The electron forewake: Shadowing and drift-energization as flowing magnetized plasma encounters an obstacle

Haakonsen, Christian Bernt; Hutchinson, I. H.

doi:10.1063/1.4932006

Cited by 6 publications

(1 citation statement)

References 47 publications

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“…In dusty plasmas under normal conditions, ions streaming past an isolated grain focus behind the grain and give rise to wakefield. It has routinely been a common analytical as well as numerical observation in dusty plasmas [26][27][28][29]. A detailed description of these wakes delineating the grain-plasma dynamics under cryogenic environment is presented here.…”

Section: Simulation Resultsmentioning

confidence: 99%

Ultracold ions wake in dusty plasmas

Sundar

Moldabekov

2020

New J. Phys.

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Motivated by the recent experimental realization of ultracold dusty plasma (2019 Sci. Rep. 9 3261), we present the results of particle-in-cell simulation with Monte-Carlo-collisions for wake behind a dust particle due to focusing of ions at superfluid helium temperature (∼2 K). Dynamical screening (wakefield) defines structural and dynamical properties of charged dust particles in plasmas such as phase transition, crystal formation, vibration modes (waves) etc. Here, we delineate in detail the dependence of wake strength on the streaming velocity of ions and on the ion-neutral charge exchange collision frequency (neutrals density) in the ultracold dusty plasma. Lowering the temperature to ultracold level leads to a wake pattern behind a dust particle that completely differs from the wake at normal conditions. For wide range of parameters, most remarkable features of the wakefield are (i) the formation of wake pattern with two maxima split in transverse to ion flow direction in the downstream area, (ii) pronounced inverse V shape of the wakefield closely resembling the wake in quark-gluon plasma and dense quantum plasma (warm dense matter), and (iii) the inter-dust attraction region in transverse direction. The latter shows that molecule-like interaction between dust particles is realized in ultracold dusty plasmas. These observations show a fundamental difference of ultracold dusty plasma physics from well studied complex plasmas at normal conditions.

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Section: Simulation Resultsmentioning

confidence: 99%

Ultracold ions wake in dusty plasmas

Sundar

Moldabekov

2020

New J. Phys.

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Fore-wake excitations from moving charged objects in a complex plasma

Tiwari

Sen

2016

Physics of Plasmas

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A charged object moving at a supersonic speed in a plasma creates the familiar Mach cone structure in its wake but can also give rise to nonlinear wave excitations ahead of it. Using molecular dynamic simulations, we explore such fore-wake excitations in a strongly coupled dusty plasma and demonstrate the existence of precursor solitonic pulses and dispersive shock waves in that region. The excitation conditions as well as the propagation characteristics of such pulses are delineated as a function of the projectile velocity, the plasma density, the Coulomb coupling parameter, and the amount of charge on the projectile. Our simulation results provide a kinetic basis for earlier fluid model calculations and also give insights into the dynamical processes responsible for such excitations that can aid in future experimental and application oriented studies.

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Wake effects of a stationary charged grain in streaming magnetized ions

Sundar

2018

Phys. Rev. E

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A systematic numerical study of wake potential and ion density distribution of a single grain in flowing ions under the influence of a magnetic field applied along the flow is presented. A strong magnetic field introduces ion focus depletion behind grains, facilitating the entrance of electrons far in the downstream towards the grain. It is shown that the magnetic field suppresses the amplitude of the wake potential and modifies the ion density distribution substantially. The wake peak potential and position characteristics and density distribution of plasma constituents in the presence of a magnetic field and charge-exchange collisions for the subsonic, sonic, and supersonic regime are also delineated. In the subsonic regime, simulations demonstrate the accumulation of ions near the dust grain in the transverse direction, while complete suppression of oscillations in the transverse direction takes place for the sonic and supersonic regime.

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The electron forewake: Shadowing and drift-energization as flowing magnetized plasma encounters an obstacle

Cited by 6 publications

References 47 publications

Ultracold ions wake in dusty plasmas

Ultracold ions wake in dusty plasmas

Fore-wake excitations from moving charged objects in a complex plasma

Wake effects of a stationary charged grain in streaming magnetized ions

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