Title :
Transverse Stabilization of Atmospheric-Pressure DC Glow Plasma in Air With Resistive Barrier
Author :
Stephan, Karl D. ; Ghimire, Sagar ; Smith, Robert K. ; Komala-Noor, Laurence ; Massey, Nathan
Author_Institution :
Ingram Sch. of Eng., Texas State Univ., San Marcos, TX, USA
Abstract :
Atmospheric-pressure glow plasmas in air or other gases are attractive for industrial plasma processing, but attempts to obtain large-volume plasmas are plagued with filamentation due to transverse plasma instability. A method to prevent transverse instability of DC glow discharges using a resistive barrier is presented. Experimental data on current-voltage characteristics, light intensity versus time, and quantitative striation measurements indicate that the plasma is a true DC glow discharge which shows some longitudinal instability, but is transversely stabilized by a barrier with resistivity in the 104-106 Ω-m range. A finite-element model of the discharge´s electric field elucidates the mechanism of transverse stabilization.
Keywords :
glow discharges; plasma diagnostics; plasma instability; plasma transport processes; DC glow discharges; atmospheric-pressure DC glow plasma; current-voltage characteristics; filamentation; finite-element model; industrial plasma processing; large-volume plasmas; light intensity; longitudinal instability; resistive barrier; striation measurements; transverse plasma instability; transverse stabilization; Anodes; Cathodes; Discharges; Glow discharges; Plasmas; Rocks; Surface discharges; Glow discharges; plasma generation;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2011.2163735
