Convective Dust Clouds Driven by Thermal Creep in a Complex Plasma

Mitic, Slobodan; Sütterlin, R.; Höfner, A. V. Ivlev H.; Thoma, Markus H.; Zhdanov, S. K.; Morfill, G. E.

doi:10.1103/physrevlett.101.235001

Cited by 48 publications

(36 citation statements)

References 30 publications

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“…2(b) is often seen in experiments on spatially extended dust clouds and may possibly derive from intrinsic plasma forces 13 or unwanted thermal gradients due to the tempered electrodes. 25 Performing both the extinction measurement and the laser slice technique simultaneously, dynamical phenomena such as dust density waves can be investigated with respect to their global and local properties. 27…”

Section: Extinction Measurementmentioning

confidence: 99%

Computer tomography of large dust clouds in complex plasmas

Killer

Himpel

Melzer

2014

Review of Scientific Instruments

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The dust density is a central parameter of a dusty plasma. Here, a tomography setup for the determination of the three-dimensionally resolved density distribution of spatially extended dust clouds is presented. The dust clouds consist of micron-sized particles confined in a radio frequency argon plasma, where they fill almost the entire discharge volume. First, a line-of-sight integrated dust density is obtained from extinction measurements, where the incident light from an LED panel is scattered and absorbed by the dust. Performing these extinction measurements from many different angles allows the reconstruction of the 3D dust density distribution, analogous to a computer tomography in medical applications.

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Section: Extinction Measurementmentioning

confidence: 99%

Computer tomography of large dust clouds in complex plasmas

Killer

Himpel

Melzer

2014

Review of Scientific Instruments

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“…Therefore it is proportional to the thermal conductivity of the gas κ T , the temperature gradient and the squared particle radius: F th ∝ a 2 κ T ∇T N . Thermophoresis can be used to levitate particles in a plasma chamber against gravity into regions in the bulk plasma, providing similar conditions as experiments in microgravity, and it can lead to other interesting phenomena such as convection, circulations and formation of structures [107,108,109,110].…”

Section: Forcesmentioning

confidence: 99%

Phase Transitions in Two-Dimensional Complex Plasmas

Knapek¹

2011

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“…Vaulina et al 4,[16][17][18] and Samarian et al 19 attributed that dust charge gradient in an inhomogeneous plasma in the presence of a non-electrostatic force orthogonal to it causes an instability which leads to the formation of the dust vortices. Mittic et al 20 reported the formation of dust vortices due to thermal creep flow (TCF) in a low frequency discharge produced in an inhomogeneously heated vertical glass tube at low pressures. Later, Flanagan et al 21 designed an experiment to isolate TCF from other temperature gradient driven effects and verified its role on vorticity formation at low pressures.…”

Section: Introductionmentioning

confidence: 99%

Observation of dust torus with poloidal rotation in direct current glow discharge plasma

et al. 2015

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Observation of dust cloud rotation in parallel-plate DC glow discharge plasma is reported here. The experiments are carried out at high pressures ($130 Pa) with a metallic ring placed on the lower electrode (cathode). The dust cloud rotates poloidally in the vertical plane near the cathode surface. This structure is continuous toroidally. Absence of magnetic field rules out the possibility of E Â B induced ion flow as the cause of dust rotation. The dust rotational structures exist even with water cooled cathode. Therefore, temperature gradient driven mechanisms, such as thermophoretic force, thermal creep flow, and free convection cannot be causing the observed dust rotation. Langmuir probe measurement reveals the existence of a sharp density gradient near the location of the rotating dust cloud. The gradient in the density, giving rise to a gradient in the ion drag force, has been identified as the principal cause behind the rotation of dust particles. V C 2015 AIP Publishing LLC. [http://dx.

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Convective Dust Clouds Driven by Thermal Creep in a Complex Plasma

Cited by 48 publications

References 30 publications

Computer tomography of large dust clouds in complex plasmas

Computer tomography of large dust clouds in complex plasmas

Phase Transitions in Two-Dimensional Complex Plasmas

Observation of dust torus with poloidal rotation in direct current glow discharge plasma

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