Accelerators in materials research

• Autorzy: Turos A.
• Konferencja: Proceedings of the Jubilee Symposium for the 50th anniversary of the foundation of the Institute of Nuclear Research "Atomic Science in the XXI Century" June 16, 2005, Warsaw, Poland
• Języki publikacji: EN

Abstrakty

EN

Abstract Since at least forty years accelerators of charged particles no longer belong to nuclear physics exclusively. This is especially true for accelerators at energies below 1 GeV. The vast majority of accelerators in this energy range is used for materials research and medicine. In materials research the applications are principally twofold: modifications of solids and surface layer microanalysis. Two most important challenges for materials research at the beginning of XXI century as determined by the Materials Research Society are: development of materials able to repair human body and development of materials for new electronic devices able to cope with the enormous amount of information to be stored and transmitted. The role of accelerators with regard to the challenges of modern technology will be discussed.

Słowa kluczowe

EN

materials research; accelerators; ion beam modification; ion beam analysis

• Wydawca: Institute of Nuclear Chemistry and Technology
• Czasopismo: Nukleonika
• Rocznik: 2005
• Tom: Vol. 50,suppl.3
• Strony: 11--15
• Opis fizyczny: Bibliogr. 22 poz., rys.

Twórcy

autor

Turos A.

• Institute of Electronic Materials Technology, 133 Wólczyńska Str., 01-919 Warsaw, Poland,

Bibliografia

• 1. Amsel G, Nadai J, d’Aretemare E, David D, Girard E, Moulin J (1971) Microanalysis by the direct observation of nuclear reactions using a 2 MeV Van de Graaf accelerator. Nucl Instrum Meth 92:481−485
• 2. Bieliński D, Lipiński P, Ślusarski L et al. (2004) Surface layer modification of ion bombarded HDPE. Appl Surf Sci 564:179−186
• 3. Colinge JP (2004) Silicon on insulator technology, 3rd ed. Kluwer Academic Publishing, Boston MA
• 4. Costa L, Luda MP, Trossarelli L et al. (1998) Oxidation in orthopaedic UHMWPE sterilized by gamma-radiation and ethylene oxide. Biomaterials 19:659−668
• 5. Doyle BL, Walsh DS, Renfrow SN, Vizkelethy G, Schenkel T, Hamza AV (2003) Nuclear emission spectroscopies. Nucl Instrum Meth B 181:199−210
• 6. Feldman LC, Mayer JW (1986) Fundamentals of surface and thin film analysis. North-Holland, New York
• 7. Fischer BE, Heiss M, Cholewa M (2003) About the art to shoot with single ions. Nucl Instrum Meth B 210:285−291
• 8. Mayer JW, Eriksson L, Davies JA (1970) Ion implantation in semicondutors. Academic Press, New York
• 9. Mayer J, Turos A (1973) Comparison of surface layers analysis techniques. Thin Solid Films 19:1−10
• 10. Narojczyk J, Werner Z, Piekoszewski J, Szymczyk W (2005) Effects of nitrogen implantation on lifetime of cutting tools made of SK5M tool steel. Vacuum 78:229−233
• 11. Proceedings of the XIIth Int Conf on Ion Beam Modification of Materials (2000) Nucl Instrum Meth B 161/163:1−1213
• 12. Proceedings of the XIIIth Int Conf on Ion Beam Modification of Materials (2003) Nucl Instrum Meth B 206:1−1143
• 13. Proceedings of the XVth Int Conf on Ion Beam Analysis (2002) Nucl Instrum Meth B 190:1−906
• 14. Proceedings of the XVIth Int Conf on Ion Beam Analysis (2004) Nucl Instrum Meth B 219/220:1−1084
• 15. Rossi P, Doyle BL, Banks JC et al. (2003) Ion photon emission spectroscopy. Nucl Instrum Meth B 210:123−128
• 16. Tesmer J, Nastasi M (eds) (1995) Ion beam analysis handbook. MRS, Pittsburg
• 17. Turos A (1978) Near surface analysis of solids using ion beam techniques. Nukleonika 23:183−207
• 18. Turos A, Jagielski J, Piątkowska A, Bieliński D, Ślusarski L, Madi NK (2002) Ion beam modification of surface properties of polymers. Vacuum 70:201−205
• 19. Turos A, Wilhelmi Z (1968) Applications of the Coulomb backscattering of heavy charged particles. I – Thickness measurements of thin foils and surface layers. Nukleonika 13:991−997
• 20. Turos A, Wilhelmi Z (1969) Applications of the Coulomb backscattering of heavy charged particles. II – Chemical analysis of surface layers. Nukleonika 14:319−335
• 21. Watt F (1997) The nuclear microprobe: a unique instrument. Nucl Instrum Meth B 130:1−8
• 22. Watt F, van Kan JA, Rajta I et al. (2003) The National University of Singapore high energy ion nano-probe facility: performance tests. Nucl Instrum Meth B 210:12−20