Electrodynamics of Continuous Media |
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Page 47
... field which equals the mean field E. Assuming the particles spherical and using formula ( 8.2 ) , we obtain for the proportionality coefficient between В and ... electric field §10 Thermodynamic relations for dielectrics in an electric field.
... field which equals the mean field E. Assuming the particles spherical and using formula ( 8.2 ) , we obtain for the proportionality coefficient between В and ... electric field §10 Thermodynamic relations for dielectrics in an electric field.
Page 246
... field H. Determine the resulting electric field near the sphere . SOLUTION . In calculating the resulting electric field , the magnetic field may be taken to be the same as for a sphere at rest , since an allowance for the reciprocal ...
... field H. Determine the resulting electric field near the sphere . SOLUTION . In calculating the resulting electric field , the magnetic field may be taken to be the same as for a sphere at rest , since an allowance for the reciprocal ...
Page 329
... electric field An isotropic body becomes optically anisotropic when placed in a constant electric field . This anisotropy may be regarded as the result of a change in the dielectric constant due to the constant field . Although this ...
... electric field An isotropic body becomes optically anisotropic when placed in a constant electric field . This anisotropy may be regarded as the result of a change in the dielectric constant due to the constant field . Although this ...
Contents
ELECTROSTATICS OF CONDUCTORS 1 The electrostatic field of conductors | 1 |
2 The energy of the electrostatic field of conductors | 3 |
3 Methods of solving problems in electrostatics | 9 |
Copyright | |
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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
angle anisotropy atoms averaging axes axis body boundary condition calculated charge circuit co-ordinates coefficient components conducting conductor constant corresponding cross-section crystal Curie point curl H current density denote depends derivative determined dielectric permeability diffraction dipole direction discontinuity distance effect electric field electromagnetic electrons electrostatic ellipsoid entropy equation div expression external field ferroelectric ferromagnetic field H fluid flux force formula free energy frequency function given gives grad H₂ Hence incident induction integral isotropic Laplace's equation layer linear macroscopic magnetic field magnetic moment magnetisation magnitude Maxwell's equations medium metal normal obtain optical particle perpendicular piezoelectric plane polarisation PROBLEM propagation properties pyroelectric quantities refraction relation respect result rotation scalar scattering SOLUTION sphere suffixes superconducting surface symmetry tangential temperature theory thermodynamic potential tion unit volume values variable velocity wave vector wire z-axis zero