Sergey B. Leonov scite author profile

The main focus of the review is on dynamics and kinetics of near-surface discharge plasmas, such as surface dielectric barrier discharges sustained by AC and repetitively pulsed waveforms, pulsed DC discharges, and quasi-DC discharges, generated in quiescent air and in the airflow. A number of technical issues related to plasma flow control applications are discussed in detail, including discharge development via surface ionization waves, charge transport and accumulation on dielectric surface, discharge contraction, different types of flow perturbations generated by surface discharges, and effect of high-speed flow on discharge dynamics. In the first part of the manuscript, plasma morphology and results of electrical and optical emission spectroscopy measurements are discussed. Particular attention is paid to dynamics of surface charge accumulation and dissipation, both in diffuse discharges and during development of ionization instabilities resulting in discharge contraction. Contraction leads to significant increase of both the surface area of charge accumulation and the energy coupled to the plasma. The use of alternating polarity pulse waveforms accelerates contraction of surface dielectric barrier discharges and formation of filamentary plasmas. The second part discusses the interaction of discharge plasmas with quiescent air and the external airflow. Four major types of flow perturbations have been identified: (1) low-speed near-surface jets generated by electrohydrodynamic interaction (ion wind); (2) spanwise and streamwise vortices formed by both electrohydrodynamic and thermal effects; (3) weak shock waves produced by rapid heating in pulsed discharges on sub-microsecond time scale; and (4) nearsurface localized stochastic perturbations, on sub-millisecond time, detected only recently. The mechanism of plasma-flow interaction remains not fully understood, especially in filamentary surface dielectric barrier discharges. Localized quasi-DC surface discharges sustained in a high-speed flow are discussed in the third part of the review. Although dynamics of this type of the discharge is highly transient, due to its strong interaction with the flow, the resultant flow structure is stationary, including the oblique shock and the flow separation region downstream of the discharge. The oblique shock is attached to a time-averaged, wedge-shaped, near-wall plasma layer, with the shock angle controlled by the discharge power, which makes possible changing the flow structure and parameters in a controlled way. Finally, unresolved and openended issues are discussed in the summary.

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Dynamics of energy coupling and thermalization in barrier discharges over dielectric and weakly conducting surfaces onµs to ms time scales

Leonov¹,

Petrishchev²,

Adamovich³

2014

J. Phys. D: Appl. Phys.

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Near-Surface Electrical Discharge in Supersonic Airflow: Properties and Flow Control

Leonov

Yarantsev

2008

Journal of Propulsion and Power

152

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Plasma-induced ignition and plasma-assisted combustion in high-speed flow

Leonov

Yarantsev

2006

Plasma Sources Sci. Technol.

119

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The suitability of the electrical discharge technique for application in plasma-induced ignition and plasma-assisted combustion in high-speed flow is reviewed. Nonequilibrium, unsteady and nonuniform modes are under analysis to demonstrate the advantage of such a technique over heating. A reduction in the required power deposition is possible due to unsteady operation and non-homogeneous spatial distribution. Mixing intensification in non-premixed flow could be achieved by nonuniform electrical discharges. The scheme of fuel ignition behind the wallstep and in the cavity is under consideration. Experimental results on multi-electrode discharge maintenance in the separation zone of supersonic flow are presented. The model test on hydrogen and ethylene ignition is demonstrated at direct fuel injection. An energetic threshold of fuel ignition under separation and in the shear layer is measured under the experimental conditions.

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Mechanisms of Flow Control by Near-Surface Electrical Discharge Generation

Leonov

Yarantsev

Gromov³

et al. 2005

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Sergey B. Leonov

Dynamics of near-surface electric discharges and mechanisms of their interaction with the airflow

Dynamics of energy coupling and thermalization in barrier discharges over dielectric and weakly conducting surfaces onµs to ms time scales

Near-Surface Electrical Discharge in Supersonic Airflow: Properties and Flow Control

Plasma-induced ignition and plasma-assisted combustion in high-speed flow

Mechanisms of Flow Control by Near-Surface Electrical Discharge Generation

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