Journal of the Korean Physical Society

, Volume 71, Issue 11, pp 764–768 | Cite as

Estimation of dose delivered to accelerator devices from stripping of 18.5 MeV/n 238U ions using the FLUKA code

  • Leila Mokhtari Oranj
  • Hee-Seock Lee
  • Mario Santana Leitner
Article
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Abstract

In Korea, a heavy ion accelerator facility (RAON) has been designed for production of rare isotopes. The 90° bending section of this accelerator includes a 1.3-μm-carbon stripper followed by two dipole magnets and other devices. An incident beam is 18.5 MeV/n 238U33+,34+ ions passing through the carbon stripper at the beginning of the section. The two dipoles are tuned to transport 238U ions with specific charge states of 77+, 78+, 79+, 80+ and 81+. Then other ions will be deflected at the bends and cause beam losses. These beam losses are a concern to the devices of transport/beam line. The absorbed dose in devices and prompt dose in the tunnel were calculated using the FLUKA code in order to estimate radiation damage of such devices located at the 90° bending section and for the radiation protection. A novel method to transport multi-charged 238U ions beam was applied in the FLUKA code by using charge distribution of 238U ions after the stripper obtained from LISE++ code. The calculated results showed that the absorbed dose in the devices is influenced by the geometrical arrangement. The maximum dose was observed at the coils of first, second, fourth and fifth quadruples placed after first dipole magnet. The integrated doses for 30 years of operation with 9.5 pμA 238U ions were about 2 MGy for those quadrupoles. In conclusion, the protection of devices particularly, quadruples would be necessary to reduce the damage to devices. Moreover, results showed that the prompt radiation penetrated within the first 60 - 120 cm of concrete.

Keywords

RISP Heavy ion accelerator Absorbed dose Multi-charged 238U ions FLUKA LISE++ code 
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References

  1. [1]
    J. H. Oh, L. Mokhtari Oranj, H. S. Lee and S. K. Ko, J. Korean Phys. Soc. 66, 432 (2015).ADSCrossRefGoogle Scholar
  2. [2]
    A. Ferrari, P. R. Sala, A. Fass`o and J. Ranft, FLUKA: a multi-particle transport code, CERN 2005-10, 2005, INFN/TC 05/11, SLAC-R-773.CrossRefGoogle Scholar
  3. [3]
    O. Tarasov and D. Bazin, Nucl. Instr. Meth. Phys. Res B. 204, 174 (2003).ADSCrossRefGoogle Scholar
  4. [4]
    http://www.nscl.msu.edu/lise.Google Scholar
  5. [5]
    V. Vlachoudis, FLAIR: A powerful but user friendly graphical interface for FLUKA Proc. Int. Conf. on Mathematics, Computational Methods & Reactor Physics (M&C 2009) (Saratoga spring, New York, 2009).Google Scholar
  6. [6]
    G. Lum, Radiation damage level of electronics to materials (LOCKHEED MARTIN, 2011).Google Scholar
  7. [7]
    A. F. Zeller and E. Lansing, Final report on radiation resistant Magnets II, DOE Geant DE-FG02-03ER41254.Google Scholar
  8. [8]
    R. Roberts, D. Georgobiani and R. Ronningen, FRIB preseparator radiation environment and superconducting magnet lifetime estimator, Radiation effects in superconducting magnet materials (RESMM12) (2012).Google Scholar

Copyright information

© The Korean Physical Society 2017

Authors and Affiliations

  • Leila Mokhtari Oranj
    • 1
  • Hee-Seock Lee
    • 2
  • Mario Santana Leitner
    • 3
  1. 1.Division of Advanced Nuclear EngineeringPOSTECHPohangKorea
  2. 2.Pohang Accelerator LaboratoryPOSTECHPohangKorea
  3. 3.SLAC National Accelerator LaboratoryMenlo ParkUSA

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