What does this research mean for the field?

Optimizing key design parameters, material properties, and pulse source interactions in pulsed dielectric barrier discharges is essential for maximizing their efficiency and industrial applicability in low-temperature plasma production. Novelty: ClaimNovelty.SYNTHESIS. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This review examines the design parameters important for generating low-temperature atmospheric plasma using pulsed dielectric barrier discharges.

May 16, 2026Open Access

Design Considerations for Low-Temperature Plasma Production in Air Using Pulsed Dielectric Barrier Discharges: A Review

Key Points

This review examines the design parameters important for generating low-temperature atmospheric plasma using pulsed dielectric barrier discharges.
Analyzed key design parameters of dielectric barrier discharges including barrier thickness, relative permittivity, and gap distance.
Discussed material phenomena like surface charging and degradation in low-temperature plasma systems.
Explored the interactions between pulsed power sources and dielectric barrier discharge mechanisms.
Identified optimal design parameters that enhance efficiency and reliability of low-temperature plasma production.
Discussed benefits of pulsed excitation over conventional AC methods, including reduced energy usage.
Mapped the interdependencies of design factors to aid in the optimization of pulsed dielectric barrier discharge systems.

Abstract

Low-temperature atmospheric plasma (LTP) is widely used in industrial processes, such as disinfection, surface modification and wastewater treatment. The dielectric barrier discharge (DBD) is regarded as one of the most robust and reliable methods for generating LTP in ambient air. Compared to conventional AC excitation, pulsed powering offers several advantages (i.e., lower energy use and heat production). The present trend is to use short and fast pulses (in the nano- and picosecond range). In this review, the key design parameters of a DBD (barrier thickness, relative permittivity and gap distance) are discussed. Material-specific phenomena like surface charging and degradation are analyzed. The complex interactions between the pulse source and DBD are examined. By mapping the interdependencies, this review aims to support the rational design and optimization of pulsed DBD systems, and to facilitate their broader industrial use.

Design Considerations for Low-Temperature Plasma Production in Air Using Pulsed Dielectric Barrier Discharges: A Review

Key Points

Abstract

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