Generation of cold atmospheric plasma jet by a coaxial double dielectric barrier reactor

Nguyen, Duc Ba; Trinh, Quang Hung; Mok, Young Sun; Lee, Won Gyu

doi:10.1088/1361-6595/ab6ebd

Cited by 15 publications

(18 citation statements)

References 52 publications

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“…Such APPJ present double dielectric barriers as sketched in the (a) configuration where two outer rings surround a dielectric capillary, in the (b) configuration where a pin electrode is embedded in a dielectric material or in the (c) configuration where the polarized electrode and the counter-electrode are wounded around a tube following a double helix structure. Such dielectric-embedded electrodes are particularly relevant for processing liquids or corrosive gases [11]. The second category corresponds to the APPJ's with single-dielectric barrier so that plasma is in contact with only one electrode.…”

Section: I3 Appj Configurationsmentioning

confidence: 99%

Transmission and multiple reflection mechanisms of guided streamers propagating through grounded annular electrode and interacting with grounded surface electrode

Decauchy

Dufour

2022

Plasma Sources Sci. Technol.

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The repeatable dynamics and the reversal propagation of guided streamers remains a major question of fundamental physics. In this article, trains of positive guided streamers are generated within an atmospheric pressure plasma jet supplied in helium and polarized by a high-voltage nanosecond pulse generator. The device is completed by two distant targets: a grounded annular electrode coaxially centered around the capillary through which guided streamers can propagate and a grounded surface electrode on which they can interact. The resulting transmitted and multiple reflected guided streamers are measured combining optical characterization (fast ICCD imaging) and electrical characterization (high voltage probe and current monitors). While the electrical approach provides information on the capacitive/conductive nature of the current peaks as well as on their positive/negative value, fast ICCD imaging distinguishes whether the guided streamers are incident, reflected or transmitted. Combining these two techniques allow us to demonstrate experimentally that the reflected streamers are negative contrarily to the others. Besides, 4 types of reflections have been highlighted: a reflection (r) at the outlet of the capillary, a reflection on the grounded surface electrode (R) and two reflections (r’ and r”) observed when an incident guided streamer passes through the grounded annular electrode. The two techniques agree that the characteristic propagation times are always shorter for reflected negative streamers than for the positive ones propagating forward. Hence, for a grounded annular electrode placed 3 cm away from the high voltage electrode, propagation time is 80 ns for reflection versus 250 ns for transmission. These characteristic propagation times are even shorter when the annular electrode is brought closer to the surface electrode with velocities typically higher than 300 km/s. In addition, the intensity ratios of reflected/incident guided currents drop sharply, typically losing one decade over a counter-propagation length of only 3-5 cm. Finally, all these experimental data are utilized to build an equivalent electrical model that allow to better understand the dynamics of the guided streamers and explain their transmission and reflection modes upon their interaction with the two distant grounded electrodes.

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Section: I3 Appj Configurationsmentioning

confidence: 99%

Transmission and multiple reflection mechanisms of guided streamers propagating through grounded annular electrode and interacting with grounded surface electrode

Decauchy

Dufour

2022

Plasma Sources Sci. Technol.

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“…In general, APPJs have a simple structure consisting of a gas-feeding tube and electrodes. To prevent the unwanted transition of glow to arc discharge, a dielectric barrier that can easily control the current during discharge is commonly used, thus resulting in AC discharge [ 19 , 20 , 21 , 22 , 23 ]. When generating a DC discharge, it is common to expose the powered electrode to the discharge space, include a proper ballast resistor in the circuit to control the current, and ground the counter electrode [ 24 , 25 , 26 , 27 , 28 , 29 , 30 , 31 ].…”

Section: Resultsmentioning

confidence: 99%

Transparent Polyaniline Thin Film Synthesized Using a Low-Voltage-Driven Atmospheric Pressure Plasma Reactor

et al. 2021

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The use of low-voltage-driven plasma in atmospheric pressure (AP) plasma polymerization is considered as a simple approach to reducing the reactivity of the monomer fragments in order to prevent excessive cross-linking, which would have a negative effect on the structural properties of the polymerized thin films. In this study, AP-plasma polymerization can be processed at low voltage by an AP-plasma reactor with a wire electrode configuration. A bare tungsten wire is used as a powered electrode to initiate discharge in the plasma area (defined as the area between the wide glass tube and the substrate stand), thus allowing plasma polymerization to proceed at a lower voltage compared to other AP-plasma reactors with dielectric barriers. Thus, transparent polyaniline (PANI) films are successfully synthesized. The surface morphology, roughness, and film thickness of the PANI films are characterized by field emission scanning electron microscopy and atomic force microscopy. Thus, the surface of the polymerized film is shown to be homogenous, smooth, and flat, with a low surface roughness of 1 nm. In addition, the structure and chemical properties of the PANI films are investigated by Fourier transform infrared spectroscopy, thus revealing an improvement in the degree of polymerization, even though the process was performed at low voltage.

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“…R15 [42] excitations R1-R4, see table 1), and He * are produced by electron impacted excitations (R5) [15,17,39]. While the excited state N 2 + (B) with 18.7 eV excitation energy, can be produced by the Penning ionization process between metastable He * (19.8 ∼ 23.7 eV) and molecule N 2 (R6) [40,41].…”

Section: Effect Of Adding Extra Shielding On the Oes Of Gaseous React...mentioning

confidence: 99%

“…Recently, one method has proposed that using shielding gas flow to limit air diffusion into the discharge region, and help to stabilize and control plasma propagation as well as reactive species production [12][13][14][15]. For example, Yatom et al combined experimental and computational investigations to conclude that shielding Ar gas in the discharge configuration decrease the air diffusion into the discharge region, which can significantly increase electron density and the ionization of water in wet gas discharge [13].…”

Section: Introductionmentioning

confidence: 99%

The influences of shielding gas and quartz tube on discharge properties and reactive species productions of nanosecond pulsed gas–liquid discharge

Liang¹,

Zhao²,

Zhou³

et al. 2022

J. Phys. D: Appl. Phys.

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In this paper, shielding gas (He) and shielding quartz tube (straight tube and conical tube) is added to nanosecond pulsed He gas-liquid discharge for the purposes of enhancing the plasma volume and productions of •OH and H2O2. The plasma properties, including current-voltage waveforms, the temporal-resolved discharge images, optical emission spectra, gas temperature, electron density, and the •OH and H2O2 productions are analyzed and compared among different discharges generated under the cases of no shielding, shielding He gas, shielding straight tube, and shielding conical tube. The results show that adding shielding gas and tubes in the discharge reactor can decrease the gas temperature and electron density, but enhance the plasma volume and area of plasma-liquid interface in comparison with no shielding case. In comparison, the addition of shielding gas has the most benefit for enhancing the concentrations of •OH and H2O2 produced by gas-liquid discharge. Adding a shielding conical tube slows down the decrease extent of •OH and H2O2 productions caused by increasing discharge gap. When the discharge gasp excesses 6 mm, adding a shielding conical quartz also has an obvious enhanced effect on the production of •OH and H2O2 in compared with no shielding case. While adding a shielding straight tube with small diameter has a little effect on H2O2 production, even a negative effect on •OH production.

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Generation of cold atmospheric plasma jet by a coaxial double dielectric barrier reactor

Cited by 15 publications

References 52 publications

Transmission and multiple reflection mechanisms of guided streamers propagating through grounded annular electrode and interacting with grounded surface electrode

Transmission and multiple reflection mechanisms of guided streamers propagating through grounded annular electrode and interacting with grounded surface electrode

Transparent Polyaniline Thin Film Synthesized Using a Low-Voltage-Driven Atmospheric Pressure Plasma Reactor

The influences of shielding gas and quartz tube on discharge properties and reactive species productions of nanosecond pulsed gas–liquid discharge

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