Formation of spatially periodic fronts of high-energy electrons in a radio-frequency driven surface microdischarge | Zendy

James Dedrick | Zendy; Deborah O’Connell | Zendy; Timo Gans | Zendy; Rod Boswell | Zendy; Christine Charles | Zendy

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Formation of spatially periodic fronts of high-energy electrons in a radio-frequency driven surface microdischarge

Author(s) -

James Dedrick,

Deborah O’Connell,

Timo Gans,

Rod Boswell,

Christine Charles

Publication year - 2013

Publication title -

applied physics letters

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.182

H-Index - 442

eISSN - 1077-3118

pISSN - 0003-6951

DOI - 10.1063/1.4789371

Subject(s) - atomic physics , electron , excitation , argon , electric field , radio frequency , phase (matter) , atmospheric pressure , spectroscopy , pulse (music) , materials science , physics , voltage , telecommunications , quantum mechanics , meteorology , computer science

The generation of spatially periodic fronts of high-energy electrons (>13.48 eV) has been investigated in a radio-frequency surface microdischarge in atmospheric-pressure argon. Optical emission spectroscopy is used to study the Ar I 2p1−1s2 transition surrounding a filamentary microdischarge, both spatially and with respect to the phase of the applied voltage. The formation of excitation fronts, which remain at a constant propagation distance throughout the RF cycle and for the duration of the pulse, may be explained by a localized increase in the electric field at the tip of surface-charge layers that are deposited during the extension phase.

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