This article is cited in 11 papers

PLASMA, HYDRO- AND GAS DYNAMICS

Discharge in the atmosphere in a Gaussian beam of subthreshold millimeter waves

K. V. Artem'ev^a, G. M. Batanov^a, N. K. Berezhetskaya^a, V. D. Borzosekov^ab, L. V. Kolik^a, E. M. Konchekov^ab, I. A. Kossyi^a, D. V. Malakhov^abc, A. E. Petrov^ab, K. A. Sarksyan^a, V. D. Stepakhin^ab, N. K. Kharchev<sup>a

a</sup> Prokhorov General Physics Institute, Russian Academy of Sciences, Moscow, Russia
^b Pirogov Russian National Research Medical University, Moscow, Russia
^c Moscow Technological University (MIREA), Moscow, Russia

Abstract: The propagation velocities of a subthreshold discharge excited in air at atmospheric pressure by a pulsed microwave beam with a Gaussian field distribution, a wavelength of $4$ mm, and an intensity up to $30$ kW/cm$^2$ have been measured by means of optical and microwave diagnostics. It has been shown that the motion of a discharge front along the path of the beam toward the region of an increasing microwave field is accompanied by an increase in the velocity from subsonic (${\sim}\,10^4\,$ cm/s) to supersonic (${\sim}\,(6{-}8)\times 10^4\,$ cm/s). At the same time, motion toward the decreasing field region is accompanied by a decrease in the velocity from supersonic to subsonic. It has been found that the maximum temperature of the gas in the discharge at velocities of $\sim 10^4$ cm/s reaches $\sim 5.3$ kK.

Received: 04.12.2017
Revised: 12.12.2017

DOI: 10.7868/S0370274X18040033

 English version: Journal of Experimental and Theoretical Physics Letters, 2018, 107:4, 219–222

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