Breakdown of Argon and Nitrogen inside a Microgap Driven at High Frequency
POSTER
Abstract
The high-frequency oscillation of free electrons in a microgap (gap size< 1mm) leads to gas breakdown when the driving electric field exceeds a threshold, Ebd. In these experiments, with microwave signals introduced into a re-entrant microwave resonator, Ebd for argon and nitrogen was measured over a wide range of pressures and microgap sizes. As gas pressure is reduced below atmospheric, two distinct gap size dependent behavioral pressure regimes are observed where plasma transitions from uniform breakdown within the gap at higher pressure, to a glow discharge outside of the gap at lower pressure. The transition between these two regimes predictably occurs when the size of the microgap exceeds the dimension where microgap boundary loss of the oscillating electrons can be expected, resulting in a simple power law relationship between the transition pressure and the microgap size.
*This material is based upon work supported by the U.S. Department of Energy, Office of Science, Office of Fusion Energy Sciences Award Nr. DE-SC0019062 and the L.T. Guess Physics Summer Research Fund.
Publication:J.D. Campbell, A. Bowman III, G.T. Lenters, and S.K. Remillard, "Collision and diffusion in microwave breakdown of N2 gas in and around microgaps," AIP Advances, 4, 017119, (2014).
T.J. Klein, Cameron J. Recknagel, Christopher J. Ploch, and S.K. Remillard, "Microwave Breakdown of Low Pressure N2 Gas in Microgaps," Applied Physics Letters, 99, no.12, 121503, (2011).
S. K. Remillard, A. Hardaway, B. Mork, J. Gilliland, and J. Gibbs, "Using a re-entrant microwave resonator to measure and model the dielectric breakdown electric field of gases," Progress In Electromagnetics Research, B15, pp. 175-195, (2009).
