Litcius/Paper detail

Three-electrode surface dielectric barrier discharge driven by repetitive pulses: streamer dynamic evolution and discharge mode transition

Bangfa Peng, Nan Jiang, Yifei Zhu, Jie Li, Yan Wu

2024Plasma Sources Science and Technology16 citationsDOIOpen Access PDF

Abstract

Abstract The streamer dynamic evolution and discharge mode transition of a three-electrode surface dielectric barrier discharge (SDBD) driven by repetitive pulses are studied experimentally and numerically for better plasma-mode control and optimized application. Spatial-temporal plasma morphologic features together with electro-optical behavior are utilized to analyze the streamer dynamic evolution and streamer-to-spark transition. To gain a deep insight into the physical mechanism of the discharge mode transition in repetitive pulses, a 2D fluid model combined with a 0D kinetic model is built and studied. A good agreement between the experimental measurements and numerical simulation in the propagation dynamics and voltage–current characteristics is achieved. The results show that the surface-streamer discharge in the form of primary and transitional streamers can transform into a surface-spark discharge characterized by the primary streamer, transitional streamer and spark phase in repetitive pulses under the high applied electric field. A high gas temperature will result in a large reduced electric field after the transitional streamer, which exceeds the ionization threshold and thus promotes the discharge mode transition. A high number of electrons can be released from the negative charges by oxygen atoms during the inter-pulse period, which is favorable for the re-ignition and ionization process of the subsequent pulse discharge.

Topics & Concepts

Dielectric barrier dischargeElectrodeMaterials scienceMode (computer interface)Streamer dischargeDielectricOptoelectronicsChemistryComputer scienceOperating systemPhysical chemistryPlasma Applications and DiagnosticsPlasma Diagnostics and ApplicationsDiamond and Carbon-based Materials Research