Electrodynamics of conducting dispersive media

This book presents a sequential representation of the electrodynamics of conducting media with dispersion. In addition to the general electrodynamic formalism, specific media such as classical nondegenerate plasma, degenerate metal plasma, magnetoactive anisotropic plasma, atomic hydrogen gas, semiconductors, and molecular crystals are considered. The book draws on such classics as Electrodynamics of plasma and plasma-like media (Silin and Rukhadze) and Principles of Plasma Electrodynamics (Alexandrov, Bogdankevich, and Rukhadze), yet its outlook is thoroughly modern-both in content and presentation, including both classical and quantum approaches. It explores such recent topics as surface waves on thin layers of plasma and non-dispersive media, the permittivity of a monatomic gas with spatial dispersion, and current-driven instabilities in plasma, among many others. Each chapter is equipped with a large number of problems with solutions that have academic and practical importance. This book will appeal to graduate students as well as researchers and other professionals due to its straight-forward yet thorough treatment of electrodynamics in conducting dispersive media.

• Chapter One Principles of Electrodynamics of Media with Spatial Dispersion 1.1. Equations of Electromagnetic Fields 1.2. Tensor of Complex Dielectric Permittivity 1.3. Dispersion of Dielectric Permittivity 1.4. Energy of the Electromagnetic Fields in a Medium 1.5. Electromagnetic Waves in a Medium 1.6. Plane Monochromatic Waves in a Medium 1.7. Electromagnetic Wave Propagation in a Weakly Spatial Dispersive Medium 1.8. Energy Loss of Fast Moving Electrons in the Medium 1.9. Electromagnetic Field Fluctuations 1.9.1. Correlation functions and general analysis 1.9.2. Electromagnetic field fluctuations in homogenous isotropic non-grotropic media 1.9.3. Casualty principle and generalization of Kramers-Kronig relations. 1.10. Electromagnetic Properties of Inhomogeneous Plasmas 1.10.1. Inhomogeneous media without spatial dispersion. Approximation of geometrical optics. 1.10.1.1. Field equation for an inhomogeneous medium without spatial dispersion 1.10.1.2. The method of geometrical optics and the WKB method 1.10.1.3. The Bohr-Sommerfeld quasi classical quantization rules 1.10.2. Approximation of geometrical optics for inhomogeneous media with spatial dispersion 1.10.2.1. Eikonal equation for inhomogeneous medium with spatial dispersion 1.10.2.2. Quantization rules 1.11. Problems Chapter Two Isotropic Plasma 2.1. Kinetic Equation with Self-consistent Fields 2.2. Dielectric Permittivity of Collisionless Isotropic Plasma 2.3. Dielectric Permittivity and Electromagnetic Oscillations of Isotropic Collisionless Nonrelativistic Electron Plasma 2.4. Dielectric Permittivity and Electromagnetic Oscillations of Relativistic Collisionless Electron Plasma 2.5. Oscillations of Isotropic Electron-Ion Plasma 2.6. Hydrodynamics of Collisionless Plasma 2.7. Dielectric Permittivity of Plasma
• Taking account of Particle Collisions 2.8. Boundary Problem of Fields in Plasma 2.9. Reflection and absorption of electromagnetic Waves in Semi-bounded Plasma 2.10. Linear Electromagnetic Phenomena in Bounded Plasmas 2.10.1. Surface electromagnetic waves in semi-bounded plasmas 2.10.1.1. Solution of the Vlasov equation for the semi-bounded isotropic plasma 2.10.1.2. Solution of field equations 2.10.1.3. Surface impedance 2.10.1.4. Dispersion equation for surface waves 2.10.1.5. Surface waves in cold semi-bounded plasma 2.10.1.6. Cherenkov damping of surface waves 2.10.1.7. Surface ion-acoustic waves 2.10.2. Surface waves on plasma layers 2.10.2.1. Potential surface waves on thin layers of non-dispersive media 2.10.2.2. Surface waves on thin layers of dispersive media 2.11. Problems Chapter Three Anisotropic Plasma 3.1. Dielectric permittivity of collisionless plasma in a constant magnetic field 3.2. Electromagnetic Oscillations of Non-relativistic Plasma in a Constant Magnetic Field 3.3. Relativistic Electron Plasma in the Magnetic Field 3.4. Electron-Ion Plasma in the External Magnetic Field 3.5. Particle Collisions in Magneto-Active Plasma 3.6. Magnetohydrodynamics of Collisionless Plasma 3.7. Interaction of Straight Neutralized Beams of Charged Particles with Plasma 3.7.1. Interaction of a Straight Monoenergetic Electron Beam with Cold Plasma: (Cherenkov Instability) 3.7.2. Effect of Thermal Motion on the Cherenkov Instability 3.7.3. Current-Driven Instabilities in Plasma: Bunemann Instability 3.7.4. Current-Driven Instabilities in Plasma: Ion-Acoustic Instability 3.8. Dielectric Tensor of Weakly Inhomogeneous Magnetized Plasmas in the Approximation of Geometrical Optics 3.8.1. Distribution function for equilibrium inhomogeneous plasma 3.8.2. Magnetic confinement of inhomogeneous plasma 3.8.3. Dielectric tensor of weakly inhomogeneous magnetized plasma 3.8.4. Larmor drift frequency 3.9. Spectra of HF and Larmor Oscillations in Weakly Inhomogeneous Plasmas 3.9.1. Transverse oscillations of weakly inhomogeneous isotropic plasma 3.9.2. Langmuir Oscillations. Tonks-Dattner resonances 3.9.3. Ion-Acoustic oscillations of inhomogeneous isotropic plasma 3.9.4. Oscillations of weakly inhomogeneous magneto-active plasma 3.9.5. Drift oscillations of weakly inhomogeneous collisionless plasma 3.9.5.1. Larmor drift in inhomogeneous plasma 3.9.5.2. Dispersion equation for drift oscillations 3.9.5.3. Spectra of fast long-wavelength drift oscillations 3.9.5.4. Universal instability of inhomogeneous plasma 3.9.5.5. Spectra of slow long-wavelength drift oscillations 3.9.5.6. Drift-dissipative and drift-temperature instabilities 3.10. Instability of the Boundary of Magnetically Confined Plasma 3.10.1. Poisson's equation for the magnetically confined inhomogeneous plasma 3.10.2. Surface oscillations of cold magneto-active plasma with a sharp boundary 3.10.3. Instability of the surface of magnetically confined plasma 3.11. Problems Chapter Four Quantum Plasma (Influence of spatial Dispersion on some Phenomena in Metals) 4.1. Quantum Kinetic Equation with Self-consisted Fields and Magnetic Permittivity of an Electron gas 4.2. Longitudinal Oscillations of a Degenerate Electron Gas and Characteristic Energy Loss of the fast moving Electrons 4.3. Anomalous skin-effect in metals 4.4. Paramagnetic Resonance Absorption of Metals by Conduction Electrons 4.5. Collisionless Absorption of Sound Waves in Condensed Matters 4.5.1. Acoustic wave absorption and excitation in piezo-semiconductors 4.5.2. Excitation of coupled quasi elasto-electromagnetic surface waves 4.6. Problems Chapter Five Spatial Dispersion in Molecular Crystals 5.1. Dielectric permittivity of molecular crystals 5.2. The Permittivity of a Monatomic Gas with Spatial Dispersion 5.3. Problems