Landau L.D., Lifshitz E.M. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media :: Электронная библиотека попечительского совета мехмата МГУ

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Landau L.D., Lifshitz E.M. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media

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Название: Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media

Авторы: Landau L.D., Lifshitz E.M.

Аннотация:

Covers the theory of electromagnetic fields in matter, and the theory of the macroscopic electric and magnetic properties of matter. There is a considerable amount of new material particularly on the theory of the magnetic properties of matter and the theory of optical phenomena with new chapters on spatial dispersion and non-linear optics. The chapters on ferromagnetism and antiferromagnetism and on magnetohydrodynamics have been substantially enlarged and eight other chapters have additional sections.

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Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

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Издание: 2

Год издания: 1984

Количество страниц: 455

Добавлена в каталог: 25.06.2021

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Предметный указатель

Image      8
Image force      9 37
Images, method of      8—10
Impedance      210
Impedance matrix      213
Impedance surface      203 300—4 332—3
Incommensurate phases      179
Inductance mutual      119 210
Inductance self-      118; see also Self-inductance
Induction electric      35
Induction magnetic      105
Induction unipolar      220
Inertial range of turbulence      255
Integral intensity of X-ray diffraction      445—7
Intermediate state      189—98
Inversion method of      10—11
Inversion radius of      10
Inversion transformation      10
Ionization losses by fast particles      394—405
Ionization losses by fast particles relativistic      399—405
Joule's law      87
Joule's law in a moving conductor      217
Kerr effect      347
Kinematic theory of scattering      443n.
Kinetic coefficients      88
Kinetic coefficients symmetry of      87—8 90 333 348
Kramers and Kronig's formulae      281—3 302—3
Landau—Placzek formula      431
Laue's equation      441
Laue's method      445n.
Leduc—Righi effect      101
Linear currents      110 119—21 210—2 221—2
Linear currents mutual inductance of      210
Linear currents self-inductance of      121—6
Liquid crystal      70
Liquid crystal scattering in      435—6
Local equation      200
Logarithmic accuracy      122
Lorentz condition      399
Losses electric      274
Losses magnetic      274
Magnetic anisotropy energy      136n. 138—40
Magnetic axis      235
Magnetic Bravais lattice      135
Magnetic crystal classes      131 132—4
Magnetic field      106
Magnetic field boundary conditions      107 200—1
Magnetic field conducting fluid moving in      225—56
Magnetic field conductor moving in      217—22
Magnetic field forces on matter in      126—9
Magnetic field of steady current      107—13
Magnetic field static (IV)      105ff.
Magnetic field thermodynamics of      113—17
Magnetic flux      120
Magnetic induction      105
Magnetic losses      274
magnetic moment      106
Magnetic moment in variable field      268
Magnetic permeability      106
Magnetic permeability analytic properties of      283
Magnetic permeability dispersion of      268—72
Magnetic permeability of crystals      331
Magnetic polarizability tensor      204
Magnetic Reynolds number      229
Magnetic space groups      131 134—5
Magnetic structure      130
Magnetic structure helicoidal      178—9
Magnetic sub-lattice      132
Magnetic surfaces      232
magnetic susceptibility      106
Magnetic susceptibility sign of      106 115
Magnetic symmetry of crystals      130—5
Magnetic-type waves      see H waves
Magnetic—optical effects      347—55
magnetization      105
Magnetization by rotation      129
Magnetization curve      141—4
Magnetization easy      139
Magnetization regions of spontaneous      see Domains
Magnetoelastic energy      144
Magnetoelectric effect      176—8
Magnetohydrodynamics (VIII)      225ff.
Magnetosonic waves      237
Magnetostatic energy      158
Magnetostatic oscillations      269n.
Magnetostatics and electrostatics compared      113 126 130 135
Magnetostriction      144—7
Magnetostriction linear      176
Mandel'shtam—Brillouin doublet      430
Manley—Rowe theorem      373
Maxwell effect      356
Maxwell stress tensor      29
Maxwell's equations      2 105 333 399
Maxwellian relaxation time      432
Mechanical—optical effects      355—7
Meridional distribution      234
Micromagnetism      157n.
Momentum density      260
Mutual inductance      119 210
Natural optical activity      362—6
Natural optical activity of crystals      364—5
Navier-Stokes equation      225 228
Nematic crystal      70
Nernst effect      101
Non-linear optics (XIII)      372ff.
Non-local relation      358
Non-uniformity energy      147
Notation      xii—xiii
Ohm's law      86 213
Optical activity vector      348
Optical activity, natural      362—6
Optical activity, natural of crystals      364—5
Optical axis      339 343
Optical axis circular      346
Optical axis singular      346
Optical frequencies      265
Optical ray axis      343
Ordinary waves      340
Orientational transitions      159—62
Oscillator strength      282
Parametric amplification      388
Peltier coefficient      99
Peltier effect      99
Penetration depth      201—10 301
Penetration depth in a superconductor      180 301
Permeability      see Magnetic permeability
Permittivity analytical properties of      279—83
Permittivity at high frequencies      267—8
Permittivity at low frequencies      267
Permittivity dispersion of      264—7
Permittivity electrostatic      36
Permittivity longitudinal      361
Permittivity non-linear      374—8
Permittivity of a mixture      42—4
Permittivity of crystals      331—3
Permittivity tensor      54 64 347 422
Permittivity transverse      361
phase velocity      236 291
Piezoelectric tensor      68 70—2
Piezoelectricity      55n. 65n. 67—74
Piezomagnetism      176 177
Pinch      233
Polariton range      369n.
Polarizability tensor      7 204
Polarization      34
Polarization coefficient      36
Polarization in a gyrotropic medium      353
Polarization in a uniaxial crystal      340
Polarization in geometrical optics      297
Polarization of a dielectric in a variable field      266—7

Polarization of electromagnetic waves in an anisotropic medium      337—8
Polarization total      297
Ponderomotive forces      59
Potential contact      93
Potential electric complex      11
Potential electric scalar      2—3 399
Potential vector      11 108 120 399
Powder method      446n.
Poynting vector      see Energy flux
Principal dielectric axes      334
Principal maxima      441
Principal section      340
Principal waves in waveguides      316
Principal waves in waveguides damping of      317
Pump wave      393
Pyroelectricity      55—6
Q factor of a resonator      311
Quadrupole moment tensor      25
Quadrupole moment tensor of conducting ellipsoid      25—6
Quality of a resonator      311
Quasi-static fields (VII)      199ff.
Raman scattering      428
Raman scattering stimulated      391—3
Raman—Landsberg—Mandel'shtam effect      428
Ray surface      335 339—40 343—4
Ray vector      335
Rayleigh scattering      428
Reactance      211n.
Reciprocity theorem      309
Reflection coefficient      295—300 303—4
Reflection point      305
Refractive index      285 290 334n. 340
Relativistic interactions      136 178
Resistance      211n.
Resistance complex      210—14
Resonators      310—13
Resonators quality of      311
Reynolds number, magnetic      229
Rotation method      446n.
Scale invariance      163 172
Scattering      413
Scattering anti-Stokes      413
Scattering antisymmetric      417
Scattering cross-section for      319
Scattering in amorphous solids      436—8
Scattering in liquid crystals      435—6
Scattering of electromagnetic waves (XV)      413ff.
Scattering of electromagnetic waves (XV) by small particles      319—22
Scattering of electromagnetic waves (XV) spontaneous      421
Scattering plane      320
Scattering principle of detailed balancing for      419—22
Scattering Raman      see Raman scattering
Scattering Rayleigh, in gases and liquids      428—33
Scattering scalar      417
Scattering spontaneous      421
Scattering Stokes      413
Scattering symmetric      417
Scattering with small change in frequency      422—8
Second-harmonic generation      383—8
Self-channelling      381
Self-focusing      378—83
Self-inductance      118
Self-inductance of linear conductors      121—6
Self-inductance of superconductors      183—5
Shock waves in a magnetic fluid      245—53
Shock waves in a magnetic fluid electromagnetic      389
Shock waves in a magnetic fluid evolutionary      247
Shock waves in a magnetic fluid fast      250
Shock waves in a magnetic fluid parallel      251
Shock waves in a magnetic fluid perpendicular      247
Shock waves in a magnetic fluid slow      250
Shock waves in a magnetic fluid switch-off      252
Shock waves in a magnetic fluid switch-on      252
Single-domain particles      157—9
Skin effect      122n. 208—10
Solenoid      122 125—6
Solids, forces in      64—7
Spatial dispersion (XIII)      358ff.
Sphere conducting      9—10 14 32 57 88—9 205—6 207 221
Sphere dielectric      39—40 42 56 57 67 263—4
Spheroidal coordinates oblate      20
Spheroidal coordinates prolate      20
Spin flop      169
Stewart—Tolman effect      223
Stimulated emission      413n.
Stimulated Raman scattering      391—3 421—2
Stopping power      396
Stress tensor      60 64 65 276—8
Strong electromagnetic waves      388—91
Sum rule      282
Superconductivity (VI)      180ff.
Superconductivity (VI) current      182—5
Superconductivity (VI) destruction of      185
Superconductivity (VI) transition point      180
Superconductors      180ff.
Superconductors critical field in      185—9
Superconductors currents in      182—5
Superconductors disc-shaped      185
Superconductors impedance of      301—2
Superconductors intermediate state of      189—98
Superconductors magnetic properties of      180—2
Superconductors multiply connected      183—5
Superconductors rotating      224
Superconductors self-inductance of      183—5
Superconductors thermodynamics of      185—9
Superconductors types of      180n.
Superconductorsellipsoidal      193
susceptibility      see Dielectric susceptibility; Magnetic susceptibility
Synchronism condition      384
Telegraph equation      318
Tensor ellipsoid      55
Thermodynamic inequalities      74—7
Thermoelectric phenomena      97
Thermoelectromotive force      100
Thermogalvanomagnetic phenomena      101
Theta pinch      234
Thomson coefficient      99
Thomson effect      99
Thomson's formula      215
Thomson's relations      100
Thomson's theorem      6
Total polarization, angle of      297
Total reflection      298
Total reflection angle of      297
Transition radiation      408—12
Transparency ranges      274
Transparent media      286—9
Transverse waves      314n.
Turbulence in conducting fluid      253
Turbulent dynamo      253—6
Two-dimensional field      11
Two-photon absorption      393
Uniaxial crystals      55 339—41
Uniaxial crystals negative      339
Uniaxial crystals positive      339
Unipolar induction      220
Vector potential      11 108 120 399
Velocity of light in a moving medium      292—3
Wave-vector surface      335 339 341—2 350
Waveguides      313
Waves electric-type      see E waves
Waves electromagnetic      see Electromagnetic waves
Waves extraordinary      340
Waves hydromagnetic      see Hydromagnetic waves
Waves magnetic-type      see H waves
Waves on a charged liquid surface      33
Waves ordinary      340
Waves principal      316
Waves scattered      413
Waves shock      see Shock waves

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