THE EGS5 CODE SYSTEM

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Table 2.9: Formulas used in various simulation modes employing detailed treatment of Comptonand Rayleigh scattering.Equation Simulation mode2.430 Compton scattering with LP, σ bC , S(x, Z) and DB.2.431 Compton scattering with LP.2.432 Rayleigh scattering with LP.2.415 Compton scattering with σ bC , S(x, Z) and DB.2.425 Compton scattering with σ bC and S(x, Z).2.426 Compton scattering with σ bC .1. Casnati [43, 44]2. Kolbenstvedt-revised [105]3. Kolbenstvedt-original [92]4. Jakoby [80]5. Gryziński [65] Equation 216. Gryziński-relativistic [65] Equation 23EII is treated as a subset of Møller scattering in EGS, so neither the electron mean-free path northe stopping power are modified when EII is treated. Molecular binding effects are ignored, andelectron impact ionization in L and higher shells is treated as free electron Møller scattering.The ratio of the K-shell EII cross section of J-th element in a material to the Møller scatteringcross section is calculated by the following equation:R(E, J) =∑ Jj=1Σ EII,j (E), (2.446)Σ Moller (E)Σ EII,j (E) = p j σ EII,j (E) ρ N 0W , (2.447)whereR(E, J) = the cumulative distribution function of the ratio of the K-shell EII cross section of theJ-th element in a material to the Møller scattering cross section at electron energy E,Σ Moller (E) = macroscopic Møller scattering cross section at electron energy E,Σ EII,j (E) = macroscopic EII cross section of the j-th element at electron energy E,σ EII,j (E) = microscopic EII cross section of the j-th element at electron energy E,p j = proportion by number of the j-th element in the material,ρ = density of a material,N 0 = Avogadro’s number,138
W = Atomic, molecular and mixture weight for an element, for a compound, and for a mixture.In EGS, K-shell vacancy creation by EII is sampled using R(E, J) values calculated in PEGSand included in the material data file.K-x ray emission and energy deposition After K-shell vacancy creation by EII, emission of K-x rays is sampled using the K-shell fluorescence yield [57], as in the treatment of the photoelectriceffect [73]. However, in the current EGS implementation, neither Auger electron emission noratomic relaxation cascades are modeled for K-shell vacancies generated by EII. K-shell x-ray energiesare sampled from the ten possible lines given in [57], and the difference between the K-shell bindingenergy E B and the emitted x-ray energy is deposited locally. In the case when no x-ray is generated(i.e., an Auger electron emission occurred), the full binding energy E B is deposited locally.Secondary electron energies and angles The energy and direction of ejected electrons followingEII are treated in an approximate manner. The binding energy E B is subtracted at randomfrom the energy of either one of the two electrons after energies have been determined from thestandard Møller scattering analysis. In the case that neither of the two electron has kinetic energygreater than E B , E B is subtracted from the energy of both electrons while keeping the ratio of thekinetic energies unchanged. The directions of electrons after EII are those given from the Møllerscattering collision analysis.139
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THE EGS5 CODE SYSTEM 1Hideo Hirayam
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4.1 UCCYL - Cylinder-Slab Geometry
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E CONTENTS OF THE EGS5 DISTRIBUTION
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2.17 Convergence of energy depositi
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List of Tables2.1 Symbols used in E
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C.2 Goudsmit-Saunderson-related sub
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With the release of the EGS4 versio
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“shower book”.For various reaso
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1.2.2 EGS1About this time Nelson be
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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 SimulationTh
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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 ProgramTable 2.1 (cont
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Figure 2.2: Feynman diagrams for br
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defined byδ ij = 1 if i = j,0 othe
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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 haveNow defineδ ′ = ∆ 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−timedE=[23 − 1
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Angular distribution formulasThe fo
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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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whereX 0 = radiation length (cm),n
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whereα ′ 1 =α ′ 2 =k 0′k 0
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+ 1 E 2′ − 1 E 1′− C 2 ln E
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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 De
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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
Page 103 and 104: Hence,so thatln [1.13 + 3.76(αZ i
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Page 107 and 108: Actually, b = 0 does not correspond
Page 109 and 110: Assume that an electron starts off
Page 111 and 112: At small path lengths t, a very lar
Page 113 and 114: xFinalDirectionφΘ∆xtInitialDire
Page 115 and 116: shown that this version of the rand
Page 117 and 118: and as we noted earlier, they are d
Page 119 and 120: FinalDirectionxEnergy HingesφΘt(
Page 121 and 122: Transport Steps,∆ E = E x ESTEPEt
Page 123 and 124: tranport step 1DEINITIAL1 DERESID1t
Page 125 and 126: = ∆E( ∣ ∣∣∣ dE−1 ∣ )
Page 127 and 128: Since the CSDA range is uniquely de
Page 129 and 130: short steps accurate, but slowstep
Page 131 and 132: Table 2.4: Materials used in refere
Page 133 and 134: Average Lateral Displacement (cm)0.
Page 135 and 136: 100 MeV Electrons0.010.001LiCLWAlST
Page 137 and 138: actions involving photons with ener
Page 139 and 140: Cu 40 keVCounts (/keV/sr/source)10
Page 141 and 142: Table 2.6: Data sources for general
Page 143 and 144: 2.16.2 Photoelectron Angular Distri
Page 145 and 146: where r 0 is the classical electron
Page 147 and 148: second term on the right-hand side
Page 149 and 150: ZθkYOφe0Xk0Figure 2.23: Photon sc
Page 151 and 152: Note the similarities and differenc
Page 153: XZωk0Oe0YFigure 2.25: Direction of
Page 157 and 158: In order to use EGS5 to answer the
Page 159 and 160: write(6,100)100 FORMAT(’ PEGS5-ca
Page 161 and 162: ! plate is 1 mm thick!-------------
Page 163 and 164: implicit noneinclude ’include/egs
Page 165 and 166: 0.989 MeV kinetic energyBrem photon
Page 167 and 168: ! locally (in fact EDEP = particles
Page 169 and 170: inmax=max(binmax,ebin(j))end dowrit
Page 171 and 172: 0.40 0.0058 *0.60 0.0054 *0.80 0.00
Page 173 and 174: !----------------------------------
Page 175 and 176: endifif(loop.lt.3) thenwrite(6,120)
Page 177 and 178: 180 FORMAT(/’ Knock-on electrons
Page 179 and 180: common/score/escore(3), iscore(3)re
Page 181 and 182: Brem photons can be created and any
Page 183 and 184: in any combination of 31 well speci
Page 185 and 186: end doend do! nmed and dunit defaul
Page 187 and 188: ! ------------------------------clo
Page 189 and 190: if (iarg.eq.17) then! A Compton sca
Page 191 and 192: ! the general purpose geometry subr
Page 193 and 194: eturnend!--------------------------
Page 195 and 196: open(UNIT= 6,FILE=’egs5job.out’
Page 197 and 198: write(6,130)130 format(/’ Start t
Page 199 and 200: icol=* int(dlog10(ebin(j)*10000.0/f
Page 201 and 202: 0.0300 0.0000*0.0320 0.0001*0.0340
Page 203 and 204: 0.0780 0.0014 *0.0800 0.0012 *0.082
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The main purpose of this section, h
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4.1.3 Leading Particle BiasingThe s
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• Sum the weighted energy deposit
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4z6Vac115Pb65Air749 1012AirAir8Vac
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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 AEGS5 FLOW DIAGRAMSHideo H
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subroutineannihVersion051219-1435ia
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¡eq1anormr = 1./sqrt(anorm2)sineta
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1br = max(br,0.D0)ekse2 = br*ekines
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12 3br = br*pesg = eie*bryesesg.lt.
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¤ne¤nesubroutinecollis(lelec,irl,
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¦ne¦necallausgab(iarg)6iq(np).eq.
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subroutinecomptVersion051219-1435ic
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3456icprof(medium).eq.3noyescallran
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subroutinecounters_outVersion051227
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1234567noii.ne.jjyesnoledgb(ii,medi
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©ne1 2 3neispl = (2*neispl + 1)/3f
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subroutineelectr(ircode)ielectr = i
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7 8 9 10 11 12 13detot = e(np)-ecut
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2324 25 26 27 282930ustep.gt.dnear(
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4142 43 44 45 4647 48 49ecut(irnew)
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5859 60 61 6263 64tmscat.eq.0.0noye
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73 7475 76noedep.lt.e(np)yescallran
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subroutinehardx(charge,kEnergy,keIn
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1 2 3 4 5iz = izziz.eq.0noxsi = zer
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13 14 15 16 17sint.ne.0.yesrdev = m
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19im=1im=im+1im >nmednoyesnoiprofm(
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2223write(kmpo,1610)read(kmpi,1260)
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26 27 28iprofm(im).ne.1noyeswrite(6
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30 31 32 33 34esig0(i,im) = esig0(i
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36 37 38noiedgfl(ii).ne.0.or.iauger
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nokaug.eq.6calllshell(3)kaug.eq.7ka
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subroutinekxrayVersion051219-1435ik
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123dfl3aug(5,iz).eq.0.nonauger = na
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12 3 4rnnow.le.omegal2(iz) + f23(iz
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1 2dflx3(6,iz).eq.0.nonxray=nxray+1
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1impacr(ir(np)).eq.1.and.iedgfl(ir(
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12fject = (ktot - k1grd(iprt,ik1))
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56789thr = 1./eta"Central correctio
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1 2 3delta = delcm(medium)*del"Reje
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89101112galpha.ge.0.0yesnoximid = 0
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subroutinephotoVersion051219-1435"C
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4 5 6 7 8rnnow.le.pbran(i)noyesiz =
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121314beta = sqrt((eelec - RM)*(eel
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subroutinephotonVersion051219-1435i
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678910idisc.gt.0yesnoedep = 0.iarg
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1718192021iausfl(iarg+1)ne0nocallpa
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2728iausfl(iarg+1)ne0noircode = 2np
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subroutinerk1Version060313-0945open
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4 5 6j=1j=j+1j>neke-1noyesj.eq.1noj
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18 19 20 21 22 23elkeold = elkek1ol
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1 2"end of file; go to 13"read(17,*
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4 5"go to 30"noabs(k1mine-k1grd(1,1
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7 8read(17,'(72a1)') bufferread(17,
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subroutine shower(iqi,ei,xi,yi,zi,u
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subroutineuphi(ientry,lvl)Version05
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subroutinerandomset(rndum)Version05
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subroutinerluxinitVersion051219-143
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1i=1i=i+1i>24noyesseeds(i) = real(i
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subroutinerluxinVersion051219-1435w
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Appendix BEGS5 USER MANUALHideo Hir
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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 modificationsThe
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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 rluxinitafter specifying LUXLE
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END OF FILE ON UNIT 12PROGRAM STOPP
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do i=1,ncasesuf(1)=ufivf(1)=vfiwf(1
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crossed, then USTEP should be set t
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subroutine howfarimplicit noneinclu
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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=3do i=2,nregecut(i)=100.0pcut(
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nlines=0nwrite=15!-----------------
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if (nlines.lt.nwrite) thenwrite(6,1
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Appendix CPEGS USER MANUALHideo Hir
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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)||+ ---------
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+------+|BREMTR|+------+|V+------+|
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+------+|PAIRTR|+------+|V+------+|
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NameDCSLOADDCSSTORDCSTABELASTINOELI
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NameAFFACTAINTPALKEALKEIALINALINIAD
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Table C.5: Functions in PEGS, part
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+------+ +------+ +------+ +------+
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Table C.8: ELEM option input data l
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Table C.10: MIXT option input data
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Table C.12: PWLF option input data
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Table C.17: PLTN option input data
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ICPROF is set to 3, the user must c
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ColumnLine 123456789112345678921234
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interiors of the intervals. If FEXA
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C.3.6The TEST OptionThe TEST option
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C.3.9The HPLT OptionThe Histogram P
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Appendix DEGS5 INSTALLATION GUIDEHi
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egs5 directory (preferably using th
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6. The user is then asked to key-in
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* User code tutor1.f has been compi
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Appendix ECONTENTS OF THE EGS5DISTR
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All of the actual FORTRAN source co
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aprime.data Data for empirical brem
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ismuth krypton silverboron lanthanu
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The tutorial problems and advanced
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Bibliography[1] R. G. Alsmiller Jr.
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[28] A. F. Bielajew. HOWFAR and HOW
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[59] K. Flöttmann. Investigations
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[92] H. Kolbenstvedt. Simple theory
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[123] Y. Namito, H. Hirayama, A. Ta
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[156] Y. A. Shreider, editor. The M
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Index“shower book”, 37AE, 28, 3
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Klein-Nishina formula, 62Landau dis
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