In this paper He-discharge (plasma jet/bullet) in atmospheric pressure air and its progression phenomenon has been studied experimentally using ICCD camera, optical emission spectroscopy (OES) and calibrated dielectric probe measurements. The repetitive nanosecond pulse has applied to a plasma pencil to generate discharge in the helium gas channel. The discharge propagation speed was measured from the ICCD images. The axial electric field distribution in the plasma jet is inferred from the optical emission spectroscopic data and from the probe measurement. The correlation between the jet velocities, jet length with the pulse duration is established. It shows that the plasma jet is not isolated from the input voltage along its propagation path. The discharge propagation speed, the electron density and the local and average electric field distribution along the plasma jet axis predicted from the experimental results are in good agreement with the data predicted by numerical simulation of the streamer propagation presented in different literatures. The ionization phenomenon of the discharge predicts the key ionization parameters, such as speed, peak electric field in the front, and electron density. The maximum local electric field measured by OES is 95 kV/cm at 1.3 cm of the jet axis, and average EF measured by probe is 24 kV/cm at the same place of the jet. The average and local electron density estimated are in the order of 10(11) cm(-3) and it reaches to the maximum of 10(12) cm(-3).
Original Publication Citation
Begum, A., Laroussi, M., & Pervez, M.R. (2013). Atmospheric pressure He-air plasma jet: Breakdown process and propagation phenomenon. AIP Advances, 3(6). doi: 10.1063/1.4811464
Begum, Asma; Laroussi, Mounir; and Pervez, Mohammad Rasel, "Atmospheric Pressure He-Air Plasma Jet: Breakdown Process and Propagation Phenomenon" (2013). Electrical & Computer Engineering Faculty Publications. 2.