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The Effect of Tube Diameter on an Atmospheric‐Pressure Micro‐Plasma Jet
Author(s) -
Cheng He,
Lu Xinpei,
Liu Dawei
Publication year - 2015
Publication title -
plasma processes and polymers
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.644
H-Index - 74
eISSN - 1612-8869
pISSN - 1612-8850
DOI - 10.1002/ppap.201500124
Subject(s) - plasma , materials science , jet (fluid) , atmospheric pressure plasma , tube (container) , electron density , voltage , atmospheric pressure , atomic physics , ignition system , dielectric barrier discharge , electron , analytical chemistry (journal) , electrode , dielectric , chemistry , composite material , mechanics , optoelectronics , electrical engineering , thermodynamics , physics , meteorology , nuclear physics , chromatography , engineering
The micro‐plasma jet is a unique way of transporting active species of plasma to small targets for applications such as a single cancer cell treatment, and endoscopic surgeries. In this letter, the authors present numerical studies on a single cylindrical electrode micro‐plasma jet. The effect of tube diameter on sustaining voltage, electron density, and the density of reactive species are investigated. The diameter of the dielectric tube was varied in the range between 0.1 and 1mm. A pulsed direct current voltage with rising phase of 50 ns was used to ignite the plasma jet. The sustaining voltage monotonically increased with the decreasing diameter of the tube. More electrons wall losses happened due to the faster drift movement to the inner wall of smaller tube diameter, therefore, the decreasing pre‐avalanche electron density need increasing ignition voltage to facilitate the avalanche‐streamer transition as the tube diameter decreased. The increasing ignition voltage increased the chemical reactivity of plasma jet. The peak density of O 2 * and O increased more than 20 times as the tube diameter decreased from 1 to 0.1 mm.