Optical diagnosis of a kHz-driven helium atmospheric pressure plasma jet

McDonnell, Cíara; Irwin, R.; White, S.; Graham, W. G.; Riley, D.

doi:10.1017/s0022377822000538

Cited by 3 publications

(1 citation statement)

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“…To date, atmospheric-pressure glow discharges have mostly been obtained using DC [42][43][44], low-(kHz) [45][46][47] and rf-frequency sources [48][49][50][51]. In the present work, we used a discharge gap of sphere-to-plane geometry to obtain and study an interelectrode microwave discharge in Ar flow, representing a new type of glow discharge at atmospheric pressure.…”

Section: Introductionmentioning

confidence: 99%

Interelectrode microwave glow discharge in atmospheric-pressure argon flow

Antipov¹,

Gadzhiev²,

Sargsyan³

et al. 2023

Phys. Scr.

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The spatio-temporal structure and plasma parameters of a new type of glow discharge – atmospheric-pressure interelectrode microwave discharge in gas flow – were studied experimentally and numerically. A multi-electrode coaxial-type cold plasma torch developed for large-area surface treatment was used as a gas discharge device. The torch was supplied with microwave power (2.45 GHz, ∼100 W) via a coaxial cable by a typical wave-guide plasmatron. Self-sustained glow discharges were excited between the round ends of the rod-like electrodes and inner wall of the cylindrical discharge chamber near the outlet. The filamentation of the discharge channel in the near-electrode regions was detected by high-speed video filming. The dendritic self-similar (fractal) character of the filaments’ structure was revealed and analyzed. The branching factor and fractal dimension of this structure were estimated as 3 and 1.1–1.3, respectively. Using discharge gas temperature T_g = 1200±100 K, as determined from the emission spectroscopy measurements, the following discharge plasma parameters were obtained from numerical calculations: electron temperature T_e = 1.14 eV and concentration n_e∼10^21-10^22 m^(-3), conductivity σ ∼ 400 Ω^(-1)m^(-1) , current density j ∼ 10^6 A/m^2, and electric field strength E ∼ 10^4 V/m.

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Section: Introductionmentioning

confidence: 99%

Interelectrode microwave glow discharge in atmospheric-pressure argon flow

Antipov¹,

Gadzhiev²,

Sargsyan³

et al. 2023

Phys. Scr.

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Enhanced plasma jet generation through numerical integration and dielectric influence analysis

Ouali,

Lagmich

2024

AIP Advances

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This paper reports a study on the production of plasma jets that are out of equilibrium through numerical solutions of electron energy distribution function using a self-consistent methodology. The approach includes the integration of the continuity, momentum, and Poisson equations, which allows the use of the mean electron energy to fit the transport and source coefficients. The paper concurrently presents an analysis of cold plasma generation in a tube. This investigation utilizes COMSOL Multiphysics software to simulate the electric field, potential, and electron density in space. Moreover, the study examines how the dielectric’s permittivity impacts plasma propagation. The simulated outcomes are compared with experimental and numerical results. As electron density, ionization rate and electric potential vary during plasma propagation on a dielectric surface, and the permittivity of dielectric materials increases, it promotes an increase in electron density around it. This, in turn, accelerates the ionization front, indicating efficient polarization and accumulation of electric charges, specifically electrons, near the dielectric surface.

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