Effect of voltage polarity on reaction mechanism of air atmospheric surface dielectric barrier discharge: A numerical study

This study establishes a two-dimensional fluid model of nanosecond surface dielectric barrier discharge (nSDBD) at atmospheric air to investigate the effects of positive and negative sinusoidal nanosecond pulsed voltages on the discharge characteristics. Key discharge parameters are studied, includi...

Full description

Saved in:
Bibliographic Details
Published in:Physics of plasmas 2025-01, Vol.32 (1)
Main Authors: Lai, Jiali, Wang, Chunjing, Li, Jing, Peng, Yi, Xu, Hancheng, Gao, Kaiyue, Chen, Chuanjie, Qian, Muyang, Dong, Bingyan, Wang, Dezhen
Format: Article
Language:English
Subjects:
Charge deposition
Charge distribution
Density distribution
Dielectric barrier discharge
Elastic waves
Electric discharges
Electric fields
Energy conversion efficiency
Energy distribution
Gas temperature
Nanosecond pulses
Pulse propagation
Reaction mechanisms
Streamer gas discharge
Surface charge
Thermal energy
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This study establishes a two-dimensional fluid model of nanosecond surface dielectric barrier discharge (nSDBD) at atmospheric air to investigate the effects of positive and negative sinusoidal nanosecond pulsed voltages on the discharge characteristics. Key discharge parameters are studied, including discharge current, distribution of major active particles, surface charge distribution on the dielectric, energy deposition density distribution, and gas temperature. The numerical simulation results indicate that the plasma streamers excited by positive and negative bipolar pulses exhibit markedly different discharge characteristics, with the discharge characteristics in the first half-cycle largely determining those of the entire cycle. Positive bipolar pulsed streamer discharges exhibit greater discharge currents and stronger local electric fields, with faster propagation speeds but also more pronounced declines. The energy deposition of positive bipolar pulse is higher than that of negative bipolar pulse. The discharges driven by negative bipolar pulses exhibit a more pronounced temperature rise effect, primarily due to their higher efficiency in converting electrical energy into thermal energy, leading to stronger localized thermal release. Consequently, the pressure waves generated by negative bipolar pulsed discharges are more intense. These numerical simulation data provide theoretical explanations and references for understanding and optimizing the physical mechanisms of nSDBD.
ISSN:1070-664X
1089-7674
DOI:10.1063/5.0238337