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

Li, Xuechen; Kang, Pengcheng; Gao, Kun; Zhou, Shuai; Wu, Kaiyue; Jia, Pengying

doi:10.1002/ppap.201900223

“…The spectra mainly include the second positive system of N 2 (C 3 Π u →B 3 Π g ), [29][30][31]48,49] where the dominant emission band heads at 337.1 nm, the first positive system of N 2 (B 3 ∏ g → A 3 ∑ + u ), [50][51][52] the first negative system of N + 2 (B 2 ∑ + g −X 2 ∑ + g ), [32,53,54] and OH transition (A 2 Σ + →X 2 Π). [33,55,56] Furthermore, the spectral line of O I (3p 5 P→3s 5 S) can also be discerned at 777.4 nm. [44] Hence, one can deduce that the active species in the plasma include electrons, positive ions (N +…”

Section: Resultsmentioning

confidence: 90%

Efficient hydrophilicity improvement of titanium surface by plasma jet in micro-hollow cathode discharge geometry

Jia

¹

,

JIA

²

,

RAN

³

et al. 2023

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The surface hydrophilicity improvement of titanium (Ti) has significant implications to the applications of the important biomaterial. In this paper, efficient hydrophilicity improvement is realized on the Ti surface by an air plasma jet in a micro- hollow cathode discharge (MHCD) geometry. Elementary discharge aspects of the plasma jet and surface characteristics of the Ti surface have been investigated with varying dissipated power (P d ). Results show that the plasma jet operates in a pulsed mode or a continuous mode depending on P d . The plume length increases with increasing P d and air flow rate. By optical emission spectroscopy, plasma parameters are investigated as functions of P d . After plasma treatment, water contact angel (WCA) of the Ti sample decreases until it reaches a minimum of 15° with increasing P d . In addition, surface topography, roughness, and content of chemical compositions are investigated by scanning electron microscopy (SEM), atomic force microscopy (AFM), and X-ray photoelectron spectroscopy (XPS) with increasing P d . It is revealed that Ti-O bond and O-H group on the Ti surface are favorable for the improvement of Ti surface hydrophilicity.

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“…For the snake-like plume, the length dependence can be explained by the same reason reported by Xian et al [75] Let us consider the dark plasma channel behind the streamer head, in which negative oxygen ions are formed due to electron attachment. [76][77][78] With increasing Q, fewer electrons are attached due to C O decrease, resulting in a higher conductivity of the plasma channel and a lower potential drop along the channel. Therefore, the potential drop of the streamer head increases, which will direct the streamer to propagate a longer distance.…”

Section: Methodsmentioning

confidence: 99%

Discharge aspects of a snake‐like plasma plume generated by an atmospheric pressure plasma jet with variable argon flow rate

Wu

¹

,

Li

²

,

Ran

³

et al. 2023

Plasma Processes & Polymers

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Plasma plume morphology, related to streamer behavior and active‐species distribution of plasma jets, is important for fixed‐point and precise treatment of workpieces. For a peculiar snake‐like plume, discharge aspects are investigated with varying argon flow rate (Q) in this paper. Results indicate that the plume length and distance between two neighboring peaks of the snake‐like plume increase with increasing Q. Fast photography indicates that the snake‐like plume is composed of positive streamers propagating along a reproducible serpentine trajectory, which occurs once per voltage cycle. Based on optical emission spectroscopy, electron temperature, electron density, and vibrational temperature are investigated with varying Q. All these phenomena are qualitatively analyzed finally.

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“…Atmospheric gas-phase discharges can be operated with a large gap spacing over the liquid electrolyte surface. Various self-organized emission patterns have also been formed using an electrolyte anode [8][9][10][11][12]. The formation of discharge emission patterns over the liquid surface is a crucial phenomenon that must be studied in order to explore the discharge operating mechanisms that are relevant when the liquid is an electrode.…”

Section: Introductionmentioning

confidence: 99%

“…Formation of ring-like, double ring-like, cone-shaped, and other patterns from AC-and DC-driven discharges over the liquid (deionized water (DIW) or tap water or electrolyte solution) surface has been examined by increasing current magnitudes and discharge power levels just after discharge initiation [8][9][10][11][12]. In atmospheric pressure plasma generated by an AC power supply, self-organized patterns such as ringlike, plasma-spot etc were observed over the liquid-electrode (tap water (500 μS cm −1 ) or DIW (0.055 μS cm −1 )) surface by varying experimental parameters such as power, gap spacing and liquid properties of the electrode [11].…”

Section: Introductionmentioning

confidence: 99%

“…In atmospheric pressure plasma generated by an AC power supply, self-organized patterns such as ringlike, plasma-spot etc were observed over the liquid-electrode (tap water (500 μS cm −1 ) or DIW (0.055 μS cm −1 )) surface by varying experimental parameters such as power, gap spacing and liquid properties of the electrode [11]. Selforganized patterns such as diffuse disk, single ring etc above the tap water (400 μS cm −1 ) anode were witnessed as a function of gap spacing and discharge current of an argon atmospheric pressure glow discharge driven by a DC power supply [12]. Filamentary streamers from direct-in-liquid discharges excited using DC power have been observed in liquids (DIW and solution) [17].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Spatio-temporal evolution characteristics and pattern formation of a gas–liquid interfacial AC current argon discharge plasma with a deionized water electrode

Qazi¹,

Khan²,

Huang³

2021

Plasma Sci. Technol.

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A discharge ignited by an AC power source in contact with deionized water as one of the electrodes is investigated. Immediately after initiation, the discharge exhibits a unique phenomenon: the gas-phase discharge is extended into the liquid. Later, a cone-like structure is observed at the liquid surface. Synchronous monitoring of current–voltage characteristics and liquid properties versus time suggests that the discharge shapes are functions of the liquid properties. The spatio-temporal profiles indicate the potential effects of water, ambient air impurities, and metastable argon on the discharge chemistry. This becomes more obvious near the liquid surface due to increasing production of various transient reactive species such as ·OH and NO·. Moreover, it is revealed that thermalization of the rotational population distributions of the rotational states ( N ′ ≤ 6 , J ′ ≤ 13 / 2 ) in the Q 1 branch of the OH A Σ + 2 , υ ′ = 0 → X Π 3 / 2 2 , υ ″ = 0 band ro-vibrational system is influenced by the humid environment near the liquid surface. In addition, the transient behaviors of instantaneous concentrations of long-lived reactive species (LRS) such as H2O2, NO 2 − , and NO 3 − are observed with lengthening the discharge time. The production of multiple transient and LRS proposes AC excited gas–liquid argon discharge as a potential applicant in industrial wastewater cleaning, clinical medicine, and agriculture.

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

Cited by 15 publications

References 29 publications

Efficient hydrophilicity improvement of titanium surface by plasma jet in micro-hollow cathode discharge geometry

Efficient hydrophilicity improvement of titanium surface by plasma jet in micro-hollow cathode discharge geometry

Discharge aspects of a snake‐like plasma plume generated by an atmospheric pressure plasma jet with variable argon flow rate

Spatio-temporal evolution characteristics and pattern formation of a gas–liquid interfacial AC current argon discharge plasma with a deionized water electrode

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