Classical Theory of Electricity and Magnetism: (a Course of Lectures) |
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... Stationary currents and magnetic fields Basic laws in stationary condition - 83 , magnetic moment of current distribution - 86 , magnetic moment and angular momentum - 88 , Larmor precession - 88 , Permanent magnets and the vector H ...
... Stationary currents and magnetic fields Basic laws in stationary condition - 83 , magnetic moment of current distribution - 86 , magnetic moment and angular momentum - 88 , Larmor precession - 88 , Permanent magnets and the vector H ...
Page 85
... stationary assumption ( equation 5 ) . Hence finally VxB = Απ j ( 11 ) Equations ( 6 ) and ( 11 ) are the fundamental equations of stationary magnetic fields so long as there is no material medium and especially no permanent magnet . It ...
... stationary assumption ( equation 5 ) . Hence finally VxB = Απ j ( 11 ) Equations ( 6 ) and ( 11 ) are the fundamental equations of stationary magnetic fields so long as there is no material medium and especially no permanent magnet . It ...
Page 102
... stationary condition , work is done as the charge is moving under the action of a force eE . This work appears as the joule heat at the rate of σE2 per unit volume and is an irreversible process , associated with increase of entropy ...
... stationary condition , work is done as the charge is moving under the action of a force eE . This work appears as the joule heat at the rate of σE2 per unit volume and is an irreversible process , associated with increase of entropy ...
Contents
The empirical basis of electrostatics | 1 |
Direct calculation of fields | 7 |
dipoles9 The Dirac 8function13 | 13 |
Copyright | |
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angle angular axes axis B₁ boundary conditions calculate called charge density charged particle coil components conductor consider coordinates cos² cose dielectric constant dipole dipole moment direction distance E₁ electric field electromagnetic field electromotive force electron electrostatic equation 16 expression field due field point finite fluid formula frame frequency function gives Hence incident interaction Laplace's equation linear Lorentz Lorentz transformation magnetic field magnitude Maxwell's equations momentum motion normal obtain orthogonal P₁ permanent magnets perpendicular photon plane plasma point charge polarization Poynting vector R₁ radiation field radiation reaction radius refracted region scalar sin² solution spherical surface integral symmetry tensor term theorem theory of relativity transformation transverse uniform vanishes vector potential velocity wave length Απ дв дг ді дх