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Page 438
John David Jackson. Make part of 13.2 13.3 Classical and Quantum - Mechanical Energy - Loss Formulas The energy transfer ( 13.31 ) to a harmonically bound charge can be used to calculate a classical energy loss per unit length for a fast ...
John David Jackson. Make part of 13.2 13.3 Classical and Quantum - Mechanical Energy - Loss Formulas The energy transfer ( 13.31 ) to a harmonically bound charge can be used to calculate a classical energy loss per unit length for a fast ...
Page 448
... energy loss no longer depends on the details of atomic structure through ( w ) ( 13.38 ) , but only on the number of electrons per unit volume through w ,. Two substances having very different atomic struc- tures will produce the same ...
... energy loss no longer depends on the details of atomic structure through ( w ) ( 13.38 ) , but only on the number of electrons per unit volume through w ,. Two substances having very different atomic struc- tures will produce the same ...
Page 449
... Energy loss , including the density effect . The dotted curve is the total energy loss without density correction . The solid curves have the density effect incorporated , the upper one being the total energy loss and the lower one the ...
... Energy loss , including the density effect . The dotted curve is the total energy loss without density correction . The solid curves have the density effect incorporated , the upper one being the total energy loss and the lower one the ...
Contents
1 | 1 |
BoundaryValue Problems in Electrostatics I | 26 |
Dielectrics | 98 |
Copyright | |
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4-vector Ampère's law angle angular distribution antenna approximation atomic axis B₁ Babinet's principle behavior boundary conditions calculate cavity Chapter charged particle coefficients collisions component conducting conductor consider constant coordinate cross section cylinder d³x dielectric diffraction dimensions dipole direction discussed E₁ electric field electromagnetic fields electrons electrostatic energy loss factor force equation frequency given Green's function impact parameter incident particle integral Kirchhoff Lagrangian Laplace's equation Lorentz force Lorentz invariant Lorentz transformation m₁ magnetic field magnetic induction magnitude Maxwell's equations meson modes momentum multipole nonrelativistic obtain oscillations P₁ parallel perpendicular phase velocity plane wave plasma polarization power radiated Poynting's vector problem propagation radius region relativistic result S₁ scalar scattering screen shown in Fig shows sin² solution sphere spherical surface transverse unit V₁ vanishes vector potential velocity wave guide wave number wavelength ΦΩ