Analysis of gas discharge characteristics across micro-gap under different pressures

Li, Yansen; Sun, Yong; Sun, Yining; Wang, Linhua; Jia, Baohua; Chen, Yun

doi:10.35848/1347-4065/ac18ab

Cited by 6 publications

(1 citation statement)

References 30 publications

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“…where γ is set to 0.025 [26,27]. From this, the breakdown voltage (U b ) can be calculated according to Paschen's law.…”

Section: Discussion and Analysismentioning

confidence: 99%

The effect of micro-gap discharge paths on ionization coefficients and similarity theory

Zhang,

Zhao,

Wang

et al. 2024

Phys. Scr.

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In order to investigate the impact of discharge paths at the micrometer scale on breakdown, two sets of different electrodes were arranged with electrode gaps ranging from 10μm to 100μm and gas pressures varying from 1kPa to 100kPa. The research has revealed that without an insulating layer at the edge of the electrode, when the product of gas pressure (p) and electrode gap (d) is less than 60Pa·cm, the number of positive ions cannot satisfy the conditions for self-sustaining discharge at the electrode gap (d). As a result, the discharge path varies along a longer path (s) to satisfy the conditions for self-sustained discharge, thereby maintaining the minimum breakdown voltage. This long-path discharge mechanism affects the ionization coefficient, resulting in an inconsistency between the ionization coefficient ratio at different distances and their respective scale factor (k) values. Therefore, on a micrometer scale, changes in the path make the application of similarity theory no longer applicable.

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“…where γ is set to 0.025 [26,27]. From this, the breakdown voltage (U b ) can be calculated according to Paschen's law.…”

Section: Discussion and Analysismentioning

confidence: 99%

The effect of micro-gap discharge paths on ionization coefficients and similarity theory

Zhang,

Zhao,

Wang

et al. 2024

Phys. Scr.

Self Cite

View full text Add to dashboard Cite

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Experimental recurrence of an unreported fire risk of power cable: Discharge of bracket cable metallic grounding under coupled vibration conditions

Huang,

Liu,

et al. 2025

Electric Power Systems Research

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Experimental study of gas breakdown and electron emission in nanoscale gaps at atmospheric pressure

Wang

Brayfield

Loveless

et al. 2022

Applied Physics Letters

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While experiment, simulation, and theory all show that the gas breakdown voltage decreases linearly with gap distance for microscale gaps at atmospheric pressure due to the contribution of field emitted electrons, the continuing reduction in device size motivates a more fundamental understanding of gas breakdown scaling for nanoscale gaps. In this study, we measure current–voltage curves for electrodes with different emitter widths for 20–800 nm gaps at atmospheric pressure to measure breakdown voltage and assess electron emission behavior. The breakdown voltage [Formula: see text] depends more strongly on effective gap distance [Formula: see text] than the ratio of the emitter width to the gap distance. For 20 and 800 nm gaps, we measure [Formula: see text] V and [Formula: see text] V. Independent of emitter width, [Formula: see text] decreases linearly with decreasing [Formula: see text] for [Formula: see text] nm; for [Formula: see text] nm, [Formula: see text] decreases less rapidly with decreasing [Formula: see text] which may correspond to a change in the field enhancement factor for smaller gaps. While gas breakdown usually proceeds directly from field emission, as for microscale gaps, some cases exhibit space-charge contribution prior to the transition to breakdown, as demonstrated by orthodoxy tests. Applying nexus theory, we determine that the range of [Formula: see text] studied is close to the transitions between field emission and space-charge-limited current in vacuum and with collisions, necessitating a coupled theoretical solution to more precisely model the electron emission behavior. Implications on device design and an overall assessment of the dependence of emission and breakdown on gap distance are also discussed.

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Analysis of gas discharge characteristics across micro-gap under different pressures

Cited by 6 publications

References 30 publications

The effect of micro-gap discharge paths on ionization coefficients and similarity theory

The effect of micro-gap discharge paths on ionization coefficients and similarity theory

Experimental recurrence of an unreported fire risk of power cable: Discharge of bracket cable metallic grounding under coupled vibration conditions

Experimental study of gas breakdown and electron emission in nanoscale gaps at atmospheric pressure

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