Influence of oxygen gas on characteristics of self-organized luminous pattern formation observed in an atmospheric dc glow discharge using a liquid electrode

Shirai, Naoki; Uchida, Satoshi; Tochikubo, Fumiyoshi

doi:10.1088/0963-0252/23/5/054010

Cited by 59 publications

(80 citation statements)

References 34 publications

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“…As for figure 18, a DC glow discharge of He over a liquid anode is used. For both, a 1% NaCl solution or tap water anode, the self-organization of patterns tends to appear for larger inter-electrode spacing and high currents [167,169]. The emergence of patterns was also found to be dependent on the axial flow rate, with lower flow rates favoring the formation of patterns; as well as on the liquid temperature, par ticularly on the vapor pressure [167].…”

Section: Patterns On Liquid Anodesmentioning

confidence: 88%

“…Such response is qualitatively maintained for higher flow rates of incident gas. Moreover, further investigations show the emergence of anode patterns due to the diffusion of air on a He discharge, whereas no patterns are observed when a sheath flow of N 2 (which limits the entrainment of O 2 into the discharge) is used [167].…”

Section: Patterns On Liquid Anodesmentioning

confidence: 99%

“…(a) The obtained patterns transition from a single constricted diffuse spot, to set of concentric annular patterns, and then to an array of spot patterns for increasing values of current in an atmospheric-pressure DC glow discharge on a liquid water anode; and (b) the imposition of an incident lateral flow of gas causes only the deflection of the plasma column when N 2 is used, whereas a complex pattern emerges when O 2 is used. (Adapted from [167] with permission, copyright 2014 IOP Publishing Ltd.) constricted diffuse spot, to a set of concentric annular patterns, and then to an array of spot patterns for increasing values of current. Figure 18(b) depicts the effect of the imposition of an incident lateral flow of molecular gas on the obtained patterns.…”

Section: Patterns On Liquid Anodesmentioning

confidence: 99%

“…A different line is used for a given electrode spacing, whereas a shaded area indicates a specific type of pattern. (Adapted from [167] with permission, copyright 2014 IOP Publishing Ltd.) study of pattern formation and self-organization phenomena in plasmas interacting with surfaces is important not only for a deeper understanding of nature, but also for their relevance to technological applications that exploit or mitigate selforganization, e.g. from surface activation and texturization, to electrode erosion and process nonuniformity.…”

Section: Concluding Remarks and Outlookmentioning

confidence: 99%

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Pattern formation and self-organization in plasmas interacting with surfaces

Trelles¹

2016

J. Phys. D: Appl. Phys.

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Pattern formation and self-organization are fascinating phenomena commonly observed in diverse types of biological, chemical and physical systems, including plasmas. These phenomena are often responsible for the occurrence of coherent structures found in nature, such as recirculation cells and spot arrangements; and their understanding and control can have important implications in technology, e.g. from determining the uniformity of plasma surface treatments to electrode erosion rates. This review comprises theoretical, computational and experimental investigations of the formation of spatiotemporal patterns that result from self-organization events due to the interaction of low-temperature plasmas in contact with confining or intervening surfaces, particularly electrodes. The basic definitions associated to pattern formation and self-organization are provided, as well as some of the characteristics of these phenomena within natural and technological contexts, especially those specific to plasmas. Phenomenological aspects of pattern formation include the competition between production/forcing and dissipation/transport processes, as well as nonequilibrium, stability, bifurcation and nonlinear interactions. The mathematical modeling of pattern formation in plasmas has encompassed from theoretical approaches and canonical models, such as reaction-diffusion systems, to drift-diffusion and nonequilibrium fluid flow models. The computational simulation of pattern formation phenomena imposes distinct challenges to numerical methods, such as high sensitivity to numerical approximations and the occurrence of multiple solutions. Representative experimental and numerical investigations of pattern formation and self-organization in diverse types of low-temperature electrical discharges (low and high pressure glow, dielectric barrier and arc discharges, etc) in contact with solid and liquid electrodes are reviewed. Notably, plasmas in contact with liquids, found in diverse emerging applications ranging from nanomaterial synthesis to medicine, show marked sensitivity to pattern formation and a broadened range of controlling parameters. The results related to the characteristics of the patterns, such as their geometric configuration and static or dynamic nature; as well as their controlling factors, including gas composition, driving voltage and current, electrode cooling, and imposed gas flow, are summarized and discussed. The article finalizes with an outlook of the research area, including theoretical, computational, and experimental needs to advance the field.

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Section: Patterns On Liquid Anodesmentioning

confidence: 88%

Section: Patterns On Liquid Anodesmentioning

confidence: 99%

Section: Patterns On Liquid Anodesmentioning

confidence: 99%

Section: Concluding Remarks and Outlookmentioning

confidence: 99%

See 2 more Smart Citations

Pattern formation and self-organization in plasmas interacting with surfaces

Trelles¹

2016

J. Phys. D: Appl. Phys.

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“…Plasma jets are normally excited by pulsed voltages with kilohertz repetition frequencies as well as sinusoidal voltages in the kilohertz-to-megahertz range. [15][16][17][18][19][20] Besides, related studies have been reported with concern of the discharge characteristics, 21 the discharge mechanism, 22,23 and the analysis of plasma products, 24 etc. Recently, the comparisons of pulsed and sinusoidal plasma jets in the gas phase have been reported, 15,25 and the results show that pulsed excitation is more efficient to produce energetic electrons rather than heat the gas, 25 and hence more reactive species can be generated in pulsed plasmas.…”

Section: Introductionmentioning

confidence: 99%

Comparison between the water activation effects by pulsed and sinusoidal helium plasma jets

Liu

Xia

et al. 2018

Physics of Plasmas

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Comparisons between pulsed and sinusoidal plasma jets have been extensively reported for the discharge characteristics and gaseous reactive species, but rarely for the aqueous reactive species in water solutions treated by the two types of plasma jets. This motivates us to compare the concentrations of aqueous reactive species induced by a pulsed and a sinusoidal plasma jet, since it is widely reported that these aqueous reactive species play a crucial role in various plasma biomedical applications. Experimental results show that the aqueous H 2 O 2 , OH/O 2 À , and O 2 À /ONOO À induced by the pulsed plasma jet have higher concentrations, and the proportional difference increases with the discharge power. However, the emission intensities of OH(A) and O(3p 5 P) are higher for the sinusoidal plasma jet, which may be attributed to its higher gas temperature since more water vapor could participate in the plasma. In addition, the efficiency of bacterial inactivation induced by the pulsed plasma jet is higher than that for the sinusoidal plasma jet, in accordance with the concentration relation of aqueous reactive species for the two types of plasma jets.

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Diffuse and spotted anode layers in an atmospheric pressure glow discharge with a water electrode and miniature argon flow

Kang

Gao

et al. 2020

Plasma Processes & Polymers

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Upon varying discharge current and gap width, several self‐organized patterns are observed in the anode layer of an atmospheric pressure glow discharge with miniature axial argon flow, including diffuse‐disk, single‐ring, disk‐ring, wheel‐spokes, and radial‐stripes patterns. Among them, the wheel‐spokes pattern is observed for the first time in atmospheric pressure glow discharge above a water anode. The conditions for generating the self‐organized patterns are also investigated. Fast photography results indicate that the patterns with low current and narrow gap are diffuse in nature, while those with high current and wide gap are composed of individual spots. This is further verified from waveforms of applied voltage and light emission signals. Moreover, the generation, movement, and disappearance of discrete spots are observed by a high‐speed video camera. Besides, the optical emission spectrum indicates that the glow discharge above the water surface is abundant with electronegative species, including O, NO, NH, and OH. Finally, the formation mechanism of diffuse and spotted anode layers is revealed.

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Influence of oxygen gas on characteristics of self-organized luminous pattern formation observed in an atmospheric dc glow discharge using a liquid electrode

Cited by 59 publications

References 34 publications

Pattern formation and self-organization in plasmas interacting with surfaces

Pattern formation and self-organization in plasmas interacting with surfaces

Comparison between the water activation effects by pulsed and sinusoidal helium plasma jets

Diffuse and spotted anode layers in an atmospheric pressure glow discharge with a water electrode and miniature argon flow

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