The effect of magnetic field on plasma particles in dusty plasma

Karasev, V. Yu.; Дзлиева, Е. С.; D’yachkov, L. G.; Novikov, L. A.; Pavlov, S. I.; Тарасов, С. А.

doi:10.1002/ctpp.201800136

Cited by 16 publications

(5 citation statements)

References 33 publications

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“…Further, it is observed that, even at relatively low magnetic fields (where still h i < 1 ), ensembles of trapped dust particles rotate as a whole around the magnetic field axis, see e.g. (Nunomura et al 1997;Sato et al 2001;Cheung et al 2003;Carstensen et al 2009;Karasev et al 2006Karasev et al , 2019. The rotation direction usually is in the r × direction where r is the (horizontal, radial, perpendicular) electric field that confines the dust particles transverse to the magnetic field.…”

Section: Rotationmentioning

confidence: 99%

Physics of magnetized dusty plasmas

Melzer¹,

Krüger²,

Maier³

et al. 2021

Rev. Mod. Plasma Phys.

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In this review, we summarize recent advances in the field of dusty plasmas at strong magnetic fields. Special emphasis is put on situations where experimental laboratory observations are available. These generally comprise dusty plasmas with magnetized electrons and ions, but unmagnetized dust. The fundamental parameters characterizing a magnetized (dusty) plasma are given and various effects in dusty plasmas under magnetic fields are presented. As examples, the reaction of the dust component to magnetic-field modified plasma properties, such as filamentation, imposed structures, dust rotation, nanodusty plasmas and the resulting forces on the dust are discussed. Further, the behavior of the dust charge is described and shown to be relatively unaffected by magnetic fields. Wake field formation in magnetized discharges is illustrated: the strength of the wake field is found to be reduced with increased magnetic field. The propagation of dust acoustic waves in magnetized dusty plasmas is experimentally measured and analyzed indicating that the wave dynamics are not heavily influenced by the magnetic field. Only at the highest fields ($$B> 1$$ B > 1 T) the wave activity is found to be reduced. Moreover, it is discussed how dust-cyclotron waves might be used to indicate a magnetized dust component. Finally, implications of a magnetized dusty plasma are illustrated.

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Section: Rotationmentioning

confidence: 99%

Physics of magnetized dusty plasmas

Melzer¹,

Krüger²,

Maier³

et al. 2021

Rev. Mod. Plasma Phys.

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“…Figure 7 shows that both the positive and negative peaks become trapped, they neither propagate or dissolve by diffusion in the system over the time scale of the simulation. This behavior is the consequence of the well known scenario that diffusion can be strongly blocked by a magnetic field in strongly coupled plasmas [47,[68][69][70][71]. In the trapped state the particles undergo a cyclotron-type motion characterized by the strength of the magnetic field (β).…”

Section: B the Effect Of The Magnetic Fieldmentioning

confidence: 99%

Molecular dynamics investigation of soliton propagation in a two‐dimensional Yukawa liquid

Hartmann

Masheyeva

Dzhumagulova

2020

Contributions to Plasma Physics

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We investigate via Molecular Dynamics simulations the propagation of solitons in a twodimensional many-body system characterized by Yukawa interaction potential. The solitons are created in an equilibrated system by the application of electric field pulses. Such pulses generate pairs of solitons, which are characterized by a positive and negative density peak, respectively, and which propagate into opposite directions. At small perturbation, the features propagate with the longitudinal sound speed, form which an increasing deviation is found at higher density perturbations. An external magnetic field is found to block the propagation of the solitons, which can, however, be released upon the termination of the magnetic field and can propagate further into directions that depend on the time of trapping and the magnetic field strength.

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“…While air pressure induction discharges weren't identified until the 1940s, low-pressure electrodeless discharge experiments began around the end of the 19th century [1][2][3]. Ring releases, once established at low pressure, could be sustained when the pressure increased to atmospheric pressure, according to Babat's 1947 paper [4][5]. As far as we know, inductively linked plasma discharges may be maintained in open tubes with airflow [6][7].…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of magnetization induction coupled discharge plasma discharge process

Wang,

Ding

2023

Applied Mathematics and Nonlinear Sciences

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First, this paper analyzes the plasma discharge and fluid model, and constructs the plasma discharge model by drift-diffusion approximation control equation, heavy particle component control equation, electric field distribution and volume force calculation, and plasma chemical kinetic model. Next, the coupling mechanism of inductively coupled RF plasma and its discharge characteristics are analyzed. Finally, the magnetized inductively coupled plasma discharge is simulated numerically. The results demonstrate that the current flowing on an inductor coil develops quicker at 0.045T and then calms down with an increase in the supplied constant dynamic magnetic field power, but the coil voltage exhibits the reverse effect.

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The effect of magnetic field on plasma particles in dusty plasma

Cited by 16 publications

References 33 publications

Physics of magnetized dusty plasmas

Physics of magnetized dusty plasmas

Molecular dynamics investigation of soliton propagation in a two‐dimensional Yukawa liquid

Numerical simulation of magnetization induction coupled discharge plasma discharge process

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