Streaming Complex Plasmas: Ion Susceptibility for a Partially Ionized Plasma in Parallel Electric and Magnetic Fields

Kählert, H.; Joost, Jan‐Philip; Ludwig, P.; Bönitz, M.

doi:10.1002/ctpp.201500088

Cited by 7 publications

(7 citation statements)

References 35 publications

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“…Our results have inspired other researchers in wider fields beyond plasma physics [64][65][66][67][68][69][70][71][72][73][74][75][76]. The followings are examples.…”

Section: Summary and Subsequent Developmentsupporting

confidence: 68%

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Dynamic Behavior of Dust Particles in Plasmas

Saitou¹,

Ishihara²

2020

Progress in Fine Particle Plasmas

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Experimentally observed dynamic behavior, such as a particle circulation under magnetic field, a bow shock formation in an upper stream of an obstacle, etc., will be reviewed. Dust particles confined in a cylindrical glass tube show a dynamic circulation when strong magnetic field is applied from the bottom of the tube using a permanent magnet. The circulation consists of two kinds of motions: one is a toroidal rotation around the tube axis, and the other is a poloidal rotation. Dust particles are blown upward from near the bottom of the tube against the gravity neighborhood of the tube axis. A two-dimensional supersonic flow of dust particles forms a bow shock in front of a needlelike-shaped obstacle when the flow crosses the obstacle. The slower flow passes the obstacle as a laminar flow. A streamlineshaped void where dust particles are not observed is formed around the obstacle.

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“…Our results have inspired other researchers in wider fields beyond plasma physics [64][65][66][67][68][69][70][71][72][73][74][75][76]. The followings are examples.…”

Section: Summary and Subsequent Developmentsupporting

confidence: 68%

“…They reported that the turbulence was able to occur at a low Reynolds number if the Weissenberg number was high. Kähler et al derived the ion susceptibility in a partially ionized plasma [65]. Tadsen et al reported that the dust cloud confined in a magnetized plasma was diamagnetic [66].…”

Section: Summary and Subsequent Developmentmentioning

confidence: 99%

Dynamic Behavior of Dust Particles in Plasmas

Saitou¹,

Ishihara²

2020

Progress in Fine Particle Plasmas

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“…We expect that our results will also be of direct relevance for experiments. Finally, an interesting question of current interest is how wake effects are modified in a magnetic field, where experiments 33 and linear response simulations 34,35 have observed a drastic modification of the wake potential with increasing field strength.…”

Section: Summary and Discussionmentioning

confidence: 99%

Impact of collisions on the dust wake potential with Maxwellian and non-Maxwellian ions

et al. 2017

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This work examines the formation of wake fields caused by ions streaming around a charged dust particle, using three-dimensional particle-in-cell (PIC) simulations with charge-neutral collisions included. The influence of an external driving electric field, which leads to a non-Maxwellian distribution of ions, is investigated in detail. The wake features formed for non-Maxwellian ions exhibit significant deviations from those observed within the model of a shifted Maxwellian distribution. The dependence of the peak amplitude and position of the wake potential upon the degree of collisionality is analyzed for a wide range of streaming velocities (Mach numbers). In contrast to a shifted Maxwellian distribution of ions, the drift-driven non-Maxwellian distribution exhibits an increase of the wake amplitude of the first attractive peak with increase in collisionality for high streaming velocities. At very low Mach numbers, collision-induced amplification is observed for Maxwellian as well as non-Maxwellian distributions.

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“…While the Coulomb interaction of dust with magnetised ions has been previously studied [13][14][15][16] , particularly in the context of wake effects, there are no known theoretical models by which the momentum transfer associated with this interaction may be calculated. However, the similar problem of Coulomb scattering of a point charge in strong magnetic fields has been treated in the context of ion stopping in a magnetised electron plasma, for which Nersisyan, Toepffer, and Zwicknagel have calculated the energy loss of a charge by treating its binary collision with another charge as a perturbation to its helical motion [17][18][19] .…”

Section: Magnetised Deflectionmentioning

confidence: 99%

Suppression of the ion drag force on dust in magnetized plasmas

James

Coppins

2020

Physics of Plasmas

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Modelling the transport of 'dust' particles in a magnetically confined plasma device is an area of active research, and requires a detailed understanding of the forces experienced by dust immersed in a plasma. One of the most significant of these is the 'ion drag force'. Dust transport codes employ a model of this force that was not specifically designed for fusion plasmas, and so does not consider the relevance of strong magnetic fields. However, it is shown here that the effect of magnetic fields on the ion drag force is significant for such plasmas. In this work, the Monte Carlo code DiMPl is employed to perform the first detailed characterisation of the dependence of the ion drag force on magnetic fields. A semi-empirical model of this dependence is fitted onto the simulation data, so that these magnetic effects may be straightforwardly captured by dust transport codes. The limiting behaviour of the ion drag force in the case of very strong fields is derived analytically, and shown to be consistent with the simulation results. The validity of the results is further motivated through a novel theoretical treatment of the ion drag force at intermediate magnetic field strengths.

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Streaming Complex Plasmas: Ion Susceptibility for a Partially Ionized Plasma in Parallel Electric and Magnetic Fields

Cited by 7 publications

References 35 publications

Dynamic Behavior of Dust Particles in Plasmas

Dynamic Behavior of Dust Particles in Plasmas

Impact of collisions on the dust wake potential with Maxwellian and non-Maxwellian ions

Suppression of the ion drag force on dust in magnetized plasmas

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