Classical Electrodynamics |
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Page 25
1.5 cm 25.0 cm 2 (a) For the three capacitor geometries in Problem 1.5 calculate
the total electrostatic energy and express it alternatively in terms of the equal and
opposite charges Q and – Q placed on the conductors and the potential ...
1.5 cm 25.0 cm 2 (a) For the three capacitor geometries in Problem 1.5 calculate
the total electrostatic energy and express it alternatively in terms of the equal and
opposite charges Q and – Q placed on the conductors and the potential ...
Page 628
... 227, 451 for plasma in magnetic field, 228 Dielectrics, 108 anisotropic, waves
in, 233 boundary conditions, 110 boundary-value problems with, 110 f.
electrostatic energy in, 123 method of images for, 111 Dielectric wave guide, 259
at optical ...
... 227, 451 for plasma in magnetic field, 228 Dielectrics, 108 anisotropic, waves
in, 233 boundary conditions, 110 boundary-value problems with, 110 f.
electrostatic energy in, 123 method of images for, 111 Dielectric wave guide, 259
at optical ...
Page 634
... 463 Multipole, electrostatic, 98 electrostatic, expansion of interaction energy in,
101 electrostatic, expansion of potential in, 98 electrostatic, rectangular, 100
magnetostatic, 145 radiating, near, induction, and radiation zones, 270 time-
varying ...
... 463 Multipole, electrostatic, 98 electrostatic, expansion of interaction energy in,
101 electrostatic, expansion of potential in, 98 electrostatic, rectangular, 100
magnetostatic, 145 radiating, near, induction, and radiation zones, 270 time-
varying ...
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Contents
Introduction to Electrostatics | 1 |
References and suggested reading | 23 |
Multipoles Electrostatics of Macroscopic Media | 98 |
Copyright | |
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