Three-dimensional dusty plasma in a strong magnetic field: Observation of rotating dust tori

Choudhary, Mangilal; Bergert, Roman; Mitic, Slobodan; Thoma, Markus H.

doi:10.1063/5.0004842

Cited by 37 publications

(40 citation statements)

References 46 publications

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“…[ 38 ] In the present experiments, T e variation across the radial distance ( r ∼ 6–16 mm) is expected to be negligible. [ 25 ] Therefore, the radial variation of V f is assumed to be the V p variation at a given magnetic field strength. A cylindrical probe of length ∼2 mm and radius 0.125 mm is used to measure radial variation of V f [ 12 ] from disk edge region ( r ∼ 4 mm) to ring edge region ( r ∼ 18 mm).…”

Section: Discussionmentioning

confidence: 99%

“…It has been reported experimentally that 3D dusty plasma exhibits the vortex motion instead of azimuthal rotation in the presence of a strong magnetic field. [25] However, a 2D dust cluster always rotates in the direction of the magnetic field-induced ion flow. [19,26] To investigate the dynamics of a nearly 2D annulus dusty plasma (confined between the co-centric disk and ring) in the presence of a strong magnetic field, two types of combinations of a disk and ring are used.…”

Section: Annulus Dusty Plasma Dynamics In the Presence Of A Magnetic mentioning

confidence: 99%

“…One of our previous studies reports the influence of ring materials (conducting and non‐conducting) on the depth of the confining potential well in the presence of a magnetic field. [ 25 ] This is probably due to the difference of surface potentials of the materials in an rf discharge. A dip potential well is expected between the conducting co‐centric disk and ring.…”

Section: Annulus Dusty Plasma Dynamics In the Presence Of A Magnetic mentioning

confidence: 99%

“…They observed the inversion of rotation at lower magnetic field strength and a slow increase of the angular frequency after B > 0.1 T. Karasev et al [23] reported a rotating dust cluster and shell structure in the presence of a strong magnetic field. Apart from DC discharges, some interesting features of 3D dusty plasmas, as damping of dust-acoustic waves [24] and counter-rotating dust torus [25] have been reported in recent experiments by Choudhary et al in rf discharge. Melzer et al [26] investigated the effect of a strong magnetic field (B > 5 T) to a dust cluster confined by a ring shaped electrode in an rf discharge.…”

Section: Introductionmentioning

confidence: 99%

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Rotational properties of annulus dusty plasma in a strong magnetic field

Choudhary

Bergert

Moritz

et al. 2020

Contributions to Plasma Physics

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The collective dynamics of an annulus dusty plasma formed between a co-centric conducting (non-conducting) disk and ring configuration is studied in a strongly magnetized radiofrequency (rf) discharge. A superconducting electromagnet is used to introduce a homogeneous magnetic field to the dusty plasma medium. In the absence of the magnetic field, the dust grains exhibit thermal motion around their equilibrium position. The dust grains start to rotate in the anticlockwise direction with increasing magnetic field (B > 0.02 T), and the constant value of the angular frequency at various strengths of the magnetic field confirms the rigid body rotation. The angular frequency of dust grains linearly increases up to a threshold magnetic field (B > 0.6 T) and after that its value remains nearly constant in a certain range of magnetic field. Further increase in magnetic field (B > 1 T) lowers the angular frequency. Low value of the angular frequency is expected by reducing the width of the annulus dusty plasma or the input rf power. The azimuthal ion drag force due to the magnetic field is assumed to be the energy source which drives the rotational motion. The resultant radial electric field in the presence of a magnetic field determines the direction of rotation. The variation of floating (plasma) potential across the annular region at given magnetic field explains the rotational properties of the annulus dusty plasma in the presence of a magnetic field.

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Section: Discussionmentioning

confidence: 99%

Section: Annulus Dusty Plasma Dynamics In the Presence Of A Magnetic mentioning

confidence: 99%

Section: Annulus Dusty Plasma Dynamics In the Presence Of A Magnetic mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Rotational properties of annulus dusty plasma in a strong magnetic field

Choudhary

Bergert

Moritz

et al. 2020

Contributions to Plasma Physics

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“…2004; Saitou & Ishihara 2013; Choudhary, Mukherjee & Bandyopadhyay 2017, 2018; Choudhary et al. 2020). In a dusty plasma, a dust particles are assumed to be spherical capacitors, which allows us to determine the surface potential and the net charge on it.…”

Section: Introductionmentioning

confidence: 99%

Comparative study of the surface potential of magnetic and non-magnetic spherical objects in a magnetized radio-frequency discharge

et al. 2020

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We report measurements of the time-averaged surface floating potential of magnetic and non-magnetic spherical probes (or large dust particles) immersed in a magnetized capacitively coupled discharge. In this study, the size of the spherical probes is taken greater than the Debye length. The surface potential of a spherical probe first increases, i.e. becomes more negative at low magnetic field ( $B < 0.05\ \textrm {T}$ ), attains a maximum value and decreases with further increase of the magnetic field strength ( $B > 0.05\ \textrm {T}$ ). The rate of change of the surface potential in the presence of a $B$ -field mainly depends on the background plasma and types of material of the objects. The results show that the surface potential of the magnetic sphere is higher (more negative) compared with the non-magnetic spherical probe. Hence, the smaller magnetic sphere collects more negative charges on its surface than a bigger non-magnetic sphere in a magnetized plasma. The different sized spherical probes have nearly the same surface potential above a threshold magnetic field ( $B > 0.03\ \textrm {T}$ ), implying a smaller role of size dependence on the surface potential of spherical objects. The variation of the surface potential of the spherical probes is understood on the basis of a modification of the collection currents to their surface due to charge confinement and cross-field diffusion in the presence of an external magnetic field.

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Dynamics of dust particles in the glow discharge stratum in crossed E × B field

Abdirakhmanov

Kodanova

Рамазанов

2022

Contrib. Plasma Phys

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In this work, the dynamic behaviour of micron‐sized dust particles suspended in the glow discharge stratum at low pressure in the crossed magnetic and electric fields was experimentally studied. The observations showed that the dust particles move in the direction opposite to the ExB drift with increasing magnetic field induction. When the magnetic field induction reaches a threshold point (B > 10 mT), the dust particles begin to rotate, forming pair of counter‐rotating vortex in the horizontal plane. It was also found that the shape of the dust structures changes from a disk shape to an ellipsoid shape. The dynamic behaviour of the dust vortices was analysed using the PIV (particle image velocimetry) method. The quantitative explanation of the generation of the co‐vortex rotation observed in the experiment was explained on the basis of the charge gradient of the dust particles, which was orthogonal to the ion drag force.

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Three-dimensional dusty plasma in a strong magnetic field: Observation of rotating dust tori

Cited by 37 publications

References 46 publications

Rotational properties of annulus dusty plasma in a strong magnetic field

Rotational properties of annulus dusty plasma in a strong magnetic field

Comparative study of the surface potential of magnetic and non-magnetic spherical objects in a magnetized radio-frequency discharge

Dynamics of dust particles in the glow discharge stratum in crossed E × B field

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