Effect of helium pressure and flow rate on microplasma propagation along hollow-core fibers

Longfei Ji; Zhenhua Bi; Jinhai Niu; Xianhui Zhang; Renwu Zhou; Ying Song; Jiahong Liu; Dongping Liu

doi:10.1116/1.4902967

Effect of helium pressure and flow rate on microplasma propagation along hollow-core fibers

Longfei Ji
, Zhenhua Bi
, Jinhai Niu
, Xianhui Zhang
, Renwu Zhou
, Ying Song
, Jiahong Liu
, Dongping Liu

科研成果: 期刊稿件 › 文章 › 同行评审

2 引用（Scopus）

摘要

The effect of helium pressure and flow rate on the propagation of microplasmas obtained inside hollow-core fibers (HCFs) with their inner diameters of 100-2000μm has been reported in this study. Measurements show that microplasma length, breakdown voltage, pulse durations, and pulse current are strongly dependent on He flow rate and He pressure ranging from 50 Pa to 1.0 atm. Comparison between experimental results and analytical mode shows that Townsend's model is valid for understanding the discharge process of microplasmas inside HCFs, where the wall effect has to be considered. Analysis indicates that long-lived metastable species (He_m&z.ast) from one previous discharge period can greatly contribute to the propagation of microplasmas along the microns-thick HCFs. An avalanche discharge model combined with the surface recombination of charged species has been used to explain the propagation of microplasma inside HCFs.

源语言	英语
文章编号	021302
期刊	Journal of Vacuum Science and Technology A: Vacuum, Surfaces and Films
卷	33
期	2
DOI	https://doi.org/10.1116/1.4902967
出版状态	已出版 - 1 3月 2015
已对外发布	是

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abstract = "The effect of helium pressure and flow rate on the propagation of microplasmas obtained inside hollow-core fibers (HCFs) with their inner diameters of 100-2000μm has been reported in this study. Measurements show that microplasma length, breakdown voltage, pulse durations, and pulse current are strongly dependent on He flow rate and He pressure ranging from 50 Pa to 1.0 atm. Comparison between experimental results and analytical mode shows that Townsend's model is valid for understanding the discharge process of microplasmas inside HCFs, where the wall effect has to be considered. Analysis indicates that long-lived metastable species (Hem\&z.ast) from one previous discharge period can greatly contribute to the propagation of microplasmas along the microns-thick HCFs. An avalanche discharge model combined with the surface recombination of charged species has been used to explain the propagation of microplasma inside HCFs.",

author = "Longfei Ji and Zhenhua Bi and Jinhai Niu and Xianhui Zhang and Renwu Zhou and Ying Song and Jiahong Liu and Dongping Liu",

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T1 - Effect of helium pressure and flow rate on microplasma propagation along hollow-core fibers

AU - Ji, Longfei

AU - Bi, Zhenhua

AU - Niu, Jinhai

AU - Zhang, Xianhui

AU - Zhou, Renwu

AU - Song, Ying

AU - Liu, Jiahong

AU - Liu, Dongping

PY - 2015/3/1

Y1 - 2015/3/1

N2 - The effect of helium pressure and flow rate on the propagation of microplasmas obtained inside hollow-core fibers (HCFs) with their inner diameters of 100-2000μm has been reported in this study. Measurements show that microplasma length, breakdown voltage, pulse durations, and pulse current are strongly dependent on He flow rate and He pressure ranging from 50 Pa to 1.0 atm. Comparison between experimental results and analytical mode shows that Townsend's model is valid for understanding the discharge process of microplasmas inside HCFs, where the wall effect has to be considered. Analysis indicates that long-lived metastable species (Hem&z.ast) from one previous discharge period can greatly contribute to the propagation of microplasmas along the microns-thick HCFs. An avalanche discharge model combined with the surface recombination of charged species has been used to explain the propagation of microplasma inside HCFs.

AB - The effect of helium pressure and flow rate on the propagation of microplasmas obtained inside hollow-core fibers (HCFs) with their inner diameters of 100-2000μm has been reported in this study. Measurements show that microplasma length, breakdown voltage, pulse durations, and pulse current are strongly dependent on He flow rate and He pressure ranging from 50 Pa to 1.0 atm. Comparison between experimental results and analytical mode shows that Townsend's model is valid for understanding the discharge process of microplasmas inside HCFs, where the wall effect has to be considered. Analysis indicates that long-lived metastable species (Hem&z.ast) from one previous discharge period can greatly contribute to the propagation of microplasmas along the microns-thick HCFs. An avalanche discharge model combined with the surface recombination of charged species has been used to explain the propagation of microplasma inside HCFs.

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M3 - 文章

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Effect of helium pressure and flow rate on microplasma propagation along hollow-core fibers

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