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51. Electrohydrodynamic force and scaling laws in surface dielectric barrier discharges

Author

Lagmich, Youssef, Callegari, Thierry, Unfer, Thomas, Pitchford, Leanne C., Boeuf, Jean-Pierre, and Pagès, Nathalie

Subjects
[SPI] Engineering Sciences [physics], Corona, Plasma simulation, Electrohydrodynamics
Abstract

The electrohydrodynamic force generated by surface dielectric barrier discharges is analyzed with a fluid mode under conditions where the electrode above the dielectric surface is the anode.. The calculated current is composed of successive large pulses associated with filamentary discharges spreading along the dielectric surface, separated by low current periods where the discharge is in a transient ``coronalike'' regime. The contribution of the corona discharges to the overall force is by far dominant. An important result is that the extension of the region above the surface where the electrohydrodynamic force is significant depends on the product of the dielectric layer capacitance and the rate of voltage increase (spatial extension is larger when this parameter is smaller), but that the total, integrated force is not very sensitive to these parameters.

Published
2007

53. Electrohydrodynamic Force in Dielectric Barrier Discharge Plasma Actuators

Author

Boeuf, Jean-Pierre, Lagmich, Youssef, Unfer, Thomas, Callegari, Thierry, Pitchford, Leanne C., and Pagès, Nathalie

Subjects
[SPI] Engineering Sciences [physics]
Abstract

Surface dielectric barrier discharges (DBDs) have been proposed as actuators for flow control. In this paper we discuss the basic mechanisms responsible for the electrohydrodynamic (EHD) force exerted by the discharge on the gas molecules. A two-dimensional fluid model of the DBD is used to describe the plasma dynamics, to understand the basic physics associated with the EHD force and to give some quantitative estimation of the force under simplified conditions. The results show that for ramp or sinusoidal voltage waveforms, the discharge consists of large amplitude short current pulses during which a filamentary plasma spreads along the surface, separated in time by long duration, low current discharge phases of a Townsend or corona type. The contribution of the low current phases to the total force exerted by the discharge on the gas is dominant because their duration is much longer than that of the current pulses and because the force takes place in a much larger volume. A description of the different discharge regimes and a parametric study of the EHD force as a function of voltage rise time and dielectric thickness is presented.

Published
2007

54. Measurement of the Surface Charge in a Dielectric Barrier Discharge Using an Electro-Optic Crystal

Author

Gegot, F., Callegari, Thierry, Aillerie, M., Galy, Jean, Boeuf, Jean-Pierre, Laboratoire Matériaux Optiques, Photonique et Systèmes (LMOPS), Université de Lorraine (UL)-CentraleSupélec, Salvestrini, Jean Paul, and CentraleSupélec-Université de Lorraine (UL)

Subjects
[PHYS.PHYS.PHYS-OPTICS] Physics [physics]/Physics [physics]/Optics [physics.optics], [PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics]
Published
2006

55. Electro-Optic Measurement of the Surface Charge in a Dielectric Barrier Discharge

Author

Gegot, F., Callegari, Thierry, Aillerie, M., Galy, Jean, Boeuf, Jean-Pierre, Laboratoire Matériaux Optiques, Photonique et Systèmes (LMOPS), CentraleSupélec-Université de Lorraine (UL), Salvestrini, Jean Paul, and Université de Lorraine (UL)-CentraleSupélec

Subjects
[PHYS.PHYS.PHYS-OPTICS] Physics [physics]/Physics [physics]/Optics [physics.optics], [PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics], ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2006

57. Absorbtion et dissipation d'énergie dans un plasma hors équilibre

Author

Boeuf, Jean-Pierre, Centre de Physique des Plasmas de Toulouse (CPAT), Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS), Massines, Françoise, and Mottin, Stéphane

Subjects
[PHYS]Physics [physics], [PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics], [SPI.PLASMA]Engineering Sciences [physics]/Plasmas, Spectroscopie de masse, Spectrométrie de masse, Optique ― Actes de congrès, diagnostics laser, [SPI.MAT]Engineering Sciences [physics]/Materials, [SDV.BBM.BP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biophysics, diagnostics plasmas, Plasmas froids ― Applications industrielles, Plasmas froids ― Congrès, [PHYS.COND]Physics [physics]/Condensed Matter [cond-mat], Technologie des réacteurs à plasmas
Abstract

International audience; P. 9. Préface / Alix GicquelP. 11. Introduction : le réseau Plasmas froids et la Mission des Ressources et Compétences Technologiques du CNRS / Gérard Lelièvre, Françoise Massines et Elodie Girard I - Génération et dissipation d'énergie P. 17. I-1. Absorbtion et dissipation d'énergie dans un plasma hors équilibre / J.-P. Bœuf P. 49. I-2. Plasmas hors-équilibre à des pressions atmosphériques / K. Hassouni, F. Massines, J.-M. Pouvesle P. 109. I-3. Les plasmas thermiques / A. Gleizes II - Accès aux caractéristiques et aux espèces du plasma P. 141. II-1. Le plasma d'arc dans le procédé de projection thermique / J.-F. Couderc P. 159. II-2. Mesures de sondes électrostatiques en plasma basse pression / S. Béchu P. 225. II-3. Diagnostics laser et spectroscopie de masse dans les plasmas réactifs / J. Jolly P. 255. II-4. Saturation optique et autres pièges en spectroscopie laser / N. Sadeghi P. 275. II-5. Pièges en spectroscopie de masse / A. Granier P. 297. II-6. Source d'ionisation par micro pointes pour la spectroscopie de masse spatiale / F. Cipriani, J.-M. Illiano, J.-J. Berthelier III - Technologie des réacteurs à plasmas P. 323. III-1. Plasmas micro-onde basses pressions excités à la résonance cyclotronique électronique / Y. Arnal P. 353. III-2. Technologie des réacteur à plasma: Dimensionnement des réacteurs à Plasma micro-onde haute pression / F. Sylva, G. Hagelaar, K. Hassouni, A. Gicquel P. 367. III-3. Technologie des réacteurs à plasmas: Plasmas inductifs et capacitifs en basse pression / Ph. Lefaucheux P. 391. III-4. Les Plasmas thermique / C. Verdy, R. Boblot, H. Deng, P. Gougeon, C. Coddet

Published
2004

61. Studies of the Electrohydrodynamic Force Produced in a Dielectric Barrier Discharge for Flow Control. Report no. 2, Phase 3

Author

UNIVERSITE PAUL SABATIER TOULOUSE (FRANCE), Boeuf, Jean-Pierre, Unfer, T., Pitchford, L., UNIVERSITE PAUL SABATIER TOULOUSE (FRANCE), Boeuf, Jean-Pierre, Unfer, T., and Pitchford, L.

Abstract

The mechanisms of ion wind generation in surface dielectric barrier discharges (SDBDs) is identical to the one in corona discharges. The electrohydrodynamic force (EHD) generated in SDBDs for moderate increase rates of the applied voltage is, as in corona discharges, due to the development of a unipolar region above the dielectric surface, where ion space charge is dominant and ions transfer momentum to the neutral gas. For very fast rise (few ns) of the applied voltage, ion wind is no longer important and the action of the discharge on the flow is different. SDBDs are more interesting for applications than DC corona because high current breakdown and transition to the arc regime are prevented by the use of a dielectric layer. There is no evidence that SDBDs can generate larger ion wind than DC corona discharges. For a given power dissipated in the discharge, the EHD force decreases when the frequency increases. This trend is also valid for other voltage waveforms. The nanosecond discharge regime has been simulated and its possible aerodynamic effects have been studied by coupling the discharge model with Navier Stokes equations. The results confirm that the EHD force generated in the nanosecond regime is negligible and show that the fast heating of the gas in the vicinity of the exposed electrode can lead to a large temperature increase in a short time, giving rise to the development of micro shockwaves. These pressure waves may be responsible for the observed aerodynamic effects., The original document contains color images.

Published
2010

64. Propagating double layers in electronegative plasmas

Author

Meige, Albert, Plihon, N., Hagelaar, Gerjan, Boeuf, Jean-Pierre, Chabert, Pascal, Boswell, Roderick, Meige, Albert, Plihon, N., Hagelaar, Gerjan, Boeuf, Jean-Pierre, Chabert, Pascal, and Boswell, Roderick

Abstract

Double layers have been observed to propagate from the source region to the diffusion chamber of a helicon-type reactor filled up with a low-pressure mixture of Ar SF6 [N. Plihon, J. Appl. Phys. 98, 023306 (2005)]. In the present paper the most significant and new experimental results are reported. A fully self-consistent hybrid model in which the electron energy distribution function, the electron temperature, and the various source terms are calculated is developed to investigate these propagating double layers. The spontaneous formation of propagating double layers is only observed in the simulation for system in which the localized inductive heating is combined with small diameter chambers. The conditions of formation and the properties of the propagating double layers observed in the simulation are in good agreement with that of the experiment. By correlating the results of the experiment and the simulation, a formation mechanism compatible with ion two-stream instability is proposed.

Published
2007

65. Microdischarge Sources of O2(singlet Delta)

Author

CENTRE DE PHYSIQUE DES PLASMAS ET DE LEURS APPLICATIONS DE TOULOUSE (CPAT) (FRANCE), Pitchford, Leanne C., Boeuf, Jean-Pierre, Puech, Vincent, Rousseau, Antoine, CENTRE DE PHYSIQUE DES PLASMAS ET DE LEURS APPLICATIONS DE TOULOUSE (CPAT) (FRANCE), Pitchford, Leanne C., Boeuf, Jean-Pierre, Puech, Vincent, and Rousseau, Antoine

Abstract

The focus was to obtain yield measurements in DC microdischarges but there will also be an important modeling component conducted in parallel with the experiments. The existing MHCD model was developed for rare gases, and this will be extended to include a description of the O2 kinetics based on previously published work. A particularly important parameter is the gas temperature and the gas heating source term in the model also needs to be extended to include V-T (vibrational to translation) energy exchange ion heating in the sheath (expected to be the dominant component) is included in our present model). We originally proposed measuring the O2(1D) yield using IR absorption spectroscopy and we still feel that it will eventually be necessary to develop this or another or the more traditional spectroscopic methods (eg CARS or UV absorption). However, during the proof-of-principle phase of this project we propose using an isothermal calorimeter as has been developed previously for measurements of O2(1D) yields by several groups 7.8. We have been in contact with Dr, Ikonnikov and he has kindly provided us with additional information on the set-up of Lodin et a17. This calorimetric technique is, in our opinion the best way to obtain a quick inexpensive and accurate estimate of the O2(1D) yield in a single microdiecharge operating in a DC mode, The experimental set-up is simple a nickel coil is positioned in the gas flow on the downstream side of the microdischarge and the chemical energy in the gas flow is detected as a change in the external power required to maintain the coil at a constant temperature (eg 150 degrees C). This power is reduced when O2(1D) is deactivated at the coil surface. The Russian group7 used a self-balancing bridge circuit to maintain the constant temperature and they calibrated their system by measuring the O2(1D) emission signal before and after the detector. They determined that between 70 and 90% of the O2(1D) reacted with the nickel coil., The original document contains color images.

Published
2006

66. The 2012 Plasma Roadmap

Author

Samukawa, Seiji, primary, Hori, Masaru, additional, Rauf, Shahid, additional, Tachibana, Kunihide, additional, Bruggeman, Peter, additional, Kroesen, Gerrit, additional, Whitehead, J Christopher, additional, Murphy, Anthony B, additional, Gutsol, Alexander F, additional, Starikovskaia, Svetlana, additional, Kortshagen, Uwe, additional, Boeuf, Jean-Pierre, additional, Sommerer, Timothy J, additional, Kushner, Mark J, additional, Czarnetzki, Uwe, additional, and Mason, Nigel, additional

Published
2012
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67. Modeling High Pressure Micro Hollow Cathode Discharges

Author

CENTRE DE PHYSIQUE DES PLASMAS ET DE LEURS APPLICATIONS DE TOULOUSE (CPAT) (FRANCE), Boeuf, Jean-Pierre, Pitchford, Leanne, CENTRE DE PHYSIQUE DES PLASMAS ET DE LEURS APPLICATIONS DE TOULOUSE (CPAT) (FRANCE), Boeuf, Jean-Pierre, and Pitchford, Leanne

Abstract

This report results from a contract tasking CPAT as follows: The Grantee will perform theoretical modeling of point, surface, and volume high-pressure plasmas created using Micro Hollow Cathode Discharge sources. The primary goal is to better understand the fundamental physics of these discharges in order to optimize operating conditions and develop more efficient devices., Grant 033083, Universite Paul Sabatier, Toulouse, France. Annex 1: Mid-term grant rept. Annex 2: Journal article to appear in Appl Phys Lett. Annex 3: Journal article to appear in IEEE Trans Plasma Sci special issue on Images in Plasma Science. Annex 4: Conference paper to appear in the Proceedings of the Gas Disch Conf, 2005. The original document contains color images.

Published
2004

78. Proceedings of NATO Advanced Research Workshop on the Formation, Transport and Consequences of Particles in Plasmas Held in Castera-Verduzan, France on 30 August-3 September 1993

Author

TOULOUSE-3 UNIV (FRANCE), Boeuf, Jean-Pierre, TOULOUSE-3 UNIV (FRANCE), and Boeuf, Jean-Pierre

Abstract

A review is presented of the phenomena associated with particles in low pressure plasmas. Dust particles which are typically micrometers in diameter have been observed by laser light scattering in various low-pressure, radiofrequency-excited plasmas. Experiments have been designed so that the origin of the dust material is unambiguous and, to some extent, quantitative. The processes involved in the appearance of the microscopic dust particles are outlined and compared with our experimental observations. The source material and its required generation rate, nucleation, charging, growth mechanisms, growth rates, and saturation mechanisms are discussed. The mutual influences of dust and plasma, particularly the role of geometric and circuit boundary conditions in laboratory plasmas, are described.

Published
1993

80. Ion and neutral energy distributions to the MgO surface and sputtering rates in plasma display panel cells.

Author

Pitchford, Leanne C., Jianqi Wang, Piscitelli, David, and Boeuf, Jean-Pierre

Subjects
PLASMA displays, MAGNESIUM oxide, SPUTTERING (Physics), ELECTRIC discharges, IONS
Abstract

One of the factors limiting the lifetime of plasma display panels (PDPs) is sputtering of the MgO layer deposited on the dielectric covering the electrode. The goal of the work reported here is to evaluate the influence of different operating conditions on the sputtering rate of the MgO layer in PDPs operating with Xe/Ne mixtures. Sputtering is caused by the ions and fast neutral atoms impacting the surface. Starting with results from a fluid model, we use a Monte Carlo simulation to calculate energy distributions of the ion and fast neutrals arriving on the MgO coated surface for a set of baseline conditions. Estimates of the sputtering yield of MgO are then combined with the energy distributions to evaluate the sputtering rates for matrix and coplanar geometries. Parametric calculations in a simple geometry were performed to examine the effect of gas mixture, gas pressure, cell capacitance, and applied voltage on the sputtering rate of the MgO layer. Our main result is the prediction of longer lifetime for mixtures containing about 20%Xe for both matrix and coplanar geometries. [ABSTRACT FROM PUBLISHER]

Published
2006
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81. Appropriate use of the particle-in-cell method in low temperature plasmas: Application to the simulation of negative ion extraction

Author

Garrigues, Laurent, Fubiani, G., Boeuf, Jean-Pierre, Groupe de Recherche Energétique, Plasmas et Hors Equilibre (LAPLACE-GREPHE), LAboratoire PLasma et Conversion d'Energie (LAPLACE), Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Toulouse III - Paul Sabatier (UT3), and Université Fédérale Toulouse Midi-Pyrénées

Subjects
010302 applied physics, Chemistry, Numerical analysis, Monte Carlo method, [SPI.PLASMA]Engineering Sciences [physics]/Plasmas, General Physics and Astronomy, Context (language use), Plasma, 01 natural sciences, Neutral beam injection, 010305 fluids & plasmas, Computational physics, Ion, Physics::Plasma Physics, Mesh generation, 0103 physical sciences, Particle-in-cell, Atomic physics, ComputingMilieux_MISCELLANEOUS
Abstract

The Particle-In-Cell Monte Carlo Collision (PIC MCC) method has been used by different authors in the last ten years to describe negative ion extraction in the context of neutral beam injection for fusion. Questionable results on the intensity and profile of the extracted negative ion beamlets have been presented in several recently published papers. Using a standard explicit PIC MCC method, we show that these results are due to a non-compliance with the constraints of the numerical method (grid spacing, number of particles per cell) and to a non-physical generation of the simulated plasma. We discuss in detail the conditions of mesh convergence and plasma generation and show that the results can significantly deviate from the correct solution and lead to unphysical features when the constraints inherent to the method are not strictly fulfilled. This paper illustrates the importance of verification in any plasma simulation. Since the results presented in this paper have been obtained with careful verifica...

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82. Guest Editorial Special Issue on Plasma Display Panels.

Author

BOEUF, JEAN-PIERRE, UCHIIKE, HEIJU, and KI-WOONG WHANG

Subjects
*PLASMA displays, *PLASMA devices
Abstract

The article discusses various reports published within the issue, including one on the history of the plasma display panel (PDP), and another on the modeling of PDP microdischarges.

Published
2006
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83. Numerical modelling of plasma for flow control in aerospace applications.

Author

Konstantinos, Kourtzanidis, Rogier, Francois, and Boeuf, Jean-Pierre

Abstract

A crucial aspect for supersonic flights is the strong shock wave that forms in front of the air vehicle. By modifying the supersonic incoming flow, one can adjust this wave -which is the most contributing factor of the drag coefficient of an aircraft- and have consequently positive effects on the fuel consumption and on the noise produced by the object due to the sonic boom. Lately, plasma associated flow control actuators have been in the center of flow control research and especially of supersonic applications. [ABSTRACT FROM PUBLISHER]

Published
2012
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84. Modélisation numérique d’actionneurs plasma pour le contrôle d’écoulement

Author

KOURTZANIDIS, Konstantinos, Institut Supérieur de l'Aéronautique et de l'Espace, Boeuf, Jean-Pierre, Rogier, François, ONERA - The French Aerospace Lab [Toulouse], ONERA, Institut Supérieur de l'Aéronautique et de l'Espace (ISAE-SUPAERO), Institut Supérieur de l’Aéronautique et de l’Espace (ISAE), Jean-Pierre BOEUF, and François ROGIER

Subjects
contrôle d’écoulement, FDTD, [SPI]Engineering Sciences [physics], Plasma, Microwave discharges, Contrôle d'écoulement, JSP, PSJ, Modélisation numérique, plasma, [SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment, [SPI.PLASMA]Engineering Sciences [physics]/Plasmas, ADI-FDTD, flow control, Sparkjet, Flow control, Numérical modeling, numerical modeling, Actionneurs, modélisation numérique, sparkjet, Décharges micro-ondes, décharges micro-ondes, HPC, microwave discharges, DBD, CFD, Actuators
Abstract

Cette thèse porte sur une nouvelle approche pour le contrôle d’écoulement aérodynamique. Cette nouvelle approche est basée sur l’utilisation d’actionneurs plasma. La modélisation numérique peut être une outil puissante entre les mains des scientifiques et des ingénieurs pour comprendre, optimiser et ainsi ouvrir la voie à la commercialisation et l’application de cette technologie. Le couplage entre l’électromagnétisme, le plasma et l’écoulement, nécessite des modèles et des techniques numériques avancées. Le travail présenté dans cette thèse, a pour principaux objectifs : le développement et la validation de méthodes numériques pour simuler efficacement le fonctionnement de certains des plus importants types d’actionneurs plasma. Nous nous sommes intéressés à trois types d’actionneurs plasma : les décharges micro-ondes, la décharge à barrière diélectrique (DBD) et le jet synthétique plasma (JSP). En ce qui concerne les décharges microondes, les objectifs sont plus fondamentaux que pour les autres types d’actionneurs. Il s’est agit de mieux comprendre la création du plasma, son évolution et de calculer l’efficacité énergétique de dispositifs microondes par la simulation numérique. Un schéma couplé implicite (ADI) - FDTD avec un modèle de plasma fluide simplifié est présenté. Cette formulation conserve la simplicité et la robustesse des systèmes de FDTD, tout en dépassant la barrière du critère de stabilité CFL. Elle conduit à un temps de calcul réduit et la possibilité de réaliser des simulations tridimensionnelles de la formation du plasma et de l’évolution d’un plasma dans un champ micro-ondes. Afin d’étudier l’énergie absorbée par le plasma et le transfert vers le gaz sous forme de chaleur ainsi que le changement consécutif de la densité du gaz, un solveur Euler a été couplé avec le modèle EM-plasma en tenant compte des effets de gaz réel. Diverses validations et applications sont ensuite étudiés. Des simulations tridimensionnelles de formation du plasma sont réalisée qui montrent la formation de structures dans une décharge micro-ondes librement localisée. Les effets de chauffage de gaz sur le développement d’un "streamer" et la durée d’un volume pré-ionisé avec des champs sous-critiques sont également calculés. En ce qui concerne les deux autres groupes d’actionneurs, les objectifs de cette thèse se concentrent sur la modélisation de leur fonctionnement et sur la production d’écoulement qui en résulte. Le Jet Synthétique Plasma a été numériquement étudié par trois modèles couplés. Les résultats obtenus sont prometteurs pour l’optimisation du JSP et une meilleure compréhension des mécanismes qui limitent ses performances. L’actionneur DBD a été modélisée en utilisant deux solveurs différents basés sur des modèles physiques similaires - celui développé à l’ONERA et l’autre à LAPLACE. Des études paramétriques ont montré que les modèles donnent une estimation assez précise de la force produite par le DBD par rapport à des mesures expérimentales. Des applications aérodynamiques de contrôle d’écoulement ont démontré les effets possibles de ces actionneurs pour la transition laminaire - turbulente et l’amélioration de la portance. Ces travaux ouvrent une perspective nouvelle dans la conception et l’optimisation de ces actionneurs. As aerodynamic flow control still remains one of the top subjects of research in the aerospace scientific world, new ways to perform such a control are being constantly studied. Microwave plasma discharges have been proposed as a mean of a non-intrusive flow control method based on the creation of hot spots of air (via the creation of plasma discharges) which can eventually interact with the external flow and modify its attributes in a beneficial way to the aerodynamic coefficients of the body of interest. Moreover, other types of plasma actuators, based on the momentum addition in the flow instead of heat, have been proven capable of positively modifying the flow aerodynamic features. Nevertheless, the development and optimization of such actuators, require further understanding of the basic multi-scale physics involved. Experiments can provide such information, but they turn to be costly and incapable of capturing the complex interactions in small space and time scales. In this thesis, we are interested in the numerical modeling of plasma flow control actuators, in order to understand deeper their nature and applicability. Firstly, we present the theory behind aerodynamic flow control and plasma physics along with a literature review of the plasma actuators’ physics, applicability and effects. Then, numerical simulations performed using adapted techniques for each different actuator, reveal interesting features of their physics and complex nature, on the way to a deeper understanding and possible optimization of their performance in aerodynamic flow control applications. Three types of plasma actuators are considered: Microwave Plasma Discharges (MPD), the Dielectric Barrier Discharge (DBD) and the Plasma Synthetic Jet (PSJ). Concerning microwave discharges, the objectives are more fundamental than the other types of actuators. Numerical simulations can provide the basic information on the physics and complex interaction between the EM waves the plasma and the gas, in order to understand the plasma creation, evolution and energy balance. Flow control applications of such discharges, as an energy deposition method, have been already quite well documented in the literature. In order to reduce the computational cost, a novel implicit coupling of the Maxwell equations with the momentum transfer equation for electrons has been developed which with the addition of a simplified model of plasma-fluid equations have enabled three-dimensional simulations in time domain. The microwave breakdown and evolution of the plasma due to the electromagnetic waves has been studied numerically, in order to quantify the energy absorbed by the plasma and transferred to neutral molecules as gas heating. Coupling of the EM-plasma model with an Euler based solver accounting for real gas effects, have revealed interesting features of the complex interaction between the plasma itself and the pressure shock waves formed due to the intense gas heating during the plasma breakdown and evolution. Concerning the two other groups of actuators, the goals of this thesis is more applied as we are interested mostly on modeling their operation and consequent momentum production. For the PSJ actuator, the numerical solver consists of three coupled numerical models: One describing the plasma formation between both electrodes in an axisymmetrical configuration, one describing the electrical supply by an external generator, and a last one that focuses on the air’s heating in the cylindrical cavity where the plasma is formed, and the actual operation of the actuator. It uses the energy distribution computed by the first sub-model as source term and calculates the jet’s flow mass rate, momentum and energy, exiting the cavity at high speeds. An external CFD solver is used to integrate the calculated momentum source term into a global model of a flat plate flow, taking into account turbulent effects. Lastly, the DBD actuator model, developed in DTIM/ONERA, Toulouse, consists of solving the momentum equations for a set of simplified species and the Poisson’s equation. The calculated body force produced by the DBD actuator is being compared with experimental results and the induced wall-jet flow due to this force is modeled in a CFD solver. A similar model developed in LAPLACE/UPS has been used to perform parametric studies on the influence of turbulence - studying different turbulent models in a RANS approach - as well as more applied simulations for flow control purposes, including laminar-turbulent transition over a flat plate and lift coefficient modification on an airfoil due to a leading edge DBD actuator. These studies offer new perspectives in the understanding and the optimization of plasma actuators for flow control purposes.

Published
2014

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