Dense magnetized plasma and its applications: review of the 3-year activity of the IAEA Co-ordinated Research Programme

• Autorzy: Gribkov V. , Malaquias A.
• Konferencja: Proceedings of the 2nd IAEA Research Co-ordination Meeting of the Co-ordinated Research Project on Dense Magnetized Plasma 1-3 June 2005, Kudowa Zdrój, Poland
• Języki publikacji: EN

Abstrakty

EN

A review of the results received in the course of fulfillment of the International Atomic Energy Agency Co-ordinated Research Project “Dense Magnetized Plasma” for the last 3 years is presented. Niche of the plasma type within the plasma physics field is outlined. Efforts of the CRP participants concentrated on design and operation of new Dense Magnetized Plasma devices are described. All of them designed for plasma heating and for other applications mainly based on the interaction of radiations generated by the devices with different objects. Materials exploitable, diagnostics of the interaction processes, as well as analytical equipment used by the participants to process the irradiated targets are described. Works developed in the frame of the CRP are covered thermonuclear fusion applications, fundamental plasma physics and material science issues, medicine, biology, and some other spheres. New data on the interaction of the radiations generated in this apparatus with various materials are given. E.g. it was found that the necessary dose producing activation/inactivation of enzymes can be much lower if used at a high-power flux density in comparison with those received with classical sources. All these experiments are discussed in the framework of pulsed radiation chemistry in its perfect sense thereto the criteria are formulated. New foreseen applications of DMP devices mainly based on neutron radiation are proposed and discussed.

Słowa kluczowe

EN

dense magnetized plasma; ion beams; plasma beams; neutron beams; X-ray beams; irradiation; high energy density; volumetric interaction

• Wydawca: Institute of Nuclear Chemistry and Technology
• Czasopismo: Nukleonika
• Rocznik: 2006
• Tom: Vol. 51, nr 1
• Strony: 5--13
• Opis fizyczny: Bibliogr. 17 poz., rys.

Twórcy

autor

Gribkov V.

autor

Malaquias A.

• Institute of Plasma Physics and Laser Microfusion, Department of Dense Magnetized Plasma, 23 Hery Str., 01-497 Warsaw, Poland, Tel.: +48 22 683 9056, Fax: +48 22 666 8372,,

Bibliografia

• 1. Bernard A, Bruzzone H, Choi P et al. (1998) Scientific status of Dense Plasma Focus Research. J Moscow Phys Society 8:1−93
• 2. Bogolubov EP, Gribkov VA, Dubrovsky AV et al. (2005) Use of installations of a Dense Plasma Focus type for material sciences. In: Proc of Inter-Branch Sci-Tech Conf:Portable neutron generators and technologies on its base,26−30 May 2004, VNIIA, Moscow, pp 81−97
• 3. Dense Z-pinches (2005) 6th Int Conf on Dense Z-Pinches and Applications, Oxford, UK. AIP Conference Proceedings, vol. 808
• 4. Dubrovsky AV, Gribkov VA (2000) Installations based on high efficiency high rep rate miniature DPF chambers for material science. Nukleonika 45;3:159−162
• 5. Gribkov VA (2005) Plasma-focus based radiation sources for nanotechnology. In: Emerging applications of radiation in nanotechnology. IAEA, Vienna. IAEATECDOC-1438, pp 233–237
• 6. Gribkov VA, Orlova MA (2004) On various possibilities in pulsed radiation biochemistry and chemistry. Radiat Environ Biophys 43:303−309
• 7. Gribkov VA, Pimenov VN, Ivanov LI et al. (2003) Interaction of high temperature deuterium plasma streams and fast ion beams with stainless steels in Dense Plasma Focus device. J Phys D 36:1817−1825
• 8. Lee S, Lee P, Zhang G et al. (1998) High rep rate high performance plasma focus as a powerful radiation source.IEEE Trans Plasma Sci 26;4:1119−1126
• 9. Mather JW (1964) Investigation of the high-energy acceleration mode in the coaxial gun. Phys Fluids 7;Suppl:28–32
• 10. Petrov DP, Filippov NV, Filippova TI, Khrabrov VA (1958) Powerful pulsed gas discharge in chambers with conductive walls. In: Plasma physics and a problem of controlled thermonuclear fusion reactions. Academy of Sciences of the USSR, Moscow. Vol. 4, pp 170−181 (in Russian)
• 11. Pikaev AK (1985) Sovremennaya radiacionnaya khimiya.Vol. 1. Osnovnye polozheniya eksperimental’naya tekhnika. Nauka, Moscow
• 12.Pikaev AK (1986) Sovremennaya radiacionnaya khimiya.Vol. 2. Radioliz gazov i zhidkostej. Nauka, Moscow
• 13. Pikaev AK (1988) Sovremennaya radiacionnaya khimiya.Vol. 3. Tverdoe telo i polimery, prikladnye aspekty.Nauka, Moscow
• 14. Scholz M, Bieńkowska B, Gribkov VA (2002) Dense Plasma Focus for applications in positron emission tomography. Czechoslovak J Phys 52;Suppl D:D85−D92
• 15. Stygar WA, Cuneo ME, Vesey RA et al. (2005)Theroretical z-pinch scaling relations for thermonuclearfusion experiments. Phys Rev E 72:026404
• 16. Tartari A, Da Re A, Mezzetti F, Angeli E, De Chiara P (2004) Feasibility of X-ray interstitial radiosurgery based on plasma focus device. Nucl Instrum Meth Phys Res B 213:607−610
• 17.Toader EI, Covlea V, Graham WG, Steen P (2004) High density and low temperature direct current reflex plasma source. Rev Sci Instrum 75:382−386