use EGS5 to answer the
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write(6,100) 100 FORMAT(’ PEGS5-c
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! plate is 1 mm thick !------------
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implicit none include ’include/eg
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0.989 MeV kinetic energy Brem photo
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! locally (in fact EDEP = particles
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inmax=max(binmax,ebin(j)) end do wr
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0.40 0.0058 * 0.60 0.0054 * 0.80 0.
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!----------------------------------
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endif if(loop.lt.3) then write(6,12
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180 FORMAT(/’ Knock-on electrons
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common/score/escore(3), iscore(3) r
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Brem photons can be created and any
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in any combination of 31 well speci
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end do end do ! nmed and dunit defa
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! ------------------------------ cl
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if (iarg.eq.17) then ! A Compton sc
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! the general purpose geometry subr
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eturn end !------------------------
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open(UNIT= 6,FILE=’egs5job.out’
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write(6,130) 130 format(/’ Start
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icol= * int(dlog10(ebin(j)*10000.0/
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0.0300 0.0000* 0.0320 0.0001* 0.034
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0.0780 0.0014 * 0.0800 0.0012 * 0.0
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The main purpose of this section, h
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4.1.3 Leading Particle Biasing The
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• Sum the weighted energy deposit
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4 z 6 Vac 11 5 Pb 6 5 Air 7 4 9 10
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Figure 4.3: UCBEND simulation at 3.
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necessary geometry input. The follo
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Appendix A EGS5 FLOW DIAGRAMS Hideo
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subroutine annih Version 051219-143
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¡ eq 1 anormr = 1./sqrt(anorm2) si
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1 br = max(br,0.D0) ekse2 = br*ekin
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1 2 3 br = br*p esg = eie*br yes es
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¤ ne ¤ ne subroutine collis (lele
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¦ ne ¦ ne call ausgab(iarg) 6 iq(
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subroutine compt Version 051219-143
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3 4 5 6 icprof(medium) .eq. 3 no ye
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subroutine counters_out Version 051
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1 2 3 4 5 6 7 no ii .ne. jj yes no
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© ne 1 2 3 neispl = (2*neispl + 1)
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subroutine electr(ircode) ielectr =
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7 8 9 10 11 12 13 detot = e(np)-ecu
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2324 25 26 27 28 29 30 ustep .gt. d
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4142 43 44 45 46 47 48 49 ecut(irne
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5859 60 61 62 63 64 tmscat .eq. 0.0
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73 74 75 76 no edep .lt. e(np) yes
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subroutine hardx (charge,kEnergy,ke
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1 2 3 4 5 iz = izz iz .eq. 0 no xsi
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13 14 15 16 17 sint .ne. 0. yes rde
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19 im=1 im=im+1 im >nmed no yes no
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22 23 write(kmpo,1610) read(kmpi,12
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26 27 28 iprofm(im) .ne. 1 no yes w
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30 31 32 33 34 esig0(i,im) = esig0(
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36 37 38 no iedgfl(ii).ne.0 .or. ia
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no kaug .eq. 6 call lshell(3) kaug.
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subroutine kxray Version 051219-143
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1 2 3 dfl3aug(5,iz) .eq. 0. no naug
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1 2 3 4 rnnow .le. omegal2(iz) + f2
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1 2 dflx3(6,iz) .eq. 0. no nxray=nx
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1 impacr(ir(np)).eq.1 .and. iedgfl(
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1 2 fject = (ktot - k1grd(iprt,ik1)
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5 6 7 8 9 thr = 1./eta "Central cor
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1 2 3 delta = delcm(medium)*del "Re
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8 9 10 11 12 galpha .ge. 0.0 yes no
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subroutine photo Version 051219-143
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4 5 6 7 8 rnnow .le. pbran(i) no ye
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12 13 14 beta = sqrt((eelec - RM)*(
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subroutine photon Version 051219-14
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6 7 8 9 10 idisc .gt. 0 yes no edep
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17 18 19 20 21 iausfl(iarg+1) ne 0
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27 28 iausfl(iarg+1) ne 0 no ircod
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subroutine rk1 Version 060313-0945
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4 5 6 j=1 j=j+1 j>neke-1 no yes j .
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18 19 20 21 22 23 elkeold = elke k1
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1 2 "end of file; go to 13" read(17
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4 5 "go to 30" no abs(k1mine-k1grd(
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7 8 read(17,'(72a1)') buffer read(1
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subroutine shower (iqi,ei,xi,yi,zi,
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subroutine uphi(ientry,lvl) Version
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subroutine randomset(rndum) Version
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subroutine rluxinit Version 051219-
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1 i=1 i=i+1 i>24 no yes seeds(i) =
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subroutine rluxin Version 051219-14
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Appendix B EGS5 USER MANUAL Hideo H
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Table B.1: Variable descriptions fo
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Table B.12: Variable descriptions f
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Optional parameter modifications Th
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the call to PEGS5 may be skipped if
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egions. Execution of EGS5 is termin
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of the transport in the walls of el
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call rluxinit after specifying LUXL
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END OF FILE ON UNIT 12 PROGRAM STOP
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do i=1,ncases uf(1)=ufi vf(1)=vfi w
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crossed, then USTEP should be set t
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subroutine howfar implicit none inc
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Table B.18: IARG values program sta
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As an example of how to write an AU
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!**********************************
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nreg=3 do i=2,nreg ecut(i)=100.0 pc
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nlines=0 nwrite=15 !---------------
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if (nlines.lt.nwrite) then write(6,
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Appendix C PEGS USER MANUAL Hideo H
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is entered. On each pass through th
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(from previous figure) (to previous
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(from previous figure) | | + ------
Page 377 and 378: +------+ |BREMTR| +------+ | V +---
Page 379 and 380: +------+ |PAIRTR| +------+ | V +---
Page 381 and 382: Name DCSLOAD DCSSTOR DCSTAB ELASTIN
Page 383 and 384: Name AFFACT AINTP ALKE ALKEI ALIN A
Page 385 and 386: Table C.5: Functions in PEGS, part
Page 387 and 388: +------+ +------+ +------+ +------+
Page 389 and 390: Table C.8: ELEM option input data l
Page 391 and 392: Table C.10: MIXT option input data
Page 393 and 394: Table C.12: PWLF option input data
Page 395 and 396: Table C.17: PLTN option input data
Page 397 and 398: ICPROF is set to 3, the user must c
Page 399 and 400: Column Line 12345678911234567892123
Page 401 and 402: interiors of the intervals. If FEXA
Page 403 and 404: C.3.6 The TEST Option The TEST opti
Page 405 and 406: C.3.9 The HPLT Option The Histogram
Page 407 and 408: Appendix D EGS5 INSTALLATION GUIDE
Page 409 and 410: egs5 directory (preferably using th
Page 411 and 412: 6. The user is then asked to key-in
Page 413 and 414: * User code tutor1.f has been compi
Page 415 and 416: Appendix E CONTENTS OF THE EGS5 DIS
Page 417 and 418: All of the actual FORTRAN source co
Page 419 and 420: aprime.data Data for empirical brem
Page 421 and 422: eryllium iron silicon bismuth krypt
Page 423 and 424: The tutorial problems and advanced
Page 425 and 426: Bibliography [1] R. G. Alsmiller Jr
Page 427: [28] A. F. Bielajew. HOWFAR and HOW
Page 431 and 432: [92] H. Kolbenstvedt. Simple theory
Page 433 and 434: [123] Y. Namito, H. Hirayama, A. Ta
Page 435 and 436: [156] Y. A. Shreider, editor. The M
Page 437 and 438: Index “shower book”, 37 AE, 28,
Page 439 and 440: Klein-Nishina formula, 62 Landau di
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