The recovery of glow-plasma structure in atmospheric radio frequency microplasmas at very small gaps

Zhang, Yuantao; Shang, Wanli

doi:10.1063/1.3660677

Cited by 23 publications

(23 citation statements)

References 18 publications

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“…Moreover, an electron-heating mode and its transition, which are induced by changes in the input power and frequency, have been reported as in the cases of low-pressure discharges. 9,[13][14][15] However, the previous studies of the electron-heating mode were based on fluid models; 11,12 the effects of heating on the electron kinetics has not yet been clarified. In particular, we are interested in the electron energy distribution function (EEDF) on the electrodes in atmospheric discharges for biomedical applications.…”

Section: Introductionmentioning

confidence: 98%

“…1-8 For atmospheric radio-frequency (rf) capacitive discharges, a variety of microplasmas operating over a wide range of frequencies and sub-millimeter dimensions have been reported. 1,4,[9][10][11][12] We previously studied single-frequency (SF) 9 and dual-frequency (DF) 10 atmospheric-pressure helium microplasmas, which can be sustained over a wide range of microwave frequencies from 400 MHz to 2.45 GHz. These microwave-induced microplasmas are important because they may be used to develop safe, portable, and long-lifetime devices capable of operating at atmospheric pressure.…”

Section: Introductionmentioning

confidence: 99%

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Abnormal electron-heating mode and formation of secondary-energetic electrons in pulsed microwave-frequency atmospheric microplasmas

et al. 2014

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The formation of secondary energetic electrons induced by an abnormal electron-heating mode in pulsed microwave-frequency atmospheric microplasmas was investigated using particle-in-cell simulation. We found that additional high electron heating only occurs during the first period of the ignition phase after the start of a second pulse at sub-millimeter dimensions. During this period, the electrons are unable to follow the abruptly retreating sheath through diffusion alone. Thus, a selfconsistent electric field is induced to drive the electrons toward the electrode. These behaviors result in an abnormal electron-heating mode that produces high-energy electrons at the electrode with energies greater than 50 eV. V C 2014 AIP Publishing LLC. [http://dx.

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Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Abnormal electron-heating mode and formation of secondary-energetic electrons in pulsed microwave-frequency atmospheric microplasmas

et al. 2014

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“…The current density with a normal sinusoidal form is taken as the input parameter [4], [6], [24], and the driving frequency is 13.56 MHz; the coupled power, actually the power per area as a result of 1-D limit, is usually fixed, to reasonably compare the evolution of discharge. The present model with pure helium as working gas has been explored to investigate the discharge characteristics at very small gaps [22], and the simulation results show a good agreement of experimental observation [21]. As the oxygen admixture was introduced, the discharge characteristics and generation of ROS at a relatively large electrode gap also have been investigated and compared with the experimental measurements [13].…”

Section: Description Of Plasma Modelmentioning

confidence: 72%

“…The fundamental physics of RF discharges shows some unique characteristics features in microplasma regime, which have been discussed in detail in [17]- [19]. A sheath-dominated structure with a large portion of sheath region has usually been observed, and a traditional glowdischarge structure with a distinct bulk plasma and sheath could not be formed in RF microplasmas [20], [21]; in addition, the recent computational study indicated that the glow-discharge structure could also be recovered by increasing the excitation frequency even at very small gaps [22]. However, when the oxygen admixtures are added into helium microplasmas, plenty of new neutral and charged particles will be generated, and this could influence the evolution of discharge structure.…”

Section: Introductionmentioning

confidence: 95%

Electrode-Gap Effects on the Discharge Structure in Atmospheric Radio-Frequency Microplasmas With He/O<sub>2</sub> Mixtures

Zhang

2014

IEEE Trans. Plasma Sci.

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The electrode-gap effects on the discharge characteristics have attracted increasing attention to the design of atmospheric discharge sources. In this paper, a 1-D fluid model is used to explore the discharge structures in atmospheric radiofrequency microplasmas with He/O 2 mixture as working gas as well as to discuss the generation of reactive oxygen species (ROS) with the electrode gap varied. As oxygen admixtures are introduced into the helium microplasmas, the heavy anions of O − and O − 2 become the dominative negative species instead of electrons, and then establish the bulk plasma region together with the positive ions. Thus, even at very small gaps, a normal glow-discharge discharge structure can be formed, and a sheathdominated discharge structure, which is usually formed in pure helium microplasmas in a small size, cannot be observed any more. The simulation results also indicate that the production of main ROS is more effective in small dimensions. IndexTerms-Atmospheric radio-frequency (RF) microplasmas, discharge structure, plasma simulation, reactive oxygen species (ROS).

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“…[1][2][3][4][5][6][7][8] In particular, for atmospheric radio-frequency (rf) capacitive discharges, a large variety of single-frequency (SF) microplasmas that operate over a wide range of frequencies and sub-millimeter dimensions have been reported. 1,4,[9][10][11] Especially, in our previous study, 9 SF atmospheric-pressure helium microdischarges sustained over a wide range of microwave frequencies were the focus of our investigation. The microplasmas generated in these studies showed unique properties, such as highly energetic electrons, different discharge structures, and non-equilibrium characteristics.…”

Section: Introductionmentioning

confidence: 99%

Enhanced transportation of energetic electrons in dual-frequency atmospheric microplasmas

et al. 2013

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A comparative study of electron kinetics between single-frequency (SF) microplasmas and their equivalent dual-frequency (DF) microplasmas with matching effective frequencies in atmosphericpressure helium discharges was performed using particle-in-cell simulation with a Monte Carlo collision. The effective-frequency concept helps in analyzing DF microplasmas in a fashion similar to SF microplasmas with effective parameters. In this study, the plasma characteristics such as the plasma potential, density, and electron energy probability functions of the SF microplasma and its DF counterpart were almost the same. However, the oscillating sheath edge was pushed further into the electrode for a substantial fraction of the time and the sheath width decreased in DF microplasmas. As a result, the transportation of the energetic electrons (e > 4 eV) usable for tailoring the surface chemistry in atmospheric microplasmas is enhanced in DF microplasmas as compared to SF microplasmas. V C 2013 American Institute of Physics. [http://dx.

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The recovery of glow-plasma structure in atmospheric radio frequency microplasmas at very small gaps

Cited by 23 publications

References 18 publications

Abnormal electron-heating mode and formation of secondary-energetic electrons in pulsed microwave-frequency atmospheric microplasmas

Abnormal electron-heating mode and formation of secondary-energetic electrons in pulsed microwave-frequency atmospheric microplasmas

Electrode-Gap Effects on the Discharge Structure in Atmospheric Radio-Frequency Microplasmas With He/O<sub>2</sub> Mixtures

Enhanced transportation of energetic electrons in dual-frequency atmospheric microplasmas

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