1 *====================================================================* * * * * * * * * * FFFFF L U U K K AAA 222 000 11 11 * * F L U U K K A A 2 2 0 0 111 111 * * F L U U K K A A 2 0 0 1111 1111 * * FFFF L U U KK AAAAA == 2 0 0 11 11 * * F L U U K K A A 2 0 0 11 11 * * F L U U K K A A 2 0 0 11 11 * * F LLLLL UUU K K A A 22222 000 11111 11111 * * * * * * * * Version of Fluka2011 for GNU/Linux operating system * * * * By : * * * * Alfredo Ferrari & Paola Sala INFN Milan & CERN/EN * * * * Alfredo.Ferrari@cern.ch Paola.Sala@mi.infn.it * * * * * * Alberto Fasso` Jefferson Lab, Newport News * * * * afasso@jlab.org * * * * * * Johannes Ranft Siegen University * * * * Johannes.Ranft@cern.ch * * * * * * * * This version includes all the features of the Fluka2011 * * * * package * * * * * * * *====================================================================* FLUKA User license COPYRIGHT NOTICE AND LICENSE CONDITIONS Copyright Italian National Institute for Nuclear Physics (INFN) and European Organization for Nuclear Research (CERN), 1989-2011. All rights not expressly granted under this license are reserved. Requests for permissions not granted under this license shall be addressed to the FLUKA Collabora- tion Committee, through fcc@fluka.org. Any permission may only be granted in writing. This software results in particular from work performed by Alberto Fassò, Alfredo Ferrari, Johannes Ranft, Paola Sala (the "Authors"), and their collaborators (the "Collaborators"). INFN and CERN are the exclusive source of distribution of the code, bug fixes and documentation of the FLUKA software (FLUKA website), and may authorise distribution by mirror sites. This license cancels and replaces any prior license conditions but their warranty and liability provisions shall continue to apply to any use or modifications made under such prior license conditions. DEFINITIONS The FLUKA software ("FLUKA") means the fully integrated particle physics Monte Carlo simulation software package being developed since 1989, available from the official FLUKA website (http://www.fluka.org) and authorised mirror sites. FLUKA is made up of FLUKA core code and FLUKA User Routines. The FLUKA Copyright Holders means both CERN and INFN. FLUKA User Routines means the set of subroutines collected in the usermvax section of FLUKA and forming part of the standard distribution of FLUKA. The Licensee means any person acting individually within a non-profit organisation, exercising any permission granted by this license. LICENSE GRANT 1. Subject to the terms and conditions of this license, the FLUKA Copyright Holders herewith grant to the Licensee a worldwide, non-exclusive, royalty-free, source and object code license to use and reproduce FLUKA for internal scientific non commercial non-military purposes only. Notwithstanding the foregoing, the Licensee shall not execute FLUKA in a manner that produces an output whose contents are directly useable or easily employable to simulate the physics models embedded within FLUKA in a generic manner, or excise portions of FLUKA source or object code, and execute them independently of FLUKA. Extracting specific isolated results from any of the individual internal physics models embedded within FLUKA is not permitted. Permitted use and reproduction are referred to below as "Use". 2. Modification (including translation) of FLUKA, in whole or in part, is not permitted, except for modification of FLUKA User Routines that do not circumvent, replace, add to or modify any of the functions of the FLUKA core code. Permitted modifications are referred to below as "Modifications". 3. FLUKA is licensed for Use by the Licensee only, and the Licensee shall not market, distribute, transfer, license or sub-license, or in any way make available ("Make Available") FLUKA or Modifications, in whole or in part, to third parties, without prior written permission. The Licensee shall not assign or transfer this license. 4. Notwithstanding section 3, the Licensee may Make Available his Modifications of FLUKA User Routines to third parties under these license conditions. 5. The Licensee shall not insert FLUKA code or Modifications, in whole or in part, into other codes without prior written permission. 6. Any use of FLUKA outside the scope of this license is subject to prior written permission. GRANT BACK 7. The Licensee shall in a timely fashion notify to fcc@fluka.org any Modifications carried out by him. Except for Authors, Collaborators, and employees of the FLUKA Copyright Holders, the copyright in whose Modifications shall automatically be vested in the FLUKA Copyright Holders, the Licensee herewith grants the FLUKA Copyright Holders a perpetual, royalty- free, irrevocable and non-exclusive license to his Modifications, with no limitation of use. The Licensee acknowledges that the FLUKA Copyright Holders may insert such Modifications into future releases of FLUKA, subject to appropriate acknowledgment of the Licensee's contribution. 8. The Licensee shall report as soon as practical any errors or bugs found in any portion of FLUKA to fluka-discuss@fluka.org PUBLICATIONS AND ACKNOWLEDGEMENT 9. The Licensee shall explicitly acknowledge his use of FLUKA in any publication or communication, scientific or otherwise, relating to such use, by citing the FLUKA set of references (http://www.fluka.org, see below) and the FLUKA copyright notice. 10. The Licensee shall ensure that the FLUKA set of references, the FLUKA copyright notice and these license conditions are not altered or removed from FLUKA and that all embodiments of FLUKA and Modifications contain in full the FLUKA set of references, the FLUKA copyright notice, and these license conditions. 11. Any insertion of FLUKA code or Modifications, in whole or in part, into other codes with permission under section 5 shall preserve the FLUKA set of references, the FLUKA copyright notice and these license conditions in the FLUKA code or Modifications concerned, and must also reproduce these within any additional global notices included along or embedded within the software into which the FLUKA code or the Modifications have been integrated, in whole or in part. Any part of the FLUKA code or Modifications so inserted shall continue to be subject to these license conditions. 12. Publication of any results of comparisons of specific internal physics models extracted from FLUKA with permission under section 6 with data or with other codes or models is subject to prior written permission. 13. Contributions to any formal code comparisons and validation exercises pertaining to FLUKA, sponsored by recognised bodies or within the framework of recognised conferences and workshops, are subject to prior written permission. WARRANTY AND LIABILITY 14. DISCLAIMER FLUKA IS PROVIDED BY THE FLUKA COPYRIGHT HOLDERS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY, OF SATISFACTORY QUALITY, AND FITNESS FOR A PARTICULAR PURPOSE OR USE ARE DISCLAIMED. THE FLUKA COPYRIGHT HOLDERS AND THE AUTHORS MAKE NO REPRESENTATION THAT FLUKA AND MODIFICATIONS THEREOF WILL NOT INFRINGE ANY PATENT, COPYRIGHT, TRADE SECRET OR OTHER PROPRIETARY RIGHT. 15. LIMITATION OF LIABILITY THE FLUKA COPYRIGHT HOLDERS AND ANY CONTRIBUTOR SHALL HAVE NO LIABILITY FOR DIRECT, INDIRECT, SPECIAL, INCIDENTAL, CONSEQUENTIAL, EXEMPLARY, PUNITIVE OR OTHER DAMAGES OF ANY CHARACTER INCLUDING, WITHOUT LIMITATION, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES, LOSS OF USE, DATA OR PROFITS, OR BUSINESS INTERRUPTION, HOWEVER CAUSED AND ON ANY THEORY OF CONTRACT, WARRANTY, TORT (INCLUDING NEGLIGENCE), PRODUCT LIABILITY OR OTHERWISE, ARISING IN ANY WAY OUT OF THE USE OF FLUKA, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGES, AND THE LICENSEE SHALL HOLD THE COPYRIGHT HOLDERS AND ANY CONTRIBUTOR FREE AND HARMLESS FROM ANY LIABILITY, INCLUDING CLAIMS BY THIRD PARTIES, IN RELATION TO SUCH USE. TERMINATION 16. This license shall terminate with immediate effect and without notice if the Licensee fails to comply with any of the terms of this license, or if the Licensee initiates litigation against any of the FLUKA Copyright Holders or any contributors with regard to FLUKA. It shall also terminate with immediate effect from the date on which a new version of FLUKA becomes available. In either case sections 14 and 15 above shall continue to apply to any Use or Modifications made under these license conditions. FLUKA set of references, subject to change "The FLUKA code: Description and benchmarking" G. Battistoni, S. Muraro, P.R. Sala, F. Cerutti, A. Ferrari, S. Roesler, A. Fasso`, J. Ranft, Proceedings of the Hadronic Shower Simulation Workshop 2006, Fermilab 6--8 September 2006, M.Albrow, R. Raja eds., AIP Conference Proceeding 896, 31-49, (2007) "FLUKA: a multi-particle transport code" A. Fasso`, A. Ferrari, J. Ranft, and P.R. Sala, CERN-2005-10 (2005), INFN/TC_05/11, SLAC-R-773 Additional FLUKA references can be added, provided they are relevant for the FLUKA version under consideration. !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! !!!! DOWNLOAD/USE OF THE FLUKA SOFTWARE IMPLIES FULL !!!! !!!! ACCEPTANCE AND COMPLIANCE WITH THE LICENSE !!!! !!!! CONDITIONS !!!! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! Note: The Nuclear Energy Agency Data Bank is an authorized distributor of the code 1 **************************************************************************************************** FLUKA2011 Version 2.17 Dec-12 by A. Ferrari DATE: 8/31/13 TIME: 10:54:11 **************************************************************************************************** ***** Next control card ***** TITLE 0.000 0.000 0.000 0.000 0.000 0.000 ***** Next control card ***** GLOBAL 0.000 0.000 0.000 1.000 0.000 0.000 *---------------- Set the defaults for precision simulations ----------------* ***** Next control card ***** DEFAULTS 0.000 0.000 0.000 0.000 0.000 0.000 PRECISIO *---------------- Define the beam characteristics ----------------* *---------------- Define the beam position ----------------* *---------------- ..+....1....+....2....+....3....+....4....+....5....+....6....+....7.. ----------------* *---------------- Set the random number seed ----------------* *---------------- Set the number of primary histories to be simulated in the run ----------------* ***** Next control card ***** BEAM -1.6000E-04 0.000 0.000 0.6000 0.6000 0.000 ELECTRON **** Density scaling factors start at location 1 and end at 4000 (I*4 addr.) **** ***** Next control card ***** BEAMPOS 0.000 0.000 -1.000 0.000 0.000 0.000 ***** Next control card ***** GEOBEGIN 0.000 0.000 0.000 0.000 0.000 0.000 COMBNAME 1 IVLFLG= 0 IDBG = 0 Body data * *--------------- Black body ---------------* * * *--------------- Void sphere ---------------* * SPH blkbody 1 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.10000000E+06 0.00000000E+00 0.00000000E+00 5 SPH void 2 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.10000000E+05 0.00000000E+00 0.00000000E+00 15 RPP light 3 -0.30000000E+00 0.30000000E+00 -0.30000000E+00 0.30000000E+00 0.00000000E+00 0.80000000E-02 25 RPP xiao1 4 -0.25000000E-01 -0.23000000E-01 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 35 RPP xiao2 5 -0.19000000E-01 -0.17000000E-01 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 45 RPP xiao3 6 -0.13000000E-01 -0.11000000E-01 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 55 RPP xiao4 7 -0.70000000E-02 -0.50000000E-02 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 65 RPP xiao5 8 -0.10000000E-02 0.10000000E-02 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 75 RPP xiao6 9 0.50000000E-02 0.70000000E-02 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 85 RPP xiao7 10 0.11000000E-01 0.13000000E-01 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 95 RPP xiao8 11 0.17000000E-01 0.19000000E-01 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 105 RPP xiao9 12 0.23000000E-01 0.25000000E-01 -0.30000000E+00 0.30000000E+00 0.79950000E-02 0.80000000E-02 115 RPP weight 13 -0.30000000E+00 0.30000000E+00 -0.30000000E+00 0.30000000E+00 0.80000000E-02 0.21000000E-01 125 END 14 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 135 Number of bodies 13 Length of FPD-Array 140 Accuracy parameter: 3.89E-04 suggested: 3.89E-04 Detected max. geometry dimension: 1.00E+04 cm Input region data * *--------------- Black hole ---------------* * BLKBODY 5 + blkbody - void * *--------------- Void around ---------------* * VOID 5 + void - light - weight - xiao1 - xiao2 - xiao3 - xiao4 - xiao5 - xiao6 - xiao7 - xiao8 - xiao9 * *--------------- Target ---------------* * target0 5 + light - xiao1 - xiao2 - xiao3 - xiao4 - xiao5 - xiao6 - xiao7 - xiao8 - xiao9 target1 5 + xiao1 target2 5 + xiao2 target3 5 + xiao3 target4 5 + xiao4 target5 5 + xiao5 target6 5 + xiao6 target7 5 + xiao7 target8 5 + xiao8 target9 5 + xiao9 target10 5 + weight END Number of input regions 13 Number of code zones 13 Length of integer array 384 CODE ZONE INPUT REGION ZONE DATA LOC. NO. OF BODIES REGION NO. 1 1 105 2 1 2 2 114 12 2 3 3 163 10 3 4 4 204 1 4 5 5 209 1 5 6 6 214 1 6 7 7 219 1 7 8 8 224 1 8 9 9 229 1 9 10 10 234 1 10 11 11 239 1 11 12 12 244 1 12 13 13 249 1 13 I IR1(I) IR2(I) 1 1 1 2 2 2 3 3 3 4 4 4 5 5 5 6 6 6 7 7 7 8 8 8 9 9 9 10 10 10 11 11 11 12 12 12 13 13 13 Interpreted body echo Body n. 1 SPH blkbody Rot. 0 0.000000 0.000000 0.000000 100000.0 Body n. 2 SPH void Rot. 0 0.000000 0.000000 0.000000 10000.00 Body n. 3 RPP light Rot. 0 -0.3000000 0.3000000 -0.3000000 0.3000000 0.000000 0.8000000E-02 Body n. 4 RPP xiao1 Rot. 0 -0.2500000E-01 -0.2300000E-01 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 5 RPP xiao2 Rot. 0 -0.1900000E-01 -0.1700000E-01 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 6 RPP xiao3 Rot. 0 -0.1300000E-01 -0.1100000E-01 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 7 RPP xiao4 Rot. 0 -0.7000000E-02 -0.5000000E-02 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 8 RPP xiao5 Rot. 0 -0.1000000E-02 0.1000000E-02 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 9 RPP xiao6 Rot. 0 0.5000000E-02 0.7000000E-02 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 10 RPP xiao7 Rot. 0 0.1100000E-01 0.1300000E-01 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 11 RPP xiao8 Rot. 0 0.1700000E-01 0.1900000E-01 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 12 RPP xiao9 Rot. 0 0.2300000E-01 0.2500000E-01 -0.3000000 0.3000000 0.7995000E-02 0.8000000E-02 Body n. 13 RPP weight Rot. 0 -0.3000000 0.3000000 -0.3000000 0.3000000 0.8000000E-02 0.2100000E-01 Interpreted region echo Region n. 1 BLKBODY 1 -2 Region n. 2 VOID 2 -3 -13 -4 -5 -6 -7 -8 -9 -10 -11 -12 Region n. 3 target0 3 -4 -5 -6 -7 -8 -9 -10 -11 -12 Region n. 4 target1 4 Region n. 5 target2 5 Region n. 6 target3 6 Region n. 7 target4 7 Region n. 8 target5 8 Region n. 9 target6 9 Region n. 10 target7 10 Region n. 11 target8 11 Region n. 12 target9 12 Region n. 13 target10 13 All region volumes set to 1 Volumes (cm**3) 1 Reg. 1 2 3 4 5 6 7 8 9 10 Volume 1.000E+00 1.000E+00 1.000E+00 1.000E+00 1.000E+00 1.000E+00 1.000E+00 1.000E+00 1.000E+00 1.000E+00 0NGEOM= 4002, NGLAST= 4892 **** Stars/Energy accumulation arrays start at location 4895 and end at 4998 (I*4 addr.) **** **** Minimum step size array start at location 5001 and end at 5030 (I*4 addr.) **** **** Maximum step size array start at location 5033 and end at 5062 (I*4 addr.) **** GEOEND Total time used for geometry initialization: 4.000E-02 s ***** Next control card ***** MATERIAL 1.000 0.000 8.3700E-05 0.000 0.000 2.000 DEUTERIU ***** Next control card ***** MATERIAL 1.000 0.000 8.3700E-05 0.000 0.000 3.000 TRITIUM ***** Next control card ***** MATERIAL 0.000 0.000 0.2500 0.000 0.000 0.000 DT ***** Next control card ***** COMPOUND 0.5800 26.00 0.4200 27.00 0.000 0.000 DT ***** Next control card ***** RANDOMIZ 1.000 0.000 0.000 0.000 0.000 0.000 RM64 INITIALIZED: 98765 12345 0 0 ***** Next control card ***** ASSIGNMA 1.000 1.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 2.000 2.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 28.00 3.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 4.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 5.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 6.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 7.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 8.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 9.000 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 10.00 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 11.00 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 12.00 0.000 0.000 0.000 0.000 ***** Next control card ***** ASSIGNMA 5.000 13.00 0.000 0.000 0.000 0.000 ***** Next control card ***** USRBIN 10.00 3.000 -30.00 0.4000 0.4000 2.2100E-02 flu ***** Next control card ***** USRBIN -0.4000 -0.4000 2.2000E-02 1.0000E+04 1.0000E+04 1.000 & ***** Next control card ***** START 1.0000E+06 0.000 0.000 0.000 0.000 0.000 Total time used for input reading: 0.00 s **** Power exponent for grey particle correlations set at -13.**** *** Reading evaporation and nuclear data from unit: 14 **** Nuclear data file for Fluka9x-20xy **** File version: 2011.1 Copyright (C) 1990-2011 by Alfredo Ferrari & Paola Sala *** Evaporation: using NNDC (1996) data *** Starting location in blank common of LVL data: 5064 Last location in blank common of LVL data: 9635319 Starting location in blank common of CE data: 9635320 Last location in blank common of CE data: 9686091 Starting location in blank common of alpha data: 9686092 Last location in blank common of alpha data: 9688851 Starting location in blank common of gamma data: 9688852 Last location in blank common of gamma data: 9819799 Starting location in blank common of beta data: 9819800 Last location in blank common of beta data: 9862087 Starting location in blank common of GDR data: 9862088 Last location in blank common of GDR data: 9917142 Starting location in blank common of (g,x) data: 9917143 Last location in blank common of (g,x) data: 10220063 **** RIPL2/Ign. self-cons. T=0 N,Z-dep. level density used **** **** RIPL-2 / Ignyatuk level density en. dep. used **** **** with Moller, Nix self-cons set of parameters for T=oo **** **** Original Gilbert/Cameron pairing energy used **** **** Maximum Fermi momentum : 0.268371314 GeV/c **** **** Maximum Fermi energy : 0.0376013778 GeV **** **** Average Fermi energy : 0.022676846 GeV **** **** Average binding energy : 0.00768006314 GeV **** **** Nuclear well depth : 0.04528144 GeV **** **** Excess mass for 11-B : 0.00866803993 GeV **** **** Cameron E. m. for 11-B : 0.00792484451 GeV **** **** Cam.El. E. m. for 11-B : 0.00851833168 GeV **** **** My.&Sw. E. m. for 11-B : 0.00887639914 GeV **** **** Atomic mass for 11-B : 10.255106 GeV **** **** Nuclear mass for 11-B : 10.2525511 GeV **** **** Excess mass for 12-C : 0. GeV **** **** Cameron E. m. for 12-C : 0.00151353085 GeV **** **** Cam.El. E. m. for 12-C : 0.00163579884 GeV **** **** My.&Sw. E. m. for 12-C : -0.000383192004 GeV **** **** Atomic mass for 12-C : 11.1779318 GeV **** **** Nuclear mass for 12-C : 11.1748667 GeV **** **** Excess mass for 13-C : 0.00312499981 GeV **** **** Cameron E. m. for 13-C : 0.00287424121 GeV **** **** Cam.El. E. m. for 13-C : 0.00348056527 GeV **** **** My.&Sw. E. m. for 13-C : 0.00355792139 GeV **** **** Atomic mass for 13-C : 12.1125507 GeV **** **** Nuclear mass for 13-C : 12.1094866 GeV **** **** Excess mass for 14-N : 0.00286339992 GeV **** **** Cameron E. m. for 14-N : 0.00337313744 GeV **** **** Cam.El. E. m. for 14-N : 0.0036975285 GeV **** **** My.&Sw. E. m. for 14-N : 0.00286558713 GeV **** **** Atomic mass for 14-N : 13.0437841 GeV **** **** Nuclear mass for 14-N : 13.0402088 GeV **** **** Excess mass for 15-O : 0.00285555003 GeV **** **** Cameron E. m. for 15-O : 0.00240658456 GeV **** **** Cam.El. E. m. for 15-O : 0.00259008165 GeV **** **** My.&Sw. E. m. for 15-O : 0.00332844956 GeV **** **** Atomic mass for 15-O : 13.9752703 GeV **** **** Nuclear mass for 15-O : 13.9711847 GeV **** **** Excess mass for 16-O : -0.00473699998 GeV **** **** Cameron E. m. for 16-O : -0.00331055629 GeV **** **** Cam.El. E. m. for 16-O : -0.00319385715 GeV **** **** My.&Sw. E. m. for 16-O : -0.00483116647 GeV **** **** Atomic mass for 16-O : 14.8991718 GeV **** **** Nuclear mass for 16-O : 14.8950863 GeV **** **** Excess mass for 27-Al : -0.0171969198 GeV **** **** Cameron E. m. for 27-Al : -0.0186259765 GeV **** **** Cam.El. E. m. for 27-Al : -0.0171393938 GeV **** **** My.&Sw. E. m. for 27-Al : -0.017145671 GeV **** **** Atomic mass for 27-Al : 25.1331501 GeV **** **** Nuclear mass for 27-Al : 25.1265125 GeV **** **** Excess mass for 28-Si : -0.0214928202 GeV **** **** Cameron E. m. for 28-Si : -0.0220552329 GeV **** **** Cam.El. E. m. for 28-Si : -0.0202140864 GeV **** **** My.&Sw. E. m. for 28-Si : -0.021535717 GeV **** **** Atomic mass for 28-Si : 26.0603485 GeV **** **** Nuclear mass for 28-Si : 26.0532017 GeV **** **** Excess mass for 40-Ca : -0.0348461308 GeV **** **** Cameron E. m. for 40-Ca : -0.0357677415 GeV **** **** Cam.El. E. m. for 40-Ca : -0.0336877368 GeV **** **** My.&Sw. E. m. for 40-Ca : -0.0349160209 GeV **** **** Atomic mass for 40-Ca : 37.224926 GeV **** **** Nuclear mass for 40-Ca : 37.2147255 GeV **** **** Excess mass for 55-Fe : -0.0574751087 GeV **** **** Cameron E. m. for 55-Fe : -0.0595041849 GeV **** **** Cam.El. E. m. for 55-Fe : -0.0580860823 GeV **** **** My.&Sw. E. m. for 55-Fe : -0.0575032495 GeV **** **** Atomic mass for 55-Fe : 51.1747131 GeV **** **** Nuclear mass for 55-Fe : 51.1614609 GeV **** **** Excess mass for 56-Fe : -0.0606013089 GeV **** **** Cameron E. m. for 56-Fe : -0.0623576604 GeV **** **** Cam.El. E. m. for 56-Fe : -0.0608849637 GeV **** **** My.&Sw. E. m. for 56-Fe : -0.0604862086 GeV **** **** Atomic mass for 56-Fe : 52.1030807 GeV **** **** Nuclear mass for 56-Fe : 52.0898285 GeV **** **** Excess mass for 107-Ag: -0.088405259 GeV **** **** Cameron E. m. for 107-Ag: -0.0891378522 GeV **** **** Cam.El. E. m. for 107-Ag: -0.0886852369 GeV **** **** My.&Sw. E. m. for 107-Ag: -0.0882571116 GeV **** **** Atomic mass for 107-Ag: 99.5814896 GeV **** **** Nuclear mass for 107-Ag: 99.5576096 GeV **** **** Excess mass for 132-Xe: -0.0892794058 GeV **** **** Cameron E. m. for 132-Xe: -0.0898088515 GeV **** **** Cam.El. E. m. for 132-Xe: -0.0892864987 GeV **** **** My.&Sw. E. m. for 132-Xe: -0.0894251093 GeV **** **** Atomic mass for 132-Xe: 122.867973 GeV **** **** Nuclear mass for 132-Xe: 122.840576 GeV **** **** Excess mass for 181-Ta: -0.0484412275 GeV **** **** Cameron E. m. for 181-Ta: -0.0481105074 GeV **** **** Cam.El. E. m. for 181-Ta: -0.0478131436 GeV **** **** My.&Sw. E. m. for 181-Ta: -0.0482191741 GeV **** **** Atomic mass for 181-Ta: 168.552032 GeV **** **** Nuclear mass for 181-Ta: 168.515137 GeV **** **** Excess mass for 208-Pb: -0.0217638295 GeV **** **** Cameron E. m. for 208-Pb: -0.0184126478 GeV **** **** Cam.El. E. m. for 208-Pb: -0.020333156 GeV **** **** My.&Sw. E. m. for 208-Pb: -0.0209293775 GeV **** **** Atomic mass for 208-Pb: 193.72905 GeV **** **** Nuclear mass for 208-Pb: 193.687683 GeV **** **** Excess mass for 209-Bi: -0.0182725303 GeV **** **** Cameron E. m. for 209-Bi: -0.0147107309 GeV **** **** Cam.El. E. m. for 209-Bi: -0.0171704441 GeV **** **** My.&Sw. E. m. for 209-Bi: -0.0177380107 GeV **** **** Atomic mass for 209-Bi: 194.664047 GeV **** **** Nuclear mass for 209-Bi: 193.687195 GeV **** **** Excess mass for 235-U : 0.0409132205 GeV **** **** Cameron E. m. for 235-U : 0.0464000776 GeV **** **** Cam.El. E. m. for 235-U : 0.0420622788 GeV **** **** My.&Sw. E. m. for 235-U : 0.0413222089 GeV **** **** Atomic mass for 235-U : 218.942078 GeV **** **** Nuclear mass for 235-U : 218.895767 GeV **** **** Excess mass for 238-U : 0.0473045185 GeV **** **** Cameron E. m. for 238-U : 0.0524553321 GeV **** **** Cam.El. E. m. for 238-U : 0.0481762439 GeV **** **** My.&Sw. E. m. for 238-U : 0.0473943055 GeV **** **** Atomic mass for 238-U : 221.74295 GeV **** **** Nuclear mass for 238-U : 221.696655 GeV **** **** Evaporation from residual nucleus activated **** **** Deexcitation gamma production activated **** **** Evaporated "heavies" transport activated **** **** High Energy fission requested & activated **** **** Fermi Break Up requested & activated **** **** Neutrino generators initialized F T T **** *** Neutrino xsec file header: Neutrino Xsec file fronm *** *** Neutrino xsec file generated on: DATE: 9/10/ 8, TIME: 19:48:1 *** Minimum kinetic energy for BME : 1.0000E-03 (GeV/n) Overall minimum kinetic energy for ion nuclear interactions: 1.0000E-03 (GeV/n) Rayleigh option requested for medium number 1 Rayleigh option requested for medium number 2 **** Fluorescence data successfully retrieved from unit 13 **** **** Subroutine Mulmix: medium n. 28 **** Number of elements = 2, Density= 0.250000 (g/cm**3) 0 I Z Pa F_i Rho_i Index Atomic Atomic Proportion Proportion Number Weight by Number by weight 1 1.00000 2.01410 0.580000 0.119940 2 1.00000 3.01605 0.420000 0.130060 ZTILDE,AE1O3,BLCCRA= 1.00000E+00 1.44482E+00 1.77860E-04 ZTILDE,AE1O3,BLCCRE= 0.00000E+00 1.44482E+00 1.77860E-04 BLCC,XCC,TFFLU0,XR0FLU= 6.88032E+02 1.26929E-04 9.73091E-03 2.16869E-05 BLCCE,XCCE,TFEMF0,XR0EMF= 1.37606E+03 1.79504E-01 1.45370E-02 4.59111E-02 Particle n.: -6 Ecutm (prim. & sec.) = 3.727 GeV 3.727 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: -5 Ecutm (prim. & sec.) = 2.808 GeV 2.808 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: -4 Ecutm (prim. & sec.) = 2.809 GeV 2.809 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: -3 Ecutm (prim. & sec.) = 1.876 GeV 1.876 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 1 Ecutm (prim. & sec.) = 0.9383 GeV 0.9383 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 2 Ecutm (prim. & sec.) = 0.9383 GeV 0.9383 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 3 Ecutm (prim. & sec.) = 5.1150E-04 GeV 5.1150E-04 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 4 Ecutm (prim. & sec.) = 5.1150E-04 GeV 5.1150E-04 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 10 Ecutm (prim. & sec.) = 0.1057 GeV 0.1057 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 11 Ecutm (prim. & sec.) = 0.1057 GeV 0.1057 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 13 Ecutm (prim. & sec.) = 0.1396 GeV 0.1396 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 14 Ecutm (prim. & sec.) = 0.1396 GeV 0.1396 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 15 Ecutm (prim. & sec.) = 0.4936 GeV 0.4936 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 16 Ecutm (prim. & sec.) = 0.4936 GeV 0.4936 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 20 Ecutm (prim. & sec.) = 1.197 GeV 1.197 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 21 Ecutm (prim. & sec.) = 1.189 GeV 1.189 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 31 Ecutm (prim. & sec.) = 1.189 GeV 1.189 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 33 Ecutm (prim. & sec.) = 1.197 GeV 1.197 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 36 Ecutm (prim. & sec.) = 1.321 GeV 1.321 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 37 Ecutm (prim. & sec.) = 1.321 GeV 1.321 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 38 Ecutm (prim. & sec.) = 1.672 GeV 1.672 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 39 Ecutm (prim. & sec.) = 1.672 GeV 1.672 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 41 Ecutm (prim. & sec.) = 1.777 GeV 1.777 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 42 Ecutm (prim. & sec.) = 1.777 GeV 1.777 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 45 Ecutm (prim. & sec.) = 1.869 GeV 1.869 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 46 Ecutm (prim. & sec.) = 1.869 GeV 1.869 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 49 Ecutm (prim. & sec.) = 1.968 GeV 1.968 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 50 Ecutm (prim. & sec.) = 1.968 GeV 1.968 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 51 Ecutm (prim. & sec.) = 2.285 GeV 2.285 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 52 Ecutm (prim. & sec.) = 2.468 GeV 2.468 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 54 Ecutm (prim. & sec.) = 2.574 GeV 2.574 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 57 Ecutm (prim. & sec.) = 2.285 GeV 2.285 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 58 Ecutm (prim. & sec.) = 2.468 GeV 2.468 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 60 Ecutm (prim. & sec.) = 2.574 GeV 2.574 GeV, Hthnsz = 1.0000E+30 GeV **** Atomic electron contribution accounted via the Fano correction **** **** f_Fano = 1.063E+01, Z_Fano = 1.000E+00 **** **** Subroutine Mulmix: medium n. 5 **** Number of elements = 1, Density= 1.84800 (g/cm**3) 0 I Z Pa F_i Rho_i Index Atomic Atomic Proportion Proportion Number Weight by Number by weight 1 4.00000 9.01218 1.00000 1.84800 ZTILDE,AE1O3,BLCCRA= 4.00000E+00 2.08102E+00 2.84575E-03 ZTILDE,AE1O3,BLCCRE= 3.00000E+00 2.08102E+00 2.84575E-03 BLCC,XCC,TFFLU0,XR0FLU= 8.70192E+03 7.17510E-04 7.69391E-04 3.44717E-05 BLCCE,XCCE,TFEMF0,XR0EMF= 1.08774E+04 8.02201E-01 1.83902E-03 7.29765E-02 Particle n.: -6 Ecutm (prim. & sec.) = 3.727 GeV 3.727 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: -5 Ecutm (prim. & sec.) = 2.808 GeV 2.808 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: -4 Ecutm (prim. & sec.) = 2.809 GeV 2.809 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: -3 Ecutm (prim. & sec.) = 1.876 GeV 1.876 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 1 Ecutm (prim. & sec.) = 0.9383 GeV 0.9383 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 2 Ecutm (prim. & sec.) = 0.9383 GeV 0.9383 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 3 Ecutm (prim. & sec.) = 5.1266E-04 GeV 5.1266E-04 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 4 Ecutm (prim. & sec.) = 5.1266E-04 GeV 5.1266E-04 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 10 Ecutm (prim. & sec.) = 0.1057 GeV 0.1057 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 11 Ecutm (prim. & sec.) = 0.1057 GeV 0.1057 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 13 Ecutm (prim. & sec.) = 0.1396 GeV 0.1396 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 14 Ecutm (prim. & sec.) = 0.1396 GeV 0.1396 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 15 Ecutm (prim. & sec.) = 0.4936 GeV 0.4936 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 16 Ecutm (prim. & sec.) = 0.4936 GeV 0.4936 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 20 Ecutm (prim. & sec.) = 1.197 GeV 1.197 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 21 Ecutm (prim. & sec.) = 1.189 GeV 1.189 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 31 Ecutm (prim. & sec.) = 1.189 GeV 1.189 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 33 Ecutm (prim. & sec.) = 1.197 GeV 1.197 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 36 Ecutm (prim. & sec.) = 1.321 GeV 1.321 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 37 Ecutm (prim. & sec.) = 1.321 GeV 1.321 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 38 Ecutm (prim. & sec.) = 1.672 GeV 1.672 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 39 Ecutm (prim. & sec.) = 1.672 GeV 1.672 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 41 Ecutm (prim. & sec.) = 1.777 GeV 1.777 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 42 Ecutm (prim. & sec.) = 1.777 GeV 1.777 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 45 Ecutm (prim. & sec.) = 1.869 GeV 1.869 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 46 Ecutm (prim. & sec.) = 1.869 GeV 1.869 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 49 Ecutm (prim. & sec.) = 1.968 GeV 1.968 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 50 Ecutm (prim. & sec.) = 1.968 GeV 1.968 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 51 Ecutm (prim. & sec.) = 2.285 GeV 2.285 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 52 Ecutm (prim. & sec.) = 2.468 GeV 2.468 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 54 Ecutm (prim. & sec.) = 2.574 GeV 2.574 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 57 Ecutm (prim. & sec.) = 2.285 GeV 2.285 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 58 Ecutm (prim. & sec.) = 2.468 GeV 2.468 GeV, Hthnsz = 1.0000E+30 GeV Particle n.: 60 Ecutm (prim. & sec.) = 2.574 GeV 2.574 GeV, Hthnsz = 1.0000E+30 GeV **** Atomic electron contribution accounted via the Fano correction **** **** f_Fano = 9.779E+00, Z_Fano = 4.000E+00 **** **** Isotope tabulation data start at location 10220064 and end at 10223714 (I*4 addr.) **** No radioactive products/decays requested Flags for applying biasing to prompt and/or decay radiation: Hadr/muon EM Low en. Neut. Prompt/Decay Prompt/Decay Prompt/Decay Inter./decay length: T F T F T F Leading Particle : T F T F T F Importance and WW : T F T F T F EM transport threshold multipliers: prompt decay 1.00E+00 1.00E+00 **** Non analog absorption factors start at location 10223717 and end at 10223742 (I*4 addr.) **** **** Biased downscattering factors start at location 10223745 and end at 10223770 (I*4 addr.) **** **** Non analog absorption group limits start at location10223771 and end at 10223783 (I*4 addr.) **** **** Biased downscattering group limits start at location10223784 and end at 10223796 (I*4 addr.) **** **** Cut-off group limits start at location 10223797 and end at 10223809 (I*4 addr.) **** **** Lower Weight Window limits start at location 10223811 and end at 10223836 (I*4 addr.) **** 1 ***** Neutron Xsec: group limits, average energies, velocities and momenta ***** ***** start at location 10223837, end at location 10226004 (I*4 addr.) ***** ***** Neutron Xsec: **** **** Group limits, average energies, velocities and momenta start at location 10223837, end at location 10226004 (I*4 addr.) ***** Group cross sections storage starts at 10246285 Last location used for group xsecs 10848149 *** Values read from the cross section file *** Panini independent Xsec Number of primary groups 260 Number of primary downscatters 260 Number of primary upscatters 30 Number of secondary groups 42 Number of secondary downscatters 42 Number of neutron+gamma groups 302 Total xsec table length 335 Loc. of within group (g->g) xsec 34 Number of media read 278 Number of Leg. coefficients 6 Number of discrete angles 3 1 *** Fluka low energy group transport threshold: 261 corresponding to an energy threshold of: 1.00001E-14 GeV 1 *** Fluka to low en. xsec material correspondence: printed atomic densities are meaningless when used in a compound *** Fluka medium Name Xsec medium atomic density Id. 1 Id. 2 Id. 3 number number ( at/(cm barn) ) 1 BLCKHOLE 0 0.0000E+00 0 0 0 2 VACUUM 1000 0.0000E+00 0 0 0 5 BERYLLIU 3 1.2349E-01 4 9 296 26 DEUTERIU 1 0.0000E+00 1 2 296 27 TRITIUM 2 0.0000E+00 1 4 296 *** dp/dx tab. generated up to 5.06 GeV/c/n *** *** Barkas Z^3 corrections accounted for *** *** Bloch Z^4 corrections accounted for *** *** Mott Z - e corrections accounted for *** *** Nuclear stopping power accounted for *** **** Nuclear form factor 'a la Kelner' selected **** **** Standard Coulomb correction selected **** **** for charged hadron and muon bremmstrahlung **** ***** dp/dx : material number 28 "DT " ***** ***** Average excitation energy : 1.9200E+01 eV, weighted Z/A : 4.1069E-01 ***** ***** Sternheimer density effect parameters: ***** ***** X0 = 0.2000, X1 = 2.0000, C = -2.4642, A = 0.2646 m = 3.0000 D0 = 0.0000 ***** ***** Restricted energy loss tabulated in 256 intervals ***** ***** Delta ray production activated above 1.0000E-04 GeV ***** ***** dE/dx fluctuations activated for this medium, level 1 ***** ***** (up to 2I discrete levels, up to 2 K-edges) ***** ***** Restricted pair production energy loss added ***** ***** Exp. pair production activated above 0.0000E+00 GeV ***** ***** Restricted bremsstrahlung energy loss added ***** ***** Exp. bremsstrahlung activated above 3.0000E-04 GeV ***** ***** dp/dx : material number 5 "BERYLLIU" ***** ***** Average excitation energy : 6.3700E+01 eV, weighted Z/A : 4.4384E-01 ***** ***** Sternheimer density effect parameters: ***** ***** X0 = 0.0592, X1 = 1.6922, C = -2.7847, A = 0.8039 m = 2.4339 D0 = 0.1400 ***** ***** Restricted energy loss tabulated in 256 intervals ***** ***** Delta ray production activated above 1.0000E-04 GeV ***** ***** dE/dx fluctuations activated for this medium, level 1 ***** ***** (up to 2I discrete levels, up to 2 K-edges) ***** ***** Restricted pair production energy loss added ***** ***** Exp. pair production activated above 0.0000E+00 GeV ***** ***** Restricted bremsstrahlung energy loss added ***** ***** Exp. bremsstrahlung activated above 3.0000E-04 GeV ***** ***** dp/dx tabulations in blank common start at location 10848153 ***** ***** end at location 10915736 (I*4 addresses) ***** *** Range: P_max: 1.2300843 P_min 0.00398107152 *** ***** Range tabulations in blank common start at location 10915739 ***** ***** end at location 10915954 (I*4 addresses) ***** ***** Sigtab : material number 26 "DEUTERIU" ***** ***** Muon photonuclear interac. requested ***** ***** Xsec tabulations in blank common start at location 10915957 ***** ***** end at location 10923862 (I*4 addresses) for this medium ***** ***** Sigtab : material number 27 "TRITIUM " ***** ***** Muon photonuclear interac. requested ***** ***** Xsec tabulations in blank common start at location 10923863 ***** ***** end at location 10931768 (I*4 addresses) for this medium ***** ***** Sigtab : material number 28 "DT " ***** ***** Muon photonuclear interac. requested ***** ***** Xsec tabulations in blank common start at location 10931769 ***** ***** end at location 10939674 (I*4 addresses) for this medium ***** ***** Sigtab : material number 5 "BERYLLIU" ***** ***** Muon photonuclear interac. requested ***** ***** Xsec tabulations in blank common start at location 10939675 ***** ***** end at location 10947580 (I*4 addresses) for this medium ***** ***** Total,elastic,inelastic,pair,bremss. macroscopic cross sections tabulated in 70 intervals ***** ***** Xsec tabulations in blank common start at location 10915957 ***** ***** end at location 10947580 (I*4 addresses) ***** ***** Form Fact. tabulations in blank common start at location10947581 ***** ***** end at location11008952 (I*4 addresses) ***** Chem. sym. : H, Z = 1., A = 2.014, PZ = 5.80000E-01 , RHOZ = 1.19940E-01 Chem. sym. : H, Z = 1., A = 3.016, PZ = 4.20000E-01 , RHOZ = 1.30060E-01 Chem. sym. : Be, Z = 4., A = 9.012, PZ = 1.00000E+00 , RHOZ = 1.84800E+00 *** Blank common cells from 11008953 to 11009250 allocated for an EMF R*4 tab. array *** Blank common cells from 11009251 to 11009494 allocated for an EMF R*4 tab. array *** Blank common cells from 11009495 to 11009805 allocated for an EMF R*4 tab. array Electron Xsecs for EMF medium # 1(DT ) tabulated in 373 intervals Min kin. energy 1.000E-04 (GeV)Max kin. energy 5.06 (GeV) Electron Xsecs for EMF medium # 2(BERYLLIU) tabulated in 373 intervals Min kin. energy 1.000E-04 (GeV)Max kin. energy 5.06 (GeV) ***** EMF tabulations in blank common start at location11009806 ***** ***** end at location11076804 (I*4 addresses) ***** **** Fluorescence X-ray production requested for Emf medium # 1 **** **** Maximum K-edge energy 1.36099998E-05 MeV **** **** Lowest energy bin above it # 0 **** **** Fluorescence X-ray production requested for Emf medium # 2 **** **** Maximum K-edge energy 0.000118360003 MeV **** **** Lowest energy bin above it # 0 **** 1 Quantities/Biasing associated with each media: DT Rho = 0.250000 g/cm**3 Rlc= 609.186 cm Ae = 0.610999 MeV Ue = 5060.74 MeV Ap = 3.333333E-02 MeV Up = 5060.23 MeV dE/dx fluctuations activated for this medium, level 1 below the threshold for explicit secondary electron production (up to 2I discrete levels, up to 2 K-edges) BERYLLIU Rho = 1.84800 g/cm**3 Rlc= 35.2760 cm Ae = 0.610999 MeV Ue = 5060.74 MeV Ap = 3.333333E-02 MeV Up = 5060.23 MeV dE/dx fluctuations activated for this medium, level 1 below the threshold for explicit secondary electron production (up to 2I discrete levels, up to 2 K-edges) 1 Correspondence of regions and EMF-FLUKA material numbers and names: Region EMF FLUKA 1 0 VACUUM 1 BLCKHOLE 2 0 VACUUM 2 VACUUM 3 1 DT 28 DT Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 4 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 5 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 6 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 7 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 8 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 9 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 10 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 11 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 12 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T 13 2 BERYLLIU 5 BERYLLIU Ecut = 6.1100E-01 MeV, Pcut = 3.3333E-02 MeV, BIAS = F, Ray. = T, S(q,Z) = T, Pz(q,Z) = T ******* Stopped in usrbin: insufficient space for allocation in blank common ******* ******* 78920202 I*4 memory position available when ******** needed *******