Investigation of multi-periodic self-trigger plasma in an AC-driven atmospheric pressure plasma jet

Atmospheric Pressure Plasma Jets have been intensively studied due to their potential application in biological fields but some of their physics properties are still not well understood. In the present article, a helium plasma jet driven by 15-18 kHz sinusoidal voltage ignites multi-periodic self-triggered mode or random mode depending on the applied voltage, driven frequency and inter-electrode gap distance. Most of the observed multiperiodic bullets operate every 2 or 3 sinusoidal periods. Such bullets show similarities with pulsed operating mode, having a jitter of less than 100 ns. The presence of an outer grounded electrode ring is a key parameter permitting the ignition of multiperiodic bullets; it also enhances the propagation length up to 8 times. Fast imaging reveals that 2-3 self-triggered discharges occur in the gap region prior to ignition of the bullet in both positive or negative polarities; this leads to an accumulation of charges beneath the ground electrode, locally enhancing the electric field. Bullet velocities for different polarities and gap distances are compared using optical emission spectrum.

Automated summary

The article studies a helium plasma jet driven by 15-18 kHz sinusoidal voltage and its multi-periodic self-triggered mode or random mode based on applied voltage, driven frequency, and inter-electrode gap distance. Most of the observed bullets operate every 2 or 3 sinusoidal periods, resembling pulsed operating mode. The presence of an outer grounded electrode ring is crucial for ignition and enhances the propagation length up to 8 times. Fast imaging reveals pre-ignition self-triggered discharges and accumulation of charges beneath the ground electrode, locally enhancing the electric field. Bullet velocities are compared using optical emission spectrum for different polarities and gap distances.