Dust particles of finite dimensions in complex plasmas: thermodynamics and dust-acoustic wave dispersion

Davletov, A. E.; Yerimbetova, L. T.; Arkhipov, Yu. V.; Mukhametkarimov, Ye. S.; Kissan, A.; Ткаченко, І. М.

doi:10.1017/s0022377818000879

Cited by 11 publications

(5 citation statements)

References 72 publications

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“…It is due to the fact that the particles levitate in the sheath of the bottom electrode in a parallel plate configuration having small plasma volume. The size of the crystal, with a smaller number of particles (a few tens to few hundreds) is good enough to study the dynamics of particles at an individual level [24]. However, for exploring the thermodynamics of Coulomb crystal, the number of dust particles has to be as large as possible to minimize the error associated with the statistical fluctuation (∝ 1 √ N , where N is the number of particles) [25].…”

Section: Introductionmentioning

confidence: 99%

DPEx-II: a new dusty plasma device capable of producing large sized DC coulomb crystals

Arumugam¹,

Bandyopadhyay²,

Singh³

et al. 2021

Plasma Sources Sci. Technol.

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The creation of a spatially extended stable DC complex plasma crystal is a big experimental challenge and a topical area of research in the field of dusty plasmas. In this paper we describe a newly built and commissioned dusty plasma experimental (DPEx-II) device at the Institute for Plasma Research. The device can support the formation of large sized Coulomb crystals in a DC glow discharge plasma. The plasma in this L-shaped table-top glass chamber is produced between a circular anode and a long tray shaped cathode. It is characterized with the help of various electrostatic probes over a range of discharge conditions. The dust particles are introduced by a dust dispenser to form a strongly coupled Coulomb crystal in the cathode sheath region. The unique asymmetric electrode configuration minimizes the heating of dust particles and facilitates the formation of crystalline structures with a maximum achievable dimension of 40 cm × 15 cm using this device. A larger crystal has numerous advantages over smaller ones, such as higher structural homogeneity, fewer defects, lower statistical errors due to finite size effects etc. A host of diagnostics tools are provided to characterize the Coulomb crystal. Results of a few initial experiments aimed at demonstrating the technical capabilities of the device and its potential for future dusty plasma research, are reported.

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Section: Introductionmentioning

confidence: 99%

DPEx-II: a new dusty plasma device capable of producing large sized DC coulomb crystals

Arumugam¹,

Bandyopadhyay²,

Singh³

et al. 2021

Plasma Sources Sci. Technol.

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“…2009; Williams & Snipes 2010; Ruhunusiri & Goree 2014; Avinash 2015; Davletov et al. 2018) of this wave mode, wave breaking (Liao et al. 2008; Teng et al.…”

Section: Introductionmentioning

confidence: 99%

“…This allows for the study of the properties of the dust-related phenomena such as the dust acoustic wave mode at both the global and individual particle level with incredible spatial and temporal resolution (Killer & Melzer 2014;Tadsen et al 2015;Tadsen, Greiner & Piel 2017;Yaroshenko et al 2019). In recent years, this has allowed for the study of a wide range of the properties this wave mode, including wave-particle interactions (Liao et al 2008;Chang, Teng & Lin 2012), the growth (Thomas 2006;Flanagan & Goree 2011;Heinrich et al 2011;Williams 2013) and dispersion relation (Trottenberg, Block & Piel 2006;Thomas, Fisher & Merlino 2007;Rosenberg, Thomas & Merlino 2008;Nosenko et al 2009;Williams & Snipes 2010;Ruhunusiri & Goree 2014;Avinash 2015;Davletov et al 2018) of this wave mode, wave breaking (Liao et al 2008;Teng et al 2009) and turbulence (Tsai, Chang & Lin 2014). Further, the majority of the experimental observations that have been made of this wave mode in the laboratory setting involve waves that are nonlinear (Merlino 2012).…”

Section: Introductionmentioning

confidence: 99%

Volumetric measurement of the synchronization and desynchronization of the dust acoustic wave with an external modulation

Williams

2019

J. Plasma Phys.

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A spatio-temporal measurement showing the volumetric nature of the phase synchronization of a naturally occurring dust acoustic wave to an external modulation and the relaxation from the driven wave mode back to the naturally occurring wave mode (phase desynchronization) is presented. It is shown that the phase synchronization and desynchronization occur behind a propagating synchronization/desynchronization front that travels at a slower speed than the phase velocity of the wave and that the speed of this synchronization/desynchronization front decreases with increasing neutral gas pressure. It is also observed that volume of the wave that is synchronous depends on the frequency of the external modulation and the neutral gas pressure.

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“…First of all, it is evident that in a strongly coupled dusty plasma the electrostatic force between dust particles dominates in comparison with other contributions to interaction, such as the ion drag force, etc. The other reason is that the dust component should only slightly affect the ionization equilibrium in the surrounding plasma, otherwise it is necessary to take into account the charge variation of dust particles by incorporating into consideration the electron and ion dynamics . In the present research, those assumptions are presumed to be simultaneously fulfilled in order to focus all attention on the influence the finiteness of dust particles dimensions has on their collective dynamic properties, which particularly include the dynamic structure factor and the spectrum of dust‐acoustic waves.…”

Section: Introductionmentioning

confidence: 99%

Dynamic properties of strongly coupled dusty plasmas with particles of finite dimensions

Yerimbetova

Davletov

Arkhipov

et al. 2019

Contributions to Plasma Physics

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The aim of the present study is to determine the impact the finite size of dust particles has on the static and dynamic characteristics of the dust component of a plasma.Taking into account both the finite dimensions of dust grains and the plasma screening, a model expression is chosen for the interdust interaction potential. The static structure factor of dust particles is evaluated by iteratively solving the reference hypernetted-chain approximation, which inherently contains the hard sphere model handled within the Percus-Yevick closure. The self-consistent method of moments is then engaged to relate the static and dynamic structure factors by assuming that the second derivative of the dynamic structure factor with respect to the frequency vanishes at the origin. Thus, an analytical expression for the dynamic structure factor is validated over quite a broad domain of dusty plasma non-ideality and grains packing fraction. The calculated spectrum of dust-acoustic waves reveals the appearance of the roton minimum, which becomes less pronounced when the packing fraction of dust particles rises. It is also predicted that the wavenumber position of the roton minimum is de facto independent of the size of dust particles. New analytical expressions for the dust-acoustic wave spectrum and decrement of damping are proposed and thoroughly checked. K E Y W O R D Sdust-acoustic waves, dusty plasmas, dynamic structure factor, method of moments

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Dust particles of finite dimensions in complex plasmas: thermodynamics and dust-acoustic wave dispersion

Cited by 11 publications

References 72 publications

DPEx-II: a new dusty plasma device capable of producing large sized DC coulomb crystals

DPEx-II: a new dusty plasma device capable of producing large sized DC coulomb crystals

Volumetric measurement of the synchronization and desynchronization of the dust acoustic wave with an external modulation

Dynamic properties of strongly coupled dusty plasmas with particles of finite dimensions

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