Fine structure of streamer-to-filament transition in high-pressure nanosecond surface dielectric barrier discharge

The fine structure of a streamer-to-filament transition in a single-shot high-voltage nanosecond surface dielectric barrier discharge in molecular nitrogen at pressure P = 6 bar was studied with the help of ICCD microimaging. An intermediate discharge structure, existing for only a few nanoseconds, was observed in the time interval between two discharge modes: streamer discharge, with a typical electron density of n (e) similar to 10(15) cm(-3), and filamentary discharge, with n (e) similar to 10(19) cm(-3). The structure was observed for both polarities of the high-voltage electrode. The structure can be briefly described as a stochastic appearance of thin channels propagating a bit faster than the main ionization front of merged surface streamers, transforming in a few nanoseconds in a bi-directional ionization wave. One wave, which we associate with a feather-like structure in optical emission, propagates further away from the high-voltage electrode, and another, a backward wave of emission, propagates back towards the edge of the high-voltage electrode. When the backward wave of emission almost reaches the high-voltage electrode, the filament appears. Plasma properties of the observed structure were studied to better understand the nature of a streamer-to-filament transition. Theoretical analysis suggests that the instability of a flat front of ionization wave (Laplacian instability) triggers the streamer-to-filament transition, and that a surface stem (a tiny region with enhanced electron density) should be in the origin of the bi-directional ionization wave.

Automated summary

The fine structure of a streamer-to-filament transition in a high-voltage nanosecond surface dielectric barrier discharge in molecular nitrogen at pressure P = 6 bar was investigated using ICCD microimaging. An intermediate discharge structure, existing for only a few nanoseconds, was observed between two discharge modes: streamer discharge and filamentary discharge. The structure consists of thin channels propagating faster than the main ionization front and transforms into a bi-directional ionization wave. The study provides important insights into the nature of the streamer-to-filament transition.