Classical ElectrodynamicsThis edition refines and improves the first edition. It treats the present experimental limits on the mass of photon and the status of linear superposition, and introduces many other innovations. |
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Page 19
... component of D at any point is equal to 4π times the surface charge density at that point . In an analogous manner the infinitesimal Stokesian loop can be used to determine the discontinuities of the tangential components of E and H. If ...
... component of D at any point is equal to 4π times the surface charge density at that point . In an analogous manner the infinitesimal Stokesian loop can be used to determine the discontinuities of the tangential components of E and H. If ...
Page 247
... components of a vector , and so on for higher rank tensors . Differential vector operations have definite transformation properties under rotations . For example , the gradient of a scalar , Vo , transforms as a vector , the divergence ...
... components of a vector , and so on for higher rank tensors . Differential vector operations have definite transformation properties under rotations . For example , the gradient of a scalar , Vo , transforms as a vector , the divergence ...
Page 517
... components of a vector . We designate by the same name any three physical quantities that transform under rotations in the same way as the components of x . It is natural therefore to anticipate that there are numerous physical ...
... components of a vector . We designate by the same name any three physical quantities that transform under rotations in the same way as the components of x . It is natural therefore to anticipate that there are numerous physical ...
Contents
L2 The Inverse Square Law or the Mass of the Photon | 1 |
BoundaryValue Problems | 54 |
Multipoles Electrostatics | 136 |
Copyright | |
17 other sections not shown
Common terms and phrases
4-vector Ampère's law amplitude angle angular distribution angular momentum approximation atomic axis behavior boundary conditions calculate Chapter charge density charge q charged particle classical coefficients collision components conducting conductor consider coordinates cross section current density cylinder d³x defined dielectric constant diffraction dimensions dipole direction discussed electric and magnetic electric field electromagnetic fields electrons electrostatic expansion expression factor force frame frequency given Green function incident integral limit linear Lorentz transformation macroscopic magnetic field magnetic induction magnetic monopole magnitude Maxwell equations medium modes molecules motion multipole multipole expansion multipole moments nonrelativistic normal obtained oscillations parallel parameter photon Phys plane wave plasma polarization problem propagation quantum quantum-mechanical radiation radius region relativistic result scattering shown in Fig sin² solution spectrum sphere spherical surface tensor theorem transverse unit V₁ vanishes vector potential velocity volume wave guide wave number wavelength written zero ΦΩ