Title :
RF Discharges in Nonequilibrium Atmospheric-Pressure Plasma Jets at Narrow Gap Sizes
Author :
Qurat-ul-Ain ; Laimer, Johann ; Störi, Herbert
Author_Institution :
Inst. of Appl. Phys., Vienna Univ. of Technol., Vienna, Austria
Abstract :
Electrical and spectroscopic investigations of an atmospheric-pressure plasma jet ( APPJ) using variable flow rates of helium gas have shown that an alteration of the gas flow rate changes the operation region of stable uniform discharges. By decreasing the gap spacing to values below 400 μm and decreasing the gas flow rate, the uniform discharges can be operated at higher current densities and, consequently, higher radio-frequency power. Time-resolved optical emission spectroscopy has shown that, at low gas flow rates in narrow gaps (below 400 μm), back diffusion is prominent, which influences the stability of the discharge in the jet. An attempt for scaling up an APPJ by doubling its surface area has shown that, with increasing the surface area, the power dissipation cannot be increased, thus limiting the possibility to scale up such type of plasma sources.
Keywords :
helium; high-frequency discharges; plasma diagnostics; plasma instability; plasma jets; plasma sources; plasma transport processes; He; RF discharges; back diffusion rates; discharge stability analysis; electrical method; helium gas flow rates; high current densities; high radiofrequency power; narrow gap sizes; nonequilibrium atmospheric-pressure plasma jets; operation region; plasma sources; power dissipation rates; pressure 1 atm; stable uniform discharges; time-resolved optical emission spectroscopy; Discharges (electric); Fault location; Helium; Plasma sources; Radio frequency; $gamma$-discharge; Atmospheric-pressure plasma jet (APPJ); Penning ionization; glowlike discharge; metastable state; radio-frequency (RF) discharge;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2012.2219558
