On the orbital motion limited theory for a small body at floating potential in a Maxwellian plasma

J. E. ALLEN; B. M. ANNARATONE; U. de ANGELIS

doi:10.1017/S0022377800008345

Abstract

The condition for the validity of the orbital motion limited (OML) theory is reviewed, with reference to the calculation of the floating potential attained by a spherical body immersed in a plasma. It is shown that the OML theory is never satisfied in Maxwellian plasmas, even in the case of very small bodies, i.e. those with radii much smaller than the plasma Debye length. The case considered is that where the ion temperature is less than or equal to the electron temperature. The results are relevant to the theory of dusty plasmas, where the OML theory has been much employed.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Lampe, Martin Joyce, Glenn Ganguli, Gurudas and Gavrishchaka, Valeriy 2000. Interactions between dust grains in a dusty plasma. Physics of Plasmas, Vol. 7, Issue. 10, p. 3851.

Tomme, E B Annaratone, B M and Allen, J E 2000. Damped dust oscillations as a plasma sheath diagnostic. Plasma Sources Science and Technology, Vol. 9, Issue. 2, p. 87.

Lapenta, Giovanni 2000. Linear theory of plasma wakes. Physical Review E, Vol. 62, Issue. 1, p. 1175.

Tomme, E. B. Law, D. A. Annaratone, B. M. and Allen, J. E. 2000. Parabolic Plasma Sheath Potentials and their Implications for the Charge on Levitated Dust Particles. Physical Review Letters, Vol. 85, Issue. 12, p. 2518.

Tskhakaya, D D Tsintsadze, N L Shukla, P K and Stenflo, L 2001. Re-Examination of Dust Grain Charging in a Plasma. Physica Scripta, Vol. 64, Issue. 4, p. 366.

Lampe, Martin Gavrishchaka, Valeriy Ganguli, Gurudas and Joyce, Glenn 2001. Effect of Trapped Ions on Shielding of a Charged Spherical Object in a Plasma. Physical Review Letters, Vol. 86, Issue. 23, p. 5278.

Nakamura, Y. 2001. Scattering and extinction of ion beams in a dusty plasma device. Physics of Plasmas, Vol. 8, Issue. 12, p. 5086.

Annaratone, B. M. Khrapak, A. G. Ivlev, A. V. Söllner, G. Bryant, P. Sütterlin, R. Konopka, U. Yoshino, K. Zuzic, M. Thomas, H. M. and Morfill, G. E. 2001. Levitation of cylindrical particles in the sheath of an rf plasma. Physical Review E, Vol. 63, Issue. 3,

Samarian, A.A and James, B.W 2001. Sheath measurement in rf-discharge plasma with dust grains. Physics Letters A, Vol. 287, Issue. 1-2, p. 125.

Ignatov, A. M. 2002. Heat exchange in dusty plasma. Plasma Physics Reports, Vol. 28, Issue. 10, p. 847.

Tsytovich, V. N. Morfill, G. E. and Thomas, H. 2002. Complex plasmas: I. complex plasmas as unusual state of matter. Plasma Physics Reports, Vol. 28, Issue. 8, p. 623.

Piel, A and Melzer, A 2002. Dynamical processes in complex plasmas. Plasma Physics and Controlled Fusion, Vol. 44, Issue. 1, p. R1.

Lapenta, Giovanni 2002. Nature of the force field in plasma wakes. Physical Review E, Vol. 66, Issue. 2,

Raadu, Michael A 2003. Generalised Sagdeev Potentials for Dusty Plasmas with Varying Grain Charges. Physica Scripta, Vol. 68, Issue. 4, p. 266.

Akdim, M. R. and Goedheer, W. J. 2003. Modeling of dust in a silane/hydrogen plasma. Journal of Applied Physics, Vol. 94, Issue. 1, p. 104.

Akdim, M. R. and Goedheer, W. J. 2003. Modeling of self-excited dust vortices in complex plasmas under microgravity. Physical Review E, Vol. 67, Issue. 5,

Akdim, M. R. and Goedheer, W. J. 2003. Modeling the effect of dust on the plasma parameters in a dusty argon discharge under microgravity. Physical Review E, Vol. 67, Issue. 6,

Amemiya, H and Nakamura, Y 2003. Scattering of an ion beam due to Coulomb interactions with charged fine particles. Journal of Physics D: Applied Physics, Vol. 36, Issue. 22, p. 2828.

Akdim, M R Goedheer, W J and Dahiya, R P 2003. Modelling of two differently sized dust species in plasmas under micro-gravity. New Journal of Physics, Vol. 5, Issue. , p. 20.

Bryant, Paul 2003. Floating potential of spherical probes and dust grains in collisional plasmas. Journal of Physics D: Applied Physics, Vol. 36, Issue. 22, p. 2859.

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On the orbital motion limited theory for a small body at floating potential in a Maxwellian plasma

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