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Journals & Magazines >IEEE Transactions on Plasma S... >Volume: 32 Issue: 2

Wave drag due to dust acoustic waves in collisional dusty plasmas

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D. Winske
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Abstract:

The ion drag force on dust grains in a dusty plasma contributes significantly to the formation of equilibrium dust layers and void regions in radio-frequency discharges. ...Show More

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Abstract:

The ion drag force on dust grains in a dusty plasma contributes significantly to the formation of equilibrium dust layers and void regions in radio-frequency discharges. In addition to the drag due to the direct collection of ions and to momentum transfer of ions in the electric field near grains, dust grains can also be subject to a drag force due to the effect of coherent waves, such as dust acoustic waves that can grow because of the drift of plasma ions relative to charged grains induced by an externally imposed electric field. Here, we examine wave drag due to unstable dust acoustic waves in a collisional dusty plasma using numerical simulations. We study the drag as a function of grain size as well as neutral-ion and neutral-dust collisions in both one-dimensional periodic systems, in which it is easier to study the instability properties per se, and in aperiodic configurations in order to assess effects associated with dust drag and void formation. For the parameter range considered, we find that in the absence of background collisions, the instability tends to saturate by trapping the plasma ions in the electrostatic waves, which does not affect the dust grains very much. Including ion-neutral collisions tends to suppress ion trapping, which in turn leads to larger wave amplitudes and trapping of the dust, resulting in significant drag on the dust grains. Inclusion of neutral-dust collisions leads to a grain size-dependent result, with the persistence of trapping of, and thus drag on, larger grains only. For the parameters of this study, the wave drag force is much larger than the ion drag usually considered.
Published in: IEEE Transactions on Plasma Science ( Volume: 32, Issue: 2, April 2004)
Page(s): 663 - 674
Date of Publication: 28 June 2004

ISSN Information:

DOI: 10.1109/TPS.2004.826088
References is not available for this document.
Contents

I. Introduction

The dust acoustic wave (DAW) is a fundamental mode in a dusty plasma, whose basic properties in collisionless systems have been well studied [1], [2]. The principal characteristics of DAWs have been verified experimentally [3] [4]– [6]. When the plasma ions drift relative to the charged dust, DAWs are driven unstable [7], as has been shown by numerical simulations [8]. Dust acoustic waves can also exhibit interesting nonlinear steepened wave forms [9], [10], which have recently been applied to comets [11]. DAWs persist in collisional plasmas, which are representative of many experimental regimes [12] [13] [14]. The nonlinear behavior in the presence of collisions can be somewhat unexpected; while linear theory indicates lower linear growth rates as the collision rate is increased, the nonlinear saturation levels can be enhanced for higher collision frequencies [15]. Theory has shown the relation of DAWs to other wave modes in dusty plasmas, both at higher [16] and lower frequencies [14], [17], [18] that can also exist in these experimental regimes. Moreover, strongly coupled effects can modify the properties of DAWs, both at long and short wavelengths [19]–[22]. This has been shown both experimentally [23], [24] and via simulations [25]. When the Coulomb coupling parameter is large, crystalline structures develop and waves are associated with the regular array of dust grains. The relation of these dust lattice waves to dust acoustic waves has also been determined [26], [27].

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