Classical Electrodynamics |
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Page 150
1 as one of the ways of defining the magnitude and direction of the 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 ...
1 as one of the ways of defining the magnitude and direction of the 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 ...
Page 382
This magnetic field becomes almost equal to the transverse electric field E, as B
— 1. Even at nonrelativistic velocities where y c 1, this magnetic induction is
equivalent to 2– 4 V × I B ~ c r* (11.119) which is just the Ampère-Biot–Savart ...
This magnetic field becomes almost equal to the transverse electric field E, as B
— 1. Even at nonrelativistic velocities where y c 1, this magnetic induction is
equivalent to 2– 4 V × I B ~ c r* (11.119) which is just the Ampère-Biot–Savart ...
Page 427
9 A particle of mass m and charge e moves in the laboratory in crossed , static ,
uniform , electric and magnetic fields . E is parallel to the x axis ; B is parallel to
the y axis . ( a ) For El < B make the necessary Lorentz transformation described
in ...
9 A particle of mass m and charge e moves in the laboratory in crossed , static ,
uniform , electric and magnetic fields . E is parallel to the x axis ; B is parallel to
the y axis . ( a ) For El < B make the necessary Lorentz transformation described
in ...
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Contents
Introduction to Electrostatics | 1 |
BoundaryValue Problems in Electrostatics I | 26 |
RelativisticParticle Kinematics and Dynamics | 391 |
Copyright | |
8 other sections not shown
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acceleration angle angular applied approximation assumed atomic average axis becomes boundary conditions calculate called Chapter charge charged particle classical collisions compared component conducting Consequently consider constant coordinates cross section cylinder defined density dependence derivative determine dielectric dimensions dipole direction discussed distance distribution effects electric field electromagnetic electron electrostatic energy equal equation example expansion expression factor force frame frequency function given gives incident inside integral involved light limit Lorentz loss magnetic magnetic field magnetic induction magnitude mass means modes momentum motion moving multipole normal observation obtain origin parallel particle physical plane plasma polarization position potential problem properties radiation radius region relation relative relativistic result satisfy scalar scattering shown in Fig shows side solution space sphere spherical surface transformation unit vanishes vector velocity volume wave written
Bibliographic information
| Title | Classical Electrodynamics |
| Author | John David Jackson |
| Publisher | Wiley, 1963 |
| Length | 641 pages |
| Export Citation | BiBTeX EndNote RefMan |