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Plasma Physics Volume 4 of Modern Classical Physics 1st edition by Kip Thorne, Roger Blandford ISBN‎ 0691215502 ‎ 978-0691215501

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ISBN 10:‎ 0691215502
ISBN 13: ‎ 978-0691215501
Author: Kip Thorne, Roger Blandford 

A groundbreaking textbook on twenty-first-century plasma physics and its applications

Kip Thorne and Roger Blandford’s monumental Modern Classical Physics is now available in five stand-alone volumes that make ideal textbooks for individual graduate or advanced undergraduate courses on statistical physics; optics; elasticity and fluid dynamics; plasma physics; and relativity and cosmology. Each volume teaches the fundamental concepts, emphasizes modern, real-world applications, and gives students a physical and intuitive understanding of the subject.

Plasma Physics provides an essential introduction to the subject. A gas that is significantly ionized, usually by heating or photons, a plasma is composed of electrons and ions and sometimes has an embedded or confining magnetic field. Plasmas play a major role in many contemporary applications, phenomena, and fields, including attempts to achieve controlled thermonuclear fusion using magnetic or inertial confinement; in explanations of radio wave propagation in the ionosphere and the behavior of the solar corona and wind; and in astrophysics, where plasmas are responsible for emission throughout the electromagnetic spectrum, including from black holes, highly magnetized neutron stars, and ultrarelativistic outflows. The book also can serve as supplementary reading for many other courses, including in astrophysics, geophysics, and controlled fusion.

  • Includes many exercise problems
  • Features color figures, suggestions for further reading, extensive cross-references, and a detailed index
  • Optional “Track 2” sections make this an ideal book for a one-quarter or one-semester course
  • An online illustration package is available to professors

The five volumes, which are available individually as paperbacks and ebooks, are Statistical PhysicsOpticsElasticity and Fluid Dynamics; Plasma Physics; and Relativity and Cosmology.

Plasma Physics Volume 4 of Modern Classical Physics 1st Table of contents:

19 Magnetohydrodynamics

19.1 Overview

19.2 Basic Equations of MHD

19.2.1 Maxwell’s Equations in the MHD Approximation

19.2.2 Momentum and Energy Conservation

19.2.3 Boundary Conditions

19.2.4 Magnetic Field and Vorticity

19.3 Magnetostatic Equilibria

19.3.1 Controlled Thermonuclear Fusion

19.3.2 Z-Pinch

19.3.3 Θ-Pinch

19.3.4 Tokamak

19.4 Hydromagnetic Flows

19.5 Stability of Magnetostatic Equilibria

19.5.1 Linear Perturbation Theory

19.5.2 Z-Pinch: Sausage and Kink Instabilities

19.5.3 The Θ-Pinch and Its Toroidal Analog; Flute Instability; Motivation for Tokamak

19.5.4 Energy Principle and Virial Theorems

19.6 Dynamos and Reconnection of Magnetic Field Lines

19.6.1 Cowling’s Theorem

19.6.2 Kinematic Dynamos

19.6.3 Magnetic Reconnection

19.7 MagnetosonicWaves and the Scattering of Cosmic Rays

19.7.1 Cosmic Rays

19.7.2 Magnetosonic Dispersion Relation

19.7.3 Scattering of Cosmic Rays by Alfvén Waves

Bibliographic Note

PART VI PLASMA PHYSICS

20 The Particle Kinetics of Plasma

20.1 Overview

20.2 Examples of Plasmas and Their Density-Temperature Regimes

20.2.1 Ionization Boundary

20.2.2 Degeneracy Boundary

20.2.3 Relativistic Boundary

20.2.4 Pair-Production Boundary

20.2.5 Examples of Natural and Human-Made Plasmas

20.3 Collective Effects in Plasmas—Debye Shielding and Plasma Oscillations

20.3.1 Debye Shielding

20.3.2 Collective Behavior

20.3.3 Plasma Oscillations and Plasma Frequency

20.4 Coulomb Collisions

20.4.1 Collision Frequency

20.4.2 The Coulomb Logarithm

20.4.3 Thermal Equilibration Rates in a Plasma

20.4.4 Discussion

20.5 Transport Coefficients

20.5.1 Coulomb Collisions

20.5.2 Anomalous Resistivity and Anomalous Equilibration

20.6 Magnetic Field

20.6.1 Cyclotron Frequency and Larmor Radius

20.6.2 Validity of the Fluid Approximation

20.6.3 Conductivity Tensor

20.7 Particle Motion and Adiabatic Invariants

20.7.1 Homogeneous, Time-Independent Magnetic Field and No Electric Field

20.7.2 Homogeneous, Time-Independent Electric and Magnetic Fields

20.7.3 Inhomogeneous, Time-Independent Magnetic Field

20.7.4 A Slowly Time-Varying Magnetic Field

20.7.5 Failure of Adiabatic Invariants; Chaotic Orbits

Bibliographic Note

21 Waves in Cold Plasmas: Two-Fluid Formalism

21.1 Overview

21.2 Dielectric Tensor, Wave Equation, and General Dispersion Relation

21.3 Two-Fluid Formalism

21.4 Wave Modes in an Unmagnetized Plasma

21.4.1 Dielectric Tensor and Dispersion Relation for a Cold, Unmagnetized Plasma

21.4.2 Plasma Electromagnetic Modes

21.4.3 LangmuirWaves and Ion-AcousticWaves inWarm Plasmas

21.4.4 Cutoffs and Resonances

21.5 Wave Modes in a Cold, Magnetized Plasma

21.5.1 Dielectric Tensor and Dispersion Relation

21.5.2 Parallel Propagation

21.5.3 Perpendicular Propagation

21.5.4 Propagation of RadioWaves in the Ionosphere; Magnetoionic Theory

21.5.5 CMA Diagram for Wave Modes in a Cold, Magnetized Plasma

21.6 Two-Stream Instability

Bibliographic Note

22 Kinetic Theory of Warm Plasmas

22.1 Overview

22.2 Basic Concepts of Kinetic Theory and Its Relationship to Two-Fluid Theory

22.2.1 Distribution Function and Vlasov Equation

22.2.2 Relation of Kinetic Theory to Two-Fluid Theory

22.2.3 Jeans’ Theorem

22.3 Electrostatic Waves in an Unmagnetized Plasma: Landau Damping

22.3.1 Formal Dispersion Relation

22.3.2 Two-Stream Instability

22.3.3 The Landau Contour

22.3.4 Dispersion Relation for Weakly Damped or Growing Waves

22.3.5 Langmuir Waves and Their Landau Damping

22.3.6 Ion-Acoustic Waves and Conditions for Their Landau Damping to Be Weak

22.4 Stability of ElectrostaticWaves in Unmagnetized Plasmas

22.4.1 Nyquist’s Method

22.4.2 Penrose’s Instability Criterion

22.5 Particle Trapping

22.6 N-Particle Distribution Function

22.6.1 BBGKY Hierarchy

22.6.2 Two-Point Correlation Function

22.6.3 Coulomb Correction to Plasma Pressure

Bibliographic Note

23 Nonlinear Dynamics of Plasmas

23.1 Overview

23.2 Quasilinear Theory in Classical Language

23.2.1 Classical Derivation of the Theory

23.2.2 Summary of Quasilinear Theory

23.2.3 Conservation Laws

23.2.4 Generalization to 3 Dimensions

23.3 Quasilinear Theory in Quantum Mechanical Language

23.3.1 Plasmon Occupation Number η

23.3.2 Evolution of η for Plasmons via Interaction with Electrons

23.3.3 Evolution of f for Electrons via Interaction with Plasmons

23.3.4 Emission of Plasmons by Particles in the Presence of a Magnetic Field

23.3.5 Relationship between Classical and Quantum Mechanical Formalisms

23.3.6 Evolution of η via Three-Wave Mixing

23.4 Quasilinear Evolution of Unstable Distribution Functions—A Bump in the Tail

23.4.1 Instability of Streaming Cosmic Rays

23.5 Parametric Instabilities; Laser Fusion

23.6 Solitons and Collisionless Shock Waves

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