Swift ion beams for solid state and materials science

Denker, A.; Bohne, W.; Heese, J.; Homeyer, H.; Kluge, H.; Lindner, S.; Opitz-Coutureau, J.; Röhrich, J.; Strub, E.

Artykuł - szczegóły

Tytuł artykułu

Swift ion beams for solid state and materials science

Autorzy

Denker A. , Bohne W. , Heese J. , Homeyer H. , Kluge H. , Lindner S. , Opitz-Coutureau J. , Röhrich J. , Strub E.

Treść / Zawartość

Pełne teksty:

Swift ion beams for solid state and materials science.pdf

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Identyfikatory

Warianty tytułu

Konferencja

Proceedings of the XXXIII European Cyclotron Progress Meeting, 17-21 September 2002, Warszawa-Kraków, Poland

Języki publikacji

Abstrakty

Ion beams are unique tools in modern science and technology. They are used for the analysis and modification of materials and are applied in medicine and technology. In cancer therapy fast protons allow a precise tailoring of the radiation field to the tumour, thus maximising the tumour control probability and simultaneously reducing the risk of side effects. Modification of the structure of solids by ion irradiation results in local structures on nano-scale, e.g. high-tech filters having defined pore numbers and pore sizes are produced by high-energy heavy ion irradiation with consecutive etching. Electronic devices utilised in areas with high radiation level have to be tested for their radiation hardness. The devices are irradiated with accelerated ions to receive the same dose by high-energy ions as expected during their lifetime. For materials sciences the analysis of composition and structure of solids is of uppermost importance. Complex layered structures are analysed by ERDA (Elastic Recoil Detection Analysis). Investigation of art and archaeological objects has to be non-destructive. PIXE (Proton Induced X-ray Emission) allows elemental analysis without sampling of the object. Different applications of high energy ions will be presented.

Słowa kluczowe

tumour therapy materials modification materials analysis single event effects technical applications cyclotrons

Wydawca

Institute of Nuclear Chemistry and Technology

Czasopismo

Nukleonika

Rocznik

2003

Tom

Vol. 48,suppl.2

Strony

175--180

Opis fizyczny

Bibliogr. 29 poz., rys.

Twórcy

autor

Denker A.

denker@hmi.de

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Bohne W.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Heese J.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Homeyer H.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Kluge H.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Lindner S.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Opitz-Coutureau J.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Röhrich J.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

autor

Strub E.

Ionenstrahllabor, Hahn-Meitner-Institut, 100 Glienicker Str., D 14109 Berlin, Germany, Tel.: +49 30/ 8062 2498, Fax: +49 30/ 8062 2097

Bibliografia

1. Amaldi U (2000) The importance of particle accelerators. Europhysics News 31;6:5−9
2. Apel P (1996) Polymeric materials research with cyclotrons. In: Cornell JC (ed.) Proc of the 14th Int Conf on Cyclotrons and their Applications, 8−13 October 1995, Cape Town, South Africa. World Scientific, Singapore, pp 136−143
3. Balanzat E, Betz N, Bouffard S (1995) Swift heavy ion modification of polymers. Nucl Instrum Meth Phys Res B 105:46−49
4. Bohne W, Röhrich J, Röschert G (1998) The Berlin timeof-flight ERDA setup. Nucl Instrum Meth Phys Res B 136/138:633−637
5. Denker A, Maier KH (2000) Investigation of objects d’art by PIXE with 68 MeV protons. Nucl Instrum Meth Phys Res B 161/163:704−708
6. Flanz JB, Bradley SG, Goitein M et al. (1999) Initial equipment commissioning of the northeast proton therapy center. In: Baron E, Lieuvin M (eds) Proc of the 15th Int Conf onCyclotrons and their Applications, 14−19 June 1998, Caen, France. IOP, Bristol, p 319
7. Gericke C, Kopp J, Beaujean R, Küchler S (2000) Calibration of Si-detectors for dosimetry in space. Annual Report HMI B 567:101
8. Hajdas W, Adams L, Nickson B, Zehnder A (1996) The proton irradiation facility at the Paul Scherrer Institute. Nucl Instrum Meth Phys Res B 113:54−58
9. Hayashi AM (1998) Taking on the energizer bunny. Scientific American 4:286−292
10. http://RADHOME.gsfc.nasa.gov/radhome/papers/seecai.htm
11. http://www.cyc.ucl.ac.be/HIF/HIF.html
12. http://www.cyc.ucl.ac.be/PIF/PIF.html
13. http://www.cyclotron.tamu.edu/ref/
14. http://www.ganil.fr/research/interdisciplinarity/industry/index.html
15. http://www.neurosurgery.mgh.harvard.edu/hcl/ptles.htm
16. Jongen Y, Beeckman W, Cohilis P (1996) The proton therapy system for MGH’s NPTC: equipment description and progress report. Bull Cancer Radiother 83S:219s−222s
17. Kiefer J (2001) Space radiation research in the new millennium – from where we come and where we go. Phys Medica 14;S1:1−4
18. Krauser J, Hoffmann V, Harneit W et al. (2001) Graphitic nanowires embedded in diamondlike carbon films. Proc AIP 591:507−510
19. Maier KH, Denker A, Voss P, Becker HW (1998) Single event burnout of high-power diodes. Nucl Instrum Meth Phys Res B 146:596−600
20. Meinert D, Fritzke K, Bischof M, Popow E, LuebkeOssenbeck B, Maier KH (1999) Strahlungstest der ABRIXAS Sternkamera. Annual Report HMI B 563:74
21. Pineda CA, Peisach M (1990) Prompt analysis of heavy elements by high-energy-induced (p,X) reactions. Nucl Instrum Meth Phys Res A 299:618−623
22. Schiwietz G, Luderer E, Grande PL (2001) Ion tracks – quasi one dimensional nanostructures. Appl Surf Sci 182:286−292
23. Schwartz K, Trautmann C (2001) Heavy ion-induced damage and modifications of insulating materials. Proc of SPIE 4415:248−259
24. Sisterson JM (2001) Ion beam therapy: overview of the world experience. In: Duggan JL, Morgan IL (eds) Proc of the 16th Int Conf Application of Accelerators in Research and Industry, 1−4 November 2000, Denton, TX, USA. AIP, Denton, CP576:865−868
25. Soelkner G, Voss GP, Kaindl W, Wachutka G, Maier KH, Becker HW (2000) Charge carrier avalanche multiplication in high-voltage diodes triggered by ionizing radiation. IEEE Trans Nucl Sci 47;6:2365−2372
26. Speel E, Bronk H (2001) Enamel painting: materials and recipes in Europe from c. 1500 to c. 1920. Berliner Beiträge zur Archäometrie 18:43−100
27. Spohr R (1990) Ion tracks and microtechnology. Vieweg Verlag, Braunschweig
28. Virtanen A, Hyvönen J, Ranttila K, Rekikoski I, Tuppurainen J (1999) Heavy ion and proton test site at JYFL accelerator laboratory. Nucl Instrum Meth Phys Res A 426:68−71
29. Yeo YH, McKee JSC, Smith GR et al. (1990) Commissioning and characterization of the Manitoba automated high energy proton microprobe. Nucl Instrum Meth Phys Res B 49:430−434

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-article-BUJ5-0004-0092