Characterization of atmospheric pressure plasma plume

TL;DR

This study thoroughly characterizes an atmospheric pressure plasma plume using simple, in-situ diagnostic techniques to measure parameters like temperature, velocity, and electron density, aiding optimization for biological and industrial uses.

Contribution

It introduces a comprehensive, low-complexity diagnostic approach for in-situ plasma plume characterization, including temperature, velocity, and density measurements.

Findings

Plasma temperature ranges from 42.5 to 24.5°C.

Electron excitation temperature and reactive species identified.

Plasma density ranges from 0.069 to 5.96 x 10^12 cm^-3.

Abstract

In order to optimize the parameters of the plasma plume for atmospheric pressure plasma applications such as biological and industrial applications, it is highly necessary to thoroughly understand its characteristics. In this paper, various diagnostic techniques are discussed to characterize the atmospheric pressure plasma plume. The major emphasis of this work is to utilize possibly simple methods, low complexity in post data analysis and obtain in-situ information. The parameters of the plasma plume such as spatial variation of gas temperature, electron excitation temperature, plume velocity, plume current, electron density are experimentally measured. In addition, plasma discharge behavior and plume formation with various gas flow rates and applied voltage are studied. The characterization of the above parameters is carried out by using electrical diagnostics (voltage probe and a current sensor), Optical diagnostics (optical emission spectroscopy (OES), fast imaging method using ICCD camera), and thermocouple. The plasma plume/gas temperature along the plume length is measured by using a simple K-type thermocouple and is found to be in the range of (42.5 - 24.5) deg C. The OES is used to estimate the electron excitation temperature of plasma plume and to identify the key reactive species (OH, NO, N2+, O, etc.) present in the plume. ICCD camera is utilized to capture the temporal evolution of plasma and to estimate the plume velocity along the plume length. The current transformer is utilized to measure the plume current along the plume length. By using the velocity and current information, the plasma density is evaluated, and the obtained values are in the range of (0.069-5.96)x 10^12 cm^-3. The above range of parameters and tunable nature of our designed plasma source will be useful for the development and optimization of plasma sources for various applications.