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Effects of supersonic flow on pulsed surface sliding discharge characteristics
Russian version
A.S. Sazonov1, I.V. Mursenkova1
1Department of Physics, Lomonosov Moscow State University, Moscow, Russia
Email: as.sazonov@physics.msu.ru
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The results of an experimental study of current and emission characteristics of a pulsed surface sliding discharge in supersonic air flows with Mach numbers ranging from 1.20 to 1.70 and gas densities from 0.01 to 0.32 kg/m3 are presented. A 500 ns discharge was initiated in a single-pulse mode at a voltage of 25 kV; the peak discharge current reached 1 kA. The length of the discharge region along the flow direction was approximately 100 mm. Measurements of discharge current and emission characteristics were performed in both uniform flows and in flows with an inclined shock wave. It is shown that the non-uniform density distribution in the boundary layer of a supersonic airflow results in distinctive features in the discharge current behavior and spatial radiation distribution compared to stationary air. Keywords: nanosecond surface sliding discharge, discharge current, glow distribution, supersonic flow.
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