Shielding of a test charge: Role of plasma production and loss balance

Khrapak, S. A.; Ivlev, A. V.; Morfill, G. E.

doi:10.1063/1.3377786

Cited by 39 publications

(45 citation statements)

References 31 publications

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“…In complex plasmas, the average interparticle distance compared to the particles' diameters is typically large enough to allow for an approximation of point-like particles and hence a screened Coulomb potential for point particles is appropriate. In addition to the screening length, in complex plasmas also a second repulsive length scale arises from the non-equilibrium ionization-recombination balance [7,8] which gives rise to a double Yukawa potential at interparticle distances r as U (r) k B T = Γ r [exp(−κr) + ǫ exp(−ακr)] .…”

Section: Introductionmentioning

confidence: 99%

Glass-transition properties of Yukawa potentials: From charged point particles to hard spheres

et al. 2014

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The glass transition is investigated in three dimensions for single and double Yukawa potentials for the full range of control parameters. For vanishing screening parameter, the limit of the onecomponent plasma is obtained; for large screening parameters and high coupling strengths, the glass-transition properties crossover to the hard-sphere system. Between the two limits, the entire transition diagram can be described by analytical functions. Different from other potentials, the glass-transition and melting lines for Yukawa potentials are found to follow shifted but otherwise identical curves in control-parameter space.

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Section: Introductionmentioning

confidence: 99%

Glass-transition properties of Yukawa potentials: From charged point particles to hard spheres

et al. 2014

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“…Although it is well recognized that the long range asymptote of the electrical potential can be modified (by e.g. continuous plasma absorption on the grain surface [21][22][23][24] or plasma ionization/recombination effects [25]), this is expected to affect merely grain-grain interactions, but not the momentum transfer from the ions and electrons.…”

Section: Formulationmentioning

confidence: 99%

Electron and ion thermal forces in complex (dusty) plasmas

Khrapak

2013

Physics of Plasmas

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Expressions for the ion and electron thermal forces acting on a charged grain, suspended in a weakly ionized plasma subject to temperature gradients, are derived. The main emphasize is on the conditions pertinent to the investigations of complex (dusty) plasmas in gas discharges. Estimates show that for the electron temperature gradients ∼ O(eV/cm) typically encountered in laboratory gas discharges, the electron thermal force can become an important player among other forces acting on micron-size grains.

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“…Unlike the two-dimensionally confined, mesoscopic charged particles, ions are free to move in 3D space in the absence of external forces. Under these conditions the effective interaction potential energy U Y (x) between charged particles at sufficiently large mutual distance follows the screened Coulomb (Yukawa)-type form [18] …”

Section: A Yukawa Monolayermentioning

confidence: 99%

Glass transition of charged particles in two-dimensional confinement

et al. 2015

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The glass transition of mesoscopic charged particles in two-dimensional confinement is studied by modecoupling theory. We consider two types of effective interactions between the particles, corresponding to two different models for the distribution of surrounding ions that are integrated out in coarse-grained descriptions. In the first model, a planar monolayer of charged particles is immersed in an unbounded isotropic bath of ions, giving rise to an isotropically screened Debye-Hückel (Yukawa)-type effective interaction. The second, experimentally more relevant system is a monolayer of negatively charged particles that levitate atop a flat horizontal electrode, as frequently encountered in laboratory experiments with complex (dusty) plasmas. A steady plasma current toward the electrode gives rise to an anisotropic effective interaction potential between the particles, with an algebraically long-ranged in-plane decay. In a comprehensive parameter scan that covers the typical range of experimentally accessible plasma conditions, we calculate and compare the mode-coupling predictions for the glass transition in both kinds of systems.

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Shielding of a test charge: Role of plasma production and loss balance

Cited by 39 publications

References 31 publications

Glass-transition properties of Yukawa potentials: From charged point particles to hard spheres

Glass-transition properties of Yukawa potentials: From charged point particles to hard spheres

Electron and ion thermal forces in complex (dusty) plasmas

Glass transition of charged particles in two-dimensional confinement

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