Reduced breakdown voltage for in-liquid plasma discharges using moveable electrodes

Rusen Zhou; Baowang Liu; Yiyang Li; Renwu Zhou; Wenshao Li; Jungmi Hong; Tianqi Zhang; Dejiang Zhou; Yubin Xian; Patrick J. Cullen; Xinpei Lu; Kostya Ostrikov

doi:10.1088/1361-6463/ac3d5d

Reduced breakdown voltage for in-liquid plasma discharges using moveable electrodes

Rusen Zhou, Baowang Liu, Yiyang Li, Renwu Zhou, Wenshao Li, Jungmi Hong, Tianqi Zhang, Dejiang Zhou, Yubin Xian, Patrick J. Cullen, Xinpei Lu, Kostya Ostrikov

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

Minimizing the breakdown voltage and discharge current required to initiate direct in-liquid discharges, thus lowering power-source requirements and avoiding electrode ablation, is crucial for industrial applications of in-liquid plasmas. Here we demonstrate such considerable reductions by employing movable electrodes, without changing the electrode configuration or increasing the system complexity. The new mechanism is based on electrostatic electrode attraction resulting in a reduction in the discharge spacing by up to 6 times and facilitating a plasma initiation at lower breakdown voltages. The accumulated charges consumed by the discharge revert the electrodes to the initial positions, forming a gliding arc between the enlarged gaps and thus inhibiting current increases and electrode ablation.

Original language	English
Article number	10LT01
Number of pages	7
Journal	Journal of Physics D: Applied Physics
Volume	55
Issue number	10
DOIs	https://doi.org/10.1088/1361-6463/ac3d5d
Publication status	Published - 10 Mar 2022
Externally published	Yes

Keywords

breakdown voltage
discharge gap
in-liquid plasma discharges
moveable electrodes

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10.1088/1361-6463/ac3d5dLicence: In Copyright

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title = "Reduced breakdown voltage for in-liquid plasma discharges using moveable electrodes",

abstract = "Minimizing the breakdown voltage and discharge current required to initiate direct in-liquid discharges, thus lowering power-source requirements and avoiding electrode ablation, is crucial for industrial applications of in-liquid plasmas. Here we demonstrate such considerable reductions by employing movable electrodes, without changing the electrode configuration or increasing the system complexity. The new mechanism is based on electrostatic electrode attraction resulting in a reduction in the discharge spacing by up to 6 times and facilitating a plasma initiation at lower breakdown voltages. The accumulated charges consumed by the discharge revert the electrodes to the initial positions, forming a gliding arc between the enlarged gaps and thus inhibiting current increases and electrode ablation.",

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author = "Rusen Zhou and Baowang Liu and Yiyang Li and Renwu Zhou and Wenshao Li and Jungmi Hong and Tianqi Zhang and Dejiang Zhou and Yubin Xian and Cullen, {Patrick J.} and Xinpei Lu and Kostya Ostrikov",

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T1 - Reduced breakdown voltage for in-liquid plasma discharges using moveable electrodes

AU - Zhou, Rusen

AU - Liu, Baowang

AU - Li, Yiyang

AU - Zhou, Renwu

AU - Li, Wenshao

AU - Hong, Jungmi

AU - Zhang, Tianqi

AU - Zhou, Dejiang

AU - Xian, Yubin

AU - Cullen, Patrick J.

AU - Lu, Xinpei

AU - Ostrikov, Kostya

PY - 2022/3/10

Y1 - 2022/3/10

N2 - Minimizing the breakdown voltage and discharge current required to initiate direct in-liquid discharges, thus lowering power-source requirements and avoiding electrode ablation, is crucial for industrial applications of in-liquid plasmas. Here we demonstrate such considerable reductions by employing movable electrodes, without changing the electrode configuration or increasing the system complexity. The new mechanism is based on electrostatic electrode attraction resulting in a reduction in the discharge spacing by up to 6 times and facilitating a plasma initiation at lower breakdown voltages. The accumulated charges consumed by the discharge revert the electrodes to the initial positions, forming a gliding arc between the enlarged gaps and thus inhibiting current increases and electrode ablation.

AB - Minimizing the breakdown voltage and discharge current required to initiate direct in-liquid discharges, thus lowering power-source requirements and avoiding electrode ablation, is crucial for industrial applications of in-liquid plasmas. Here we demonstrate such considerable reductions by employing movable electrodes, without changing the electrode configuration or increasing the system complexity. The new mechanism is based on electrostatic electrode attraction resulting in a reduction in the discharge spacing by up to 6 times and facilitating a plasma initiation at lower breakdown voltages. The accumulated charges consumed by the discharge revert the electrodes to the initial positions, forming a gliding arc between the enlarged gaps and thus inhibiting current increases and electrode ablation.

KW - breakdown voltage

KW - discharge gap

KW - in-liquid plasma discharges

KW - moveable electrodes

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U2 - 10.1088/1361-6463/ac3d5d

DO - 10.1088/1361-6463/ac3d5d

M3 - Article

AN - SCOPUS:85122628684

SN - 0022-3727

VL - 55

JO - Journal of Physics D: Applied Physics

JF - Journal of Physics D: Applied Physics

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M1 - 10LT01

ER -

Reduced breakdown voltage for in-liquid plasma discharges using moveable electrodes

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Keywords

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