Energy deposition for high-speed flow control / Doyle D. Knight (Rutgers, the State University of New Jersey).
Material type: TextSeries: Cambridge aerospace series ; 47.Publisher: Cambridge ; New York, NY : Cambridge University Press, 2019Description: 1 online resourceContent type:- text
- computer
- online resource
- 9781108605519
- 1108605516
- 9781316389331 (ebook)
- 1316389332 (ebook)
- 533/.62 23
- QA930 .K5875 2019eb
Includes bibliographical references and indexes.
Print version record.
Cover; Half-title; Series information; Title page; Copyright information; Dedication; Contents; Preface; 1 Introduction; 1.1 Background; 1.2 Overview of the Book; 2 Fundamental Equations; 2.1 Overview; 2.2 Conservation of Mass; 2.3 Conservation of Momentum; 2.4 Conservation of Energy; 2.5 Second Law of Thermodynamics; 2.6 Maxwell's Equations; 2.7 Schr[ddot(o)]dinger's Equation; 2.8 Liouville's Equation and Theorem; Problems; 3 Statistical Mechanics and Continuum Physics; 3.1 Overview; 3.2 An Equilibrium Probability Density Function; 3.3 Bogoliubov-Born-Green-Kirkwood-Yvon Equations
3.4 Boltzmann Equation3.5 Collision Cross-Sections; 3.6 Boltzmann's H-Theorem; 3.7 Maxwell-Boltzmann Distribution; 3.8 Boltzmann's Equations for a Gas Mixture; 3.9 Equations of Continuum Gas Dynamics; 3.10 Chapman-Enskog Method; Problems; 4 Dynamics and Kinetics of Charged Particles; 4.1 Introduction; 4.2 Debye Length; 4.3 Sheath; 4.4 Isolated Ions; 4.5 Collision Frequency; 4.6 Mean Free Path; 4.7 Elastic Collisions; 4.8 Ionic Drift Velocity and Mobility in DC Electric Field; 4.9 Current and Conductivity in DC Electric Field; 4.10 Diffusion; 4.11 Ambipolar Diffusion
4.12 Thermochemical ReactionsProblems; 5 DC Discharge; 5.1 Introduction; 5.2 Townsend Regime; 5.3 Corona Regime; 5.4 Glow Discharge; 5.5 Streamer Discharge; 5.6 Spark Discharge; 5.7 Arc Discharge; Problems; 6 Microwave Discharge; 6.1 Introduction; 6.2 Microwave Theory; 6.3 Microwave Waveguides; 6.4 Microwave Discharge in Free Space; 6.5 Microwave Breakdown; 6.6 Simulations of Microwave Discharge; 6.7 Thermochemistry of Microwave Discharge; Problems; 7 Laser Discharge; 7.1 Introduction; 7.2 Laser Theory; 7.3 Laser Discharge; 7.4 Post-Discharge Flow Structure
7.5 Conditions for Breakdown in Air7.6 Models for Breakdown; 7.7 Fraction of Laser Energy Deposited in Air; 7.8 Simulation of Laser Discharge in Air; 7.9 Continuous Laser Discharge; Problems; 8 Modeling Energy Deposition as an Ideal Gas; 8.1 Introduction; 8.2 Governing Equations; 8.3 Dimensionless Parameters; 8.4 One-Dimensional Steady Energy Deposition; 8.5 Linearized Analysis for Steady Flow; 8.6 Belokon et al. (1977); 8.7 Krasnobaev and Syunyaev (1983); 8.8 Krasnobaev (1984); 8.9 Artem'ev et al. (1988); 8.10 Vlasov et al. (1995); 8.11 Georgievsky et al. (2010); 8.12 Additional References
Problems9 Flow Control in Aerodynamics; 9.1 Introduction; 9.2 Artem'ev et al. (1989); 9.3 Myrabo and Raizer (1994); 9.4 Tretyakov et al. (1996); 9.5 Bracken et al. (2001a,b,c); 9.6 Girgis et al. (2002); 9.7 Johns Hopkins University Applied Physics Laboratory (2003-2013); 9.8 Lashkov et al. (2004); 9.9 Kandala and Candler (2004); 9.10 Adelgren et al. (2005); 9.11 Kremeyer et al. (2006); 9.12 Zheltovodov et al. (2007); 9.13 Gnemmi et al. (2008); 9.14 Yan and Gaitonde (2008); 9.15 Caruana et al. (2009) and Hardy et al. (2010); 9.16 Georgievsky and Levin (2009); 9.17 Knight et al. (2009)
Describes energy deposition using direct current (DC), microwave and laser discharge for flow control at high speeds.
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