Title :
Ignition of a Microcavity Plasma Array
Author :
Wollny, Alexander ; Hemke, Torben ; Gebhardt, Markus ; Brinkmann, Ralf Peter ; Mussenbrock, Thomas
Author_Institution :
Lehrstuhl fur Theor. Elektrotechnik, Ruhr Univ. Bochum, Bochum, Germany
Abstract :
Microcavity plasma arrays are regular arrays of inverse pyramidal cavities created on positively doped silicon wafers. Each cavity acts as a microscopic dielectric barrier discharge. It has an opening of 50 μm × 50 μm and a depth of 45 μm. The separation of the cavities is 50 μm. Operated at atmospheric pressure in argon and excited with a 100-kHz RF voltage, each cavity develops a localized microplasma. Experiments show a strong interaction of the individual cavities, leading, for example, to the propagation of ionization waves along the array surface. This paper studies the ignition of a microcavity plasma array by means of a numerical simulation. The propagation of an ionization wave is observed. Its propagation speed matches experimental findings.
Keywords :
argon; discharges (electric); ignition; ionisation; microcavities; numerical analysis; plasma simulation; wave propagation; Ar; RF voltage; array surface; cavity separation; frequency 100 kHz; inverse pyramidal cavity arrays; ionization wave propagation; localized microplasma; microcavity plasma array ignition; microscopic dielectric barrier discharge; numerical simulation; positively doped silicon wafers; pressure 1 atm; propagation speed; size 45 mum; size 50 mum; Argon; Arrays; Cavity resonators; Discharges; Ignition; Microcavities; Plasmas; Atmospheric plasmas; microplasma array; plasma ignition; plasma–plasma interaction;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2011.2128350
