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010   $a9786610559572
010   $a3-527-63502-5
010   $a3-527-60312-3
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100   $a20011218d2001      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 14$aThe physics of Alfven waves /$fNeil F. Cramer
205   $a1st ed.
210   $aBerlin ;$aNew York $cWiley-VCH$dc2001
215   $a1 online resource (314 p.)
300   $aDescription based upon print version of record.
311   $a3-527-40293-4 
320   $aIncludes bibliographical references (p. [273]-289 and index.
327   $aThe Physics of Alfve?n Waves; Contents; 1 Descriptions of Magnetized Plasmas; 1.1 Introduction; 1.2 The Multi-Fluid Equations; 1.3 The Magnetohydrodynamic Model; 1.4 The Hall-MHD Model; 1.5 Fourier Transforms; 1.6 The Kinetic Theory; 2 Waves in Uniform Plasmas; 2.1 Introduction; 2.2 Waves with the MHD Model; 2.2.1 The Alfve?n Mode; 2.2.2 The Fast and Slow Magnetoacoustic Modes; 2.3 The Hall-MHD Model; 2.3.1 Cold Plasma; 2.3.2 Warm Plasma; 2.4 Cold Collisionless Plasmas; 2.5 Collisional Damping; 2.5.1 Low Frequency; 2.5.2 Hall Effects; 2.6 Multiple Ion Species; 2.7 Kinetic Theory of Waves
327   $a2.7.1 Parallel Propagation2.7.2 Low Plasma Beta; 2.7.3 High Plasma Beta; 2.8 Kinetic Alfve?n Wave and Inertial Alfve?n Wave; 2.8.1 Fluid Theory; 2.8.2 Parallel Electron Temperature Effects; 2.8.3 Two-Potential Theory; 2.8.4 Kinetic Theory; 2.8.5 Localized Alfve?n Waves; 3 Waves in Nonuniform Plasmas; 3.1 Introduction; 3.2 Stratified Plasmas; 3.2.1 Ideal MHD; 3.2.2 Hall MHD; 3.2.3 Multi-Ion Plasmas; 3.2.4 Effects of Collisions; 3.3 Waves in Smooth Nonuniformities; 3.3.1 Ideal MHD; 3.3.2 Cold Plasma; 3.4 Alfve?n Resonance Absorption; 3.4.1 Narrow Interfaces; 3.4.2 Analytic Derivation
327   $a4 Surface Waves4.1 Introduction; 4.2 Surface Waves at Density Jumps; 4.2.1 Cold Plasma; 4.2.2 Low-Frequency Surface Waves; 4.3 Finite Ion Cyclotron Frequency Effects; 4.3.1 Surface Wave Frequency; 4.3.2 Resonance Damping; 4.4 Multiple Ion Species; 4.4.1 Surface Wave Solutions; 4.4.2 Resonance Damping; 4.5 Ideal MHD; 4.5.1 Dispersion Relation; 4.5.2 Resonance Damping; 4.6 Magnetic Field Rotation; 4.6.1 Ideal MHD; 4.6.2 Cyclotron Effects; 4.7 Radiative and Collisional Damping; 4.7.1 Radiative Damping; 4.7.2 Collisional Damping; 4.8 Kinetic Theory; 5 Instabilities and Nonlinear Waves
327   $a5.1 Introduction5.2 Instabilities; 5.2.1 Macroinstabilities; 5.2.2 Microinstabilities; 5.3 Acceleration of Charged Particles; 5.4 Nonlinear Waves; 5.4.1 Wave Equations; 5.4.2 Low Frequency; 5.4.3 Higher Frequency; 5.4.4 Oblique Propagation; 5.5 Parametric and Modulational Instabilities; 5.5.1 Excitation by a Magnetoacoustic Pump; 5.5.2 Instability of Alfve?n waves; 5.6 Nonlinear Kinetic and Inertial Alfve?n Waves; 5.7 Nonlinear Surface Waves; 5.7.1 Nonlinear Surface Waves with Hall Dispersion; 5.7.2 Surface Alfve?n Wave Solitons; 6 Laboratory Plasmas; 6.1 Introduction
327   $a6.2 Modes of Bounded Plasmas6.2.1 Resistive Plasmas; 6.3 Cylindrical Geometry; 6.3.1 Uniform Plasma; 6.3.2 Bounded Plasma; 6.3.3 Nonideal Effects; 6.4 Nonuniform Plasmas; 6.5 Effects of Current; 6.6 Discrete Alfve?n Waves; 6.6.1 Slab Plasma; 6.6.2 Cylindrical Plasma; 6.7 Toroidal Alfve?n Eigenmodes; 6.8 Current Drive; 6.9 Localized Alfve?n Waves; 7 Space and Solar Plasmas; 7.1 Introduction; 7.2 The Magnetosphere; 7.2.1 Micropulsations; 7.2.2 Kinetic and Inertial Alfve?n Waves; 7.3 Solar and Stellar Winds; 7.3.1 Turbulent Waves in the Solar Wind; 7.3.2 Wind Acceleration; 7.4 Dusty Space Plasmas
327   $a7.5 Cometary Plasmas
330   $aLow-frequency wave modes of magnetized inhomogeneous plasmas have been subject to intense study in the last decade because they play important roles in the transport of energy in the plasmas. The ""Alfve?n wave heating"" scheme has been investigated as a supplementary heating scheme for fusion plasma devices, and it has been invoked as a model of the heating of the solar and stellar coronae.This book covers the latest research into the properties and applications of low-frequency wave modes in magnetized plasmas, the Alfve?n waves and magneto-acoustic waves, in the context of laboratory, spa
606   $aMagnetohydrodynamic waves
615  0$aMagnetohydrodynamic waves.
676   $a538/.6
700   $aCramer$b Neil F$01758055
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910876551303321
996   $aThe physics of Alfven waves$94196123
997   $aUNINA