Electrical discharges in the vapour phase in liquid-filled capillaries

P. Bruggeman; J. Degroote; C. Leys; J. Vierendeels

doi:10.1088/0022-3727/41/19/194007

Electrical discharges in the vapour phase in liquid-filled capillaries

P. Bruggeman, J. Degroote, C. Leys, J. Vierendeels

Mechanical Engineering

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24 Scopus citations

Abstract

In this work electrical discharges in the vapour phase in liquid-filled capillaries are investigated. The vapour phase is generated due to Joule heating of the NaCl solution in a narrow dielectric capillary in which plasma is generated. A repetitive bubble formation regime, a chaotic plasma regime and a periodic intense plasma regime are observed with increasing voltage. The plasma is produced in the bubble and the liquid columns on both sides of the bubble serve as electrodes for the discharges. In the emission spectra contributions of OH, H, Na and O are identified. The OH rotational distribution can be characterized by a superposition of two Boltzmann distributions with temperature parameters of 2800 and 8800 K.

Original language	English (US)
Article number	194007
Journal	Journal of Physics D: Applied Physics
Volume	41
Issue number	19
DOIs	https://doi.org/10.1088/0022-3727/41/19/194007
State	Published - Oct 7 2008

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AB - In this work electrical discharges in the vapour phase in liquid-filled capillaries are investigated. The vapour phase is generated due to Joule heating of the NaCl solution in a narrow dielectric capillary in which plasma is generated. A repetitive bubble formation regime, a chaotic plasma regime and a periodic intense plasma regime are observed with increasing voltage. The plasma is produced in the bubble and the liquid columns on both sides of the bubble serve as electrodes for the discharges. In the emission spectra contributions of OH, H, Na and O are identified. The OH rotational distribution can be characterized by a superposition of two Boltzmann distributions with temperature parameters of 2800 and 8800 K.

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Electrical discharges in the vapour phase in liquid-filled capillaries

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