The effect of non-perpendicular incidence angles on discharge characteristics in an argon atmospheric plasma jet impinging on metal, water and glass substrates
The effect of non-perpendicular incidence angles on discharge characteristics in an argon atmospheric plasma jet impinging on metal, water and glass substrates
The spatial-temporal discharge behavior of an AC argon plasma jet tilted at non-perpendicular incidence angles (60°, 45°, and 30°) interacting with an ungrounded metal, water, and glass plate placed on the jet propagation track was studied by the fast-imaging technique. The conductivity of surface and incidence angles plays an essential role in the discharge current and dynamic process of the plasma jet. The nearly consistent time delay between subsequent breakdowns occurred four times for metal and two times for glass treatments. The mean luminous intensity of the plasma in one discharge cycle at the discharge area between ground electrode and target surface region for the water and glass case decreased by 39.5% and 20.5% when the incidence angle decreased from 60° to 30°, respectively. In particular, the incidence angle and gas flow rate notably impacted the spatial extension behavior created on the glass surface but had no significant difference in discharge characteristic of plasma jet with metal case. In addition, two equivalent circuit models were developed based on the simulation of the micro-discharges and the geometry of the “plasma jet-substrate” system, respectively. These results will obtain further insight into the underlying mechanisms of plasma-target interaction and facilitate the designing of appropriate jet for environmental and biomedical applications.
Li, Jiayin
75ee58ab-7c1b-40e6-bbc9-c9dfb6fa529a
Kim, Minkwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
Li, Jiayin
75ee58ab-7c1b-40e6-bbc9-c9dfb6fa529a
Kim, Minkwan
18ed9a6f-484f-4a7c-bf24-b630938c1acc
Li, Jiayin and Kim, Minkwan
(2024)
The effect of non-perpendicular incidence angles on discharge characteristics in an argon atmospheric plasma jet impinging on metal, water and glass substrates.
Physics of Plasmas, 31 (10), [103507].
(doi:10.1063/5.0214063).
Abstract
The spatial-temporal discharge behavior of an AC argon plasma jet tilted at non-perpendicular incidence angles (60°, 45°, and 30°) interacting with an ungrounded metal, water, and glass plate placed on the jet propagation track was studied by the fast-imaging technique. The conductivity of surface and incidence angles plays an essential role in the discharge current and dynamic process of the plasma jet. The nearly consistent time delay between subsequent breakdowns occurred four times for metal and two times for glass treatments. The mean luminous intensity of the plasma in one discharge cycle at the discharge area between ground electrode and target surface region for the water and glass case decreased by 39.5% and 20.5% when the incidence angle decreased from 60° to 30°, respectively. In particular, the incidence angle and gas flow rate notably impacted the spatial extension behavior created on the glass surface but had no significant difference in discharge characteristic of plasma jet with metal case. In addition, two equivalent circuit models were developed based on the simulation of the micro-discharges and the geometry of the “plasma jet-substrate” system, respectively. These results will obtain further insight into the underlying mechanisms of plasma-target interaction and facilitate the designing of appropriate jet for environmental and biomedical applications.
Text
103507_1_5.0214063
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Accepted/In Press date: 9 September 2024
e-pub ahead of print date: 8 October 2024
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Local EPrints ID: 499230
URI: http://eprints.soton.ac.uk/id/eprint/499230
ISSN: 1070-664X
PURE UUID: 176d0ba1-a37f-4443-a8d9-cbbf9f680ced
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Date deposited: 12 Mar 2025 17:42
Last modified: 22 Aug 2025 02:09
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Author:
Jiayin Li
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