2016
DOI: 10.1088/0022-3727/49/39/393002
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Pattern formation and self-organization in plasmas interacting with surfaces

Abstract: 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 th… Show more

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Cited by 89 publications
(74 citation statements)
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“…Plasmas on liquids can generate coherent structures that have not been modelled from first principles. In fact, modelling coherent structures is generally a challenge [169]. The large dynamic range of time/ spatial scales and physical phenomena continues to challenge the field.…”
Section: Modelling and Simulationmentioning
confidence: 99%
“…Plasmas on liquids can generate coherent structures that have not been modelled from first principles. In fact, modelling coherent structures is generally a challenge [169]. The large dynamic range of time/ spatial scales and physical phenomena continues to challenge the field.…”
Section: Modelling and Simulationmentioning
confidence: 99%
“…As a result, there are complex interactions among plasma jet, dielectric, and surface discharges. These interactions can lead to pattern formation . A crescent pattern appears on a dielectric colliding obliquely with a helium plasma plume, which transits to a solid‐disk pattern for vertical incidence of the plume .…”
Section: Introductionmentioning
confidence: 99%
“…These interactions can lead to pattern formation. [26,27] A crescent pattern appears on a dielectric colliding obliquely with a helium plasma plume, [28] which transits to a solid-disk pattern for vertical incidence of the plume. [29,30] Moreover, the solid disk can transit to a single ring by varying the gas flow rate, [29,30] changing the gap distance, [31] or adding trace of nitrogen into helium.…”
Section: Introductionmentioning
confidence: 99%
“…The results show that patterns appear at a critical value of h w ∼ 10 3 –10 4 Wm −2 K −1 , almost independently of the value of I tot ; the patterns become more accentuated with increasing cooling; and for very high cooling, the patterns become dynamic (which explains the asymmetric distribution of spots in Figure ). Two‐dimensional, steady‐state, and/or LTE models cannot adequately capture the occurrence of pattern formation in arc discharges − a fact that highlights the need for time‐dependent, three‐dimensional NLTE models for accurate arc discharge simulations …”
Section: Non‐equilibrium Plasma Flow Simulationsmentioning
confidence: 99%
“…Two-dimensional, steady-state, and/or LTE models cannot adequately capture the occurrence of pattern formation in arc discharges À a fact that highlights the need for time-dependent, three-dimensional NLTE models for accurate arc discharge simulations. [83]…”
Section: Free Burning Arcmentioning
confidence: 99%