Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet

Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet

Compared with the traditional sinusoidal voltage source, a short rising nanosecond voltage source can generate a high electron current for a short rising time. This paper investigates how the nanopulse parameters such as the voltage amplitude, pulse duration, and repetition frequency affect the radi...

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Main Authors: T. Y. Tang, H. S. Kim, G. H. Kim, B. Lee, H. J. Lee
Format: Article
Language:English
Published: AIP Publishing LLC 2020-12-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/5.0033907
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spelling doaj-aba4dc391333499d837d70171d197d072021-01-05T15:00:07ZengAIP Publishing LLCAIP Advances2158-32262020-12-011012125218125218-1210.1063/5.0033907Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jetT. Y. Tang0H. S. Kim1G. H. Kim2B. Lee3H. J. Lee4Department of Electrical and Computer Engineering, Pusan National University, Busan 46241, South KoreaKorea Electrotechnology Research Institute, Changwon 51543, South KoreaKorea Electrotechnology Research Institute, Changwon 51543, South KoreaKorea Electrotechnology Research Institute, Changwon 51543, South KoreaDepartment of Electrical and Computer Engineering, Pusan National University, Busan 46241, South KoreaCompared with the traditional sinusoidal voltage source, a short rising nanosecond voltage source can generate a high electron current for a short rising time. This paper investigates how the nanopulse parameters such as the voltage amplitude, pulse duration, and repetition frequency affect the radical generation and the plasma bullet propagation in an atmospheric pressure helium plasma jet. An intensified charge-coupled device was used to observe the bullet propagation in the nanosecond gate mode. The plasma bullet’s propagation speed is mainly affected by the applied voltage and externally biased electrodes rather than the pulse duration or the driving frequency. In contrast, optical emission spectroscopy diagnostics estimate that the radical density inside the atmospheric pressure plasma jet mainly increases with the repetition frequency. At the same time, the population of high-energy electrons can be controlled with the unipolar voltage amplitude. Thus, unipolar nanosecond pulses make it possible to control the emitting charges and the generated radicals independently.http://dx.doi.org/10.1063/5.0033907
collection DOAJ
language English
format Article
sources DOAJ
author T. Y. Tang
H. S. Kim
G. H. Kim
B. Lee
H. J. Lee
spellingShingle T. Y. Tang
H. S. Kim
G. H. Kim
B. Lee
H. J. Lee
Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet
AIP Advances
author_facet T. Y. Tang
H. S. Kim
G. H. Kim
B. Lee
H. J. Lee
author_sort T. Y. Tang
title Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet
title_short Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet
title_full Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet
title_fullStr Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet
title_full_unstemmed Optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet
title_sort optical diagnostics of the characteristics of a square unipolar nanosecond pulse-driven atmospheric pressure helium plasma jet
publisher AIP Publishing LLC
series AIP Advances
issn 2158-3226
publishDate 2020-12-01
description Compared with the traditional sinusoidal voltage source, a short rising nanosecond voltage source can generate a high electron current for a short rising time. This paper investigates how the nanopulse parameters such as the voltage amplitude, pulse duration, and repetition frequency affect the radical generation and the plasma bullet propagation in an atmospheric pressure helium plasma jet. An intensified charge-coupled device was used to observe the bullet propagation in the nanosecond gate mode. The plasma bullet’s propagation speed is mainly affected by the applied voltage and externally biased electrodes rather than the pulse duration or the driving frequency. In contrast, optical emission spectroscopy diagnostics estimate that the radical density inside the atmospheric pressure plasma jet mainly increases with the repetition frequency. At the same time, the population of high-energy electrons can be controlled with the unipolar voltage amplitude. Thus, unipolar nanosecond pulses make it possible to control the emitting charges and the generated radicals independently.
url http://dx.doi.org/10.1063/5.0033907
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