Influence of pulse modulation frequency on helium RF atmospheric pressure plasma jet characteristics

TL;DR

This study examines how varying pulse modulation frequency and duty cycle affect helium RF atmospheric pressure plasma jet characteristics, revealing optimal conditions for enhanced plasma performance and potential industrial and biomedical applications.

Contribution

It provides a comprehensive analysis of pulse modulation effects on plasma jets, introducing optimal parameters for improved plasma behavior and efficiency.

Findings

Lower modulation frequencies increase plasma size and reactive species emission.

Reduced gas temperature at low power operation enhances application safety.

Optimal duty cycle (10-40%) balances plasma length and power consumption.

Abstract

This work investigates the influence of pulse modulation frequency ranging from 50 Hz- 10 kHz on the helium RF atmospheric pressure plasma jet's fundamental characteristics. The impact of modulation frequency on plasma jet discharge behavior, geometrical variation, reactive species emission, and plasma parameters (gas temperature Tg, electron excitation temperature Texc, and electron density (ne) are studied using various diagnostics such as optical imaging, emission spectra, and thermal diagnostics. From the experiments, it is observed that operating the plasma jet at low pulse modulation frequencies (around 50 Hz) provides enhanced plasma dimensions, higher electron densities and greater optical emission from reactive species (viz., He I, O, OH, N2+, etc.) as compared to the higher modulation frequencies. Besides the low power consumption, the three times less gas temperature of the modulated plasma jet than the continuous wave mode makes it more advantageous for the applications. Moreover, the influence of duty cycle (D) and applied RF power (P) on the plasma jet characteristics are also discussed. It is found that 10- 40% duty cycle operation provides the most favorable attributes. More importantly, the concern of shorter plasma length in RF plasma jets is overcome by operating at 10- 20% duty cycle with increased applied power. This work thoroughly characterizes helium atmospheric pressure RF plasma jet with a wide range of pulse mode operating parameters, which could help select appropriate operating conditions for various industrial and biomedical applications.