Spectroscopic study of bipolar nanosecond pulse gas-liquid discharge in atmospheric argon

Sen Wang; Dezheng Yang; Feng Liu; Wenchun Wang; Zhi Fang

doi:10.1088/2058-6272/aabac8

Spectroscopic study of bipolar nanosecond pulse gas-liquid discharge in atmospheric argon

Sen Wang, Dezheng Yang, Feng Liu, Wenchun Wang, Zhi Fang

COLLEGE OF ELECTRICAL ENGINEERING AND CONTROL SCIENCE

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

Atmospheric gas-liquid discharge with argon as a working gas is presented by employed nanosecond pulse power. The discharge is presented in a glow-like mode. The discharge powers are determined to be less than 1W, and remains almost constant when the discharge duration time increases. Bountiful active species are determined by capturing optical emission spectra, and their main generation processes are also discussed. The plasma gas temperature is calculated as 350 K by comparing the experimental spectra and the simulated ones of N₂ C³ π_g → B³ π_g, Δν = - 2). The time resolved vibrational and rotational temperature is researched to present the stability of discharge when pulse voltage and discharge duration vary. The electron density is determined to be 1016 cm?3 according to the Stark broadening effect of the H_∞ line.

Original language	English
Article number	075404
Journal	Plasma Science and Technology
Volume	20
Issue number	7
DOIs	https://doi.org/10.1088/2058-6272/aabac8
State	Published - Jul 2018

Keywords

electron density
gas-liquid discharge
nanosecond pulse discharge
optical emission spectra

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10.1088/2058-6272/aabac8

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title = "Spectroscopic study of bipolar nanosecond pulse gas-liquid discharge in atmospheric argon",

abstract = "Atmospheric gas-liquid discharge with argon as a working gas is presented by employed nanosecond pulse power. The discharge is presented in a glow-like mode. The discharge powers are determined to be less than 1W, and remains almost constant when the discharge duration time increases. Bountiful active species are determined by capturing optical emission spectra, and their main generation processes are also discussed. The plasma gas temperature is calculated as 350 K by comparing the experimental spectra and the simulated ones of N2 C3 πg → B3 πg, Δν = - 2). The time resolved vibrational and rotational temperature is researched to present the stability of discharge when pulse voltage and discharge duration vary. The electron density is determined to be 1016 cm?3 according to the Stark broadening effect of the H∞ line.",

keywords = "electron density, gas-liquid discharge, nanosecond pulse discharge, optical emission spectra",

author = "Sen Wang and Dezheng Yang and Feng Liu and Wenchun Wang and Zhi Fang",

note = "Publisher Copyright: {\textcopyright} 2018 Hefei Institutes of Physical Science, Chinese Academy of Sciences and IOP Publishing.",

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T1 - Spectroscopic study of bipolar nanosecond pulse gas-liquid discharge in atmospheric argon

AU - Wang, Sen

AU - Yang, Dezheng

AU - Liu, Feng

AU - Wang, Wenchun

AU - Fang, Zhi

PY - 2018/7

Y1 - 2018/7

N2 - Atmospheric gas-liquid discharge with argon as a working gas is presented by employed nanosecond pulse power. The discharge is presented in a glow-like mode. The discharge powers are determined to be less than 1W, and remains almost constant when the discharge duration time increases. Bountiful active species are determined by capturing optical emission spectra, and their main generation processes are also discussed. The plasma gas temperature is calculated as 350 K by comparing the experimental spectra and the simulated ones of N2 C3 πg → B3 πg, Δν = - 2). The time resolved vibrational and rotational temperature is researched to present the stability of discharge when pulse voltage and discharge duration vary. The electron density is determined to be 1016 cm?3 according to the Stark broadening effect of the H∞ line.

AB - Atmospheric gas-liquid discharge with argon as a working gas is presented by employed nanosecond pulse power. The discharge is presented in a glow-like mode. The discharge powers are determined to be less than 1W, and remains almost constant when the discharge duration time increases. Bountiful active species are determined by capturing optical emission spectra, and their main generation processes are also discussed. The plasma gas temperature is calculated as 350 K by comparing the experimental spectra and the simulated ones of N2 C3 πg → B3 πg, Δν = - 2). The time resolved vibrational and rotational temperature is researched to present the stability of discharge when pulse voltage and discharge duration vary. The electron density is determined to be 1016 cm?3 according to the Stark broadening effect of the H∞ line.

KW - electron density

KW - gas-liquid discharge

KW - nanosecond pulse discharge

KW - optical emission spectra

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DO - 10.1088/2058-6272/aabac8

M3 - 文章

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SN - 1009-0630

VL - 20

JO - Plasma Science and Technology

JF - Plasma Science and Technology

IS - 7

M1 - 075404

ER -

Spectroscopic study of bipolar nanosecond pulse gas-liquid discharge in atmospheric argon

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Keywords

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