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Tytuł artykułu

Thermal and epithermal neutrons in the vicinity of the Primus Siemens biomedical accelerator

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Języki publikacji
EN
Abstrakty
EN
In this paper, the thermal and epithermal neutron fluence distributions in the vicinity of the Primus Siemens accelerator are presented. The measurements were carried out by the use of the neutron activation method for 15 MV X-rays and electron beams of 18 MeV and 21 MeV. From the radiation safety point of view for the hospital personnel, it is important to know the thermal and epithermal neutron fluence distribution in the vicinity of the accelerator because the neutrons interacting with atoms of a medium by various processes induce the activity of objects (accelerator, other apparatus etc.) and walls in the treatment room. The thermal and epithermal neutron capture, particularly, in high atomic number materials of the accelerator head can be a significant source of gamma radiation and it has to be taken into account for estimation of the work safety of the personnel. Values of the neutron fluence were normalized to the maximum photon (or electron) dose Dmax,gamma (e) measured at the central axis of therapeutic X-ray (or electron) beam in a water phantom. The thermal neutron fluences measured during the 15 MV X-ray emission varied between 1.1 × 10 5 n ź cm 2ź Gy -1 and 4.4 × 10 5 n ź cm -2ź Gy 1 whereas the epithermal neutron fluences ranged from 0.2 × 10 5 n ź cm 2ź Gy- 1 to 1.8 × 105 n ź cm -2ź Gy -1. In the case of electron beams, the neutron fluence measurements were performed only at the isocentre. The obtained thermal and epithermal neutron fluences were 1.2 × 10 4 n ź cm -2ź Gy -1 and 0.6 × 10 4 n ź cm -2ź Gy -1, respectively, for the 18 MeV electrons. In the the case of the 21 MeV electron beams the thermal neutron fluence was -2.0 × 10 4 n ź cm -2ź Gy -1 whereas the epithermal neutron fluence was 0.8 × 10 4 n ź cm -2ź Gy-1.
Czasopismo
Rocznik
Strony
73--81
Opis fizyczny
Bibliogr. 22 poz., rys.
Twórcy
autor
  • Institute of Physics, University of Silesia, 4 Uniwersytecka Str., 40-007 Katowice, Poland, Tel.: +48 32/ 588 211(1384), Fax: +48 32/ 588 431
autor
  • Radiotherapy Department of the Hospital – Memorial St. Leszczyński, 27 Raciborska Str., 40-074 Katowice, Poland
autor
  • Institute of Physics, University of Silesia, 4 Uniwersytecka Str., 40-007 Katowice, Poland, Tel.: +48 32/ 588 211(1384), Fax: +48 32/ 588 431
  • Radiotherapy Department of the Hospital – Memorial St. Leszczyński, 27 Raciborska Str., 40-074 Katowice, Poland
autor
  • Institute of Physics, University of Silesia, 4 Uniwersytecka Str., 40-007 Katowice, Poland, Tel.: +48 32/ 588 211(1384), Fax: +48 32/ 588 431
Bibliografia
  • 1. Beckurc K, Wirtc K (eds) (1968) Nejtronnaya fizika.Atomizdat, Moskva.
  • 2. Berman BL, Dietrich SS (eds) (1998) Atlas of photo-nuclear cross sections obtained with monoenergetic photons. Atom Data Nucl Data 38;2:199−338.
  • 3. Carrier J-F, Archambault L, Beaulieu L (2004) Validation of GEANT4, an object-oriented Monte Carlo toolkit, for simulations in medical physics. Med Phys 31;3:484−492.
  • 4. Cymermam U, Majenka A (1984) Determination of the doses of the photon and neutron secondary radiation from the Saturne-20 linear accelerator. Nowotwory 34;1:31−37 (in Polish).
  • 5. Firestone RB (eds) (1996) Table of isotopes, 8th ed., version 1.0. Lawrence Berkeley National Laboratory, University of California.
  • 6. Firk FWK (1970) Low-energy photonuclear reactions. Annu Rev Nucl Sci 20:39.
  • 7. Followill DS, Stovall MS, Kry SF, Ibbatt GS (2003) Neutron source strength measurements for Varian, Siemens, Elekta and General Electric linear accelerator. J Appl Clin Med Phys 4;3:189−194.
  • 8. Gudowska J, Brahme A (1996) Neutron radiation from high-energy X-ray medical accelerators. Nukleonika 41;2:105−118.
  • 9. ICRP (1995) Conversion coefficient for use in radio- logical protection against external radiation. ICRP Publication 74.
  • 10. Kase KR, Mao XS, Nelson WR, Liu JC, Kleck JH, Elsalim M (1998) Neutron fluence and energy spectra around the Varian Clinac 2100/2300C medical accelerator. Health Phys 74;1:38−47.
  • 11. Konefał A, Orlef A, Zipper W, Dorda J, Łobodziec W (2001) Undesired neutron radiation generated by biome-dical accelerators during high-energy X-ray and electron beam emission. Pol J Med Phys Eng 2;7(4):291−304.
  • 12. Konefał A, Orlef A, Zipper W, Maniakowski Z (2003) The use of the new Monte Carlo software packet called GEANT4 for the calculations of the doses from the X-rays outside the primary beam. Phys Med 20;S1:s147−s149.
  • 13. Levinger JS (1960) Nuclear photo disintegration. Oxford University Press, London.
  • 14. MacDonald N (ed.) (1965) Nuclear structure and electro-magnetic interaction. Plenum, New York.
  • 15. Macklin RL, Pomerance HS (1956) Neutron cross sections. In: Proc of the Int Conf on the Peaceful Uses of Atomic Energy. Vol. 5. United Nations, New York, p 96.
  • 16. Mao XS, Kase KR, Liu JC, Nelson WR, Kleck JH, Johnsen S (1997) Neutron source in the Varian Clinac 2100/2300 medical accelerator calculated by the EGS4 code. Health Phys 72;4:524−529.
  • 17. National Bureau of Standards (NBS) (1973) Photonu-clear reaction data. NBS Special Publication 380, Washington, D C.
  • 18. National Bureau of Standards (NBS) (1982) Photo-nuclear Data Index. NBSIR 82-2543, Washington, D C.
  • 19. Ongaro C, Zanini A, Natashi U, Rodenas J, Ottaviano G, Manfredatti C (2000) Analysis of photoneutron spectra produced in medical accelerators. Phys Med Biol 45:L55−L61.
  • 20. Price WJ (1964) Nuclear radiation detection. McGraw-Hill Book Co., USA.
  • 21. Scott MB, Hanson AO, Kerst DW (1955) Electro- and photo-disintegration cross sections of 63Cu. Phys Rev100:205.
  • 22. Wu RK, McGinley PH (2003) Neutron and capture gamma along maze of linear accelerator vaults. J Appl Clin Med Phys 4;2:162−171.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BUJ6-0004-0072
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