Electrodynamics of Continuous MediaCovers 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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Results 6-10 of 83
Page 42
... respect to such an average field, and so may be characterized by an effective permittivity, which we denote by emix. If E and D are the field and induction averaged in this way, then, by the definition of emix, - - D = &mix E. (9.1) If ...
... respect to such an average field, and so may be characterized by an effective permittivity, which we denote by emix. If E and D are the field and induction averaged in this way, then, by the definition of emix, - - D = &mix E. (9.1) If ...
Page 45
... respect to S, p, D and T, p, D respectively. In particular, we can obtain the field by differentiating these potentials with respect to the components of the vector D: E = 4:(OU/CD), =47(óF/ćD). (10.7) t In (10.3) and (104) the volume ...
... respect to S, p, D and T, p, D respectively. In particular, we can obtain the field by differentiating these potentials with respect to the components of the vector D: E = 4:(OU/CD), =47(óF/ćD). (10.7) t In (10.3) and (104) the volume ...
Page 46
... respect, since it is to be differentiated at constant temperature, whereas the internal energy must be expressed in ... respect to the charges on the conductors, while those with it are thermodynamic potentials with respect to their ...
... respect, since it is to be differentiated at constant temperature, whereas the internal energy must be expressed in ... respect to the charges on the conductors, while those with it are thermodynamic potentials with respect to their ...
Page 47
... respect to changes in state occurring at constant temperature and (respectively) constant charges and potentials of the conductors (the same is true for 4 and % at constant entropy). If any processes (such as chemical reactions) which ...
... respect to changes in state occurring at constant temperature and (respectively) constant charges and potentials of the conductors (the same is true for 4 and % at constant entropy). If any processes (such as chemical reactions) which ...
Page 52
... respect to pressure for constant T and G. For example, from (12.5) we have V – Vo = – (#' [ć(k V)/óPl,. (12.6) This quantity may be either positive or negative (whereas, in electrostriction of conductors, the volume is always greater in ...
... respect to pressure for constant T and G. For example, from (12.5) we have V – Vo = – (#' [ć(k V)/óPl,. (12.6) This quantity may be either positive or negative (whereas, in electrostriction of conductors, the volume is always greater in ...
Contents
1 | |
34 | |
CHAPTER III STEADY CURRENT | 86 |
CHAPTER IV STATIC MAGNETIC FIELD | 105 |
CHAPTER V FERROMAGNETISM AND ANTIFERROMAGNETISM | 130 |
CHAPTER VI SUPERCONDUCTIVITY | 180 |
CHAPTER VII QUASISTATIC ELECTROMAGNETIC FIELD | 199 |
CHAPTER VIII MAGNETOHYDRODYNAMICS | 225 |
CHAPTER XI ELECTROMAGNETIC WAVES IN ANISOTROPIC MEDIA | 331 |
CHAPTER XII SPATIAL DISPERSION | 358 |
CHAPTER XIII NONLINEAR OPTICS | 372 |
CHAPTER XIV THE PASSAGE OF FAST PARTICLES THROUGH MATTER | 394 |
CHAPTER XV SCATTERING OF ELECTROMAGNETIC WAVES | 413 |
CHAPTER XVI DIFFRACTION OF XRAYS IN CRYSTALS | 439 |
CURVILINEAR COORDINATES | 452 |
INDEX | 455 |
CHAPTER IX THE ELECTROMAGNETIC WAVE EQUATIONS | 257 |
CHAPTER X THE PROPAGATION OF ELECTROMAGNETIC WAVES | 290 |
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Electrodynamics of Continuous Media: Volume 8 L D Landau,E.M. Lifshitz,L. P. Pitaevskii Snippet view - 1995 |
Common terms and phrases
According angle anisotropy assumed averaging axes axis becomes body boundary conditions calculation called charge coefficient compared components condition conducting conductor consider constant continuous coordinates corresponding crystal curl denote density depends derivative determined dielectric direction discontinuity distance distribution effect electric field ellipsoid energy equal equation expression external factor ferromagnet fluid flux follows force formula frequency function given gives grad Hence incident increases independent induction integral linear magnetic field mean medium neglected normal obtain occur parallel particle particular permittivity perpendicular phase plane polarization positive potential present PROBLEM propagated properties quantities range regarded region relation respect result rotation satisfied scattering simply solution sphere Substituting surface symmetry taken temperature tensor theory thermodynamic transition uniform unit values variable vector volume wave write zero