PHASE STATES OF MACROPARTICLES IN PLASMA WITH HOT ELECTRONS AT PRESENCE OF ION BEAM
Keywords:
macroparticles, dusty plasma, ion beam, evaporation, electric potential
Abstract
The evaporation possibility of micro sized metallic particles during them passage through the region of a magnetized plasma with a Maxwellian velocity distribution with the electron temperature in the range Te=1...100eV at presence of an ion beam with the energy in the range εb=1...6keV is studied theoretically. The floating potential of a macroparticle is obtained using the OML theory, the effect of the electron temperature and the energy of the ion beam on its magnitude is studied. The equation of energy balance on the macroparticle surface is obtained, such energy exchange mechanisms as collisions of particles of an ion beam and plasma particles with the macroparticle, thermal radiation of the macroparticle, as well as cooling due to the evaporation of substance from the macroparticle surface are taken into account. The effect of the temperature of plasma electrons and the ion beam energy on the stationary temperature of the macroparticle is studied. It is shown that for the given plasma and ion beam parameters, the temperature of the copper macroparticle is below the boiling point so that the evaporation of the macroparticle occurs at temperatures below the boiling point. The dependences of the macroparticle evaporation time on the electron temperature and the energy of the ion beam have been obtained.Downloads
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References
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Published
2017-10-20
Cited
How to Cite
Bizyukov, O. A., Chibisov, O. D., & Kutenko, O. I. (2017). PHASE STATES OF MACROPARTICLES IN PLASMA WITH HOT ELECTRONS AT PRESENCE OF ION BEAM. East European Journal of Physics, 4(3), 48-53. https://doi.org/10.26565/2312-4334-2017-3-07
Section
Original Papers
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