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 186
... magnetic induction . The potential energy of a permanent magnetic moment ( or dipole ) in an external magnetic field can be obtained from either the force ( 5.69 ) or the torque ( 5.71 ) . If we interpret the force as the negative ...
... magnetic induction . The potential energy of a permanent magnetic moment ( or dipole ) in an external magnetic field can be obtained from either the force ( 5.69 ) or the torque ( 5.71 ) . If we interpret the force as the negative ...
Page 204
... magnetic field on the z = 0 * side of the plane in the absence of the hole . Figure 9.4 shows qualitatively how the magnetic field lines distort to give rise to the dipole field . In the opening itself ( z = 0 , 0≤p < a ) the ...
... magnetic field on the z = 0 * side of the plane in the absence of the hole . Figure 9.4 shows qualitatively how the magnetic field lines distort to give rise to the dipole field . In the opening itself ( z = 0 , 0≤p < a ) the ...
Page 266
... magnetic fields between the plates to second order in powers of the frequency ( or wave number ) , neglecting the ... field , and a transverse magnetic field is applied , there develops a component of electric field in the direction ...
... magnetic fields between the plates to second order in powers of the frequency ( or wave number ) , neglecting the ... field , and a transverse magnetic field is applied , there develops a component of electric field in the direction ...
Contents
L2 The Inverse Square Law or the Mass of the Photon | 1 |
1 | 17 |
1 | 27 |
Copyright | |
18 other sections not shown
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angle angular applied approximation assumed atomic average becomes boundary conditions calculate called Chapter charge charge density classical coefficients collision compared components conducting conductor consider constant coordinates corresponding cross section defined density dependence derivative determined dielectric dipole direction discussed distance distribution effects electric field electromagnetic electrons electrostatic energy equal equation example expansion expression factor force frame frequency function given gives incident induction inside integral involving limit linear Lorentz macroscopic magnetic field magnitude Maxwell means medium modes molecules momentum motion moving multipole normal observation obtained origin parallel particle physical plane polarization positive potential problem propagation properties quantum mechanics radiation radius region relation relative result satisfy scalar scattering shown solution space special relativity sphere spherical surface transformation unit vanishes vector velocity volume wave written zero