Magnetizing a Complex Plasma without a Magnetic Field

Kählert, H.; Carstensen, J.; Bönitz, M.; Löwen, Hartmut; Greiner, Franko; Piel, A.

doi:10.1103/physrevlett.109.155003

Cited by 70 publications

(71 citation statements)

References 37 publications

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“…Our simulation results can be verified in experiments of dusty plasmas either in magnetic fields [37] or in rotating electrodes which formally lead to the same equations of motion [10,12,13]. Binary systems can also be realized in dusty plasmas, e.g., Ref.…”

Section: Discussionsupporting

confidence: 52%

“…In particular, the motion of few-particle clusters in magnetic fields has been studied both by experiments and simulation [10,12]. The dynamics of three-dimensional ionic binary mixture have also been under investigation in early as well as recent research [18][19][20][21], with a particular focus on astrophysical plasmas and those encountered in inertial confinement fusion.…”

Section: Introductionmentioning

confidence: 99%

“…Though the presence of a magnetic field does not alter the equilibrium static properties, such as phase transitions, the dynamics are strongly affected [9]. Due to the Lorentz force, the charged particles exhibit a circular motion [10][11][12] which is expected to slow the dynamics down. Therefore the magnetic field opens the fascinating possibility to change the dynamical properties of the system externally without changing the system itself, e.g., Ref.…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of two-dimensional one-component and binary Yukawa systems in a magnetic field

2014

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We consider a two-dimensional complex plasma layer containing charged dust particles in a perpendicular magnetic field. Computer simulations of both one-component and binary systems are used to explore the equilibrium particle dynamics in the fluid state. The mobility is found to scale with the inverse of the magnetic field strength (Bohm diffusion) for strong fields. For bidisperse mixtures, the magnetic field dependence of the long-time mobility depends on the particle species providing an external control of their mobility ratio. For large magnetic fields, even a twodimensional model porous matrix can be realized composed by the almost immobilized high-charge particles which act as obstacles for the mobile low-charge particles.

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Section: Discussionsupporting

confidence: 52%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Dynamics of two-dimensional one-component and binary Yukawa systems in a magnetic field

2014

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“…Crystalline and strongly coupled fluid states [15,16] also occur naturally in dusty plasmas due to the strong Coulomb interaction between the grains. Even though the dust particles themselves are difficult to magnetize [17], their screened interaction, and thus, their collective behavior, can be affected significantly by an external magnetic field [18].Dusty plasma experiments are often confronted with ion flows due to electric fields, especially in the sheath region. They affect the charging of the dust grains [19], their mutual interaction due to the formation of wake potentials [20,21], and give rise to drag forces [22,23].…”

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confidence: 99%

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confidence: 99%

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

Kählert

Joost

Ludwig

et al. 2016

Contrib. Plasma Phys.

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The density response function for streaming ions in homogeneous, parallel electric and magnetic fields is derived self-consistently from kinetic theory. Ion-neutral collisions are treated with the Bhatnagar-GrossKrook collision operator assuming a constant ion-neutral collision frequency. The result accounts for the nonMaxwellian distribution function of the ions and is valid in the full range from weak to strong magnetization. It provides the basis for various linear response calculations in the context of magnetized complex plasmas, where streaming ions interact with highly charged dust particles under the influence of a strong external magnetic field. Magnetic fields play an important role in plasma physics because they allow one to confine and manipulate charged particles externally. Plasma properties such as wave spectra, particle diffusion, heat conduction, or plasma instabilities can be strongly modified when the plasma is magnetized. Strong magnetic fields of several Tesla are not only encountered in magnetic confinement or magnetic liner inertial fusion experiments [1] but have also become of interest for complex plasmas research [2,3]. By adjusting the magnetic field strength it is possible to create plasma states where only the electrons, electrons and ions, or possibly all three charged particle species including the dust particles are magnetized [4]. Several new phenomena have been observed in experiments with magnetic fields, including a slow rotation of the entire dust cloud [5][6][7][8][9], the spinning of dust particles [10], and complicated flow patterns [11]. In recent experiments with strong magnetic fields on the order of a few Tesla, sufficient to magnetize not only the electrons but the ions as well, filaments appeared in the discharge [12]. The dynamics of a dust particle pair also showed a pronounced response to magnetic fields of this magnitude [13]. Experiments performed at the Magnetized Dusty Plasma Experiment (MDPX) at Auburn University [14] further demonstrate that ordered structures of a titanium mesh can be imposed on the dust particles under these conditions. Crystalline and strongly coupled fluid states [15,16] also occur naturally in dusty plasmas due to the strong Coulomb interaction between the grains. Even though the dust particles themselves are difficult to magnetize [17], their screened interaction, and thus, their collective behavior, can be affected significantly by an external magnetic field [18].Dusty plasma experiments are often confronted with ion flows due to electric fields, especially in the sheath region. They affect the charging of the dust grains [19], their mutual interaction due to the formation of wake potentials [20,21], and give rise to drag forces [22,23]. Under the influence of an electric field the ion velocity distribution may considerably differ from a displaced Maxwellian due to collisions with the neutral gas. Various phenomena related to the interaction between ions and dust particles have been shown to be crucially affected by the different dist...

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The Energy‐Autocorrelation Function in Magnetized and Unmagnetized Strongly Coupled Plasmas

Ott

Bönitz

2016

Contrib. Plasma Phys.

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The energy-autocorrelation function is calculated for a screened Coulomb system in equilibrium and the contributions of different energy transport channels to the total heat conductivity are explored for magnetized and unmagnetized systems. A special focus is on the time scales of the energy-autocorrelation function which contribute to the field-parallel enhancement of heat conduction in strongly coupled plasmas. The investigation is based on first-principle molecular dynamics simulations.

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Magnetizing a Complex Plasma without a Magnetic Field

Cited by 70 publications

References 37 publications

Dynamics of two-dimensional one-component and binary Yukawa systems in a magnetic field

Dynamics of two-dimensional one-component and binary Yukawa systems in a magnetic field

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

The Energy‐Autocorrelation Function in Magnetized and Unmagnetized Strongly Coupled Plasmas

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