Classical Electrodynamics |
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Page 296
The power radiated per unit solid angle in the scalar Kirchhoff approximation is
dP ~ P, (ka): COS 0. s 2 d(2 47 where P, is given by (9.104). If we compare the
vector Kirchhoff result (9.103) with (9.112), we see similarities and differences.
The power radiated per unit solid angle in the scalar Kirchhoff approximation is
dP ~ P, (ka): COS 0. s 2 d(2 47 where P, is given by (9.104). If we compare the
vector Kirchhoff result (9.103) with (9.112), we see similarities and differences.
Page 297
Then both scalar and vector approximations reduce to the common expression, *
~ P. (ka) |Jiska sin 0) d() T ' tr ka sin 6 The ... There is reason to believe that the
vector Kirchhoff result is close to the correct one, even though the approximation
...
Then both scalar and vector approximations reduce to the common expression, *
~ P. (ka) |Jiska sin 0) d() T ' tr ka sin 6 The ... There is reason to believe that the
vector Kirchhoff result is close to the correct one, even though the approximation
...
Page
Neglecting the electromagnetic interaction between the two particles, determine
the radiation cross section in the center of mass system for a collision between
these identical particles to the lowest nonvanishing approximation. Show that the
...
Neglecting the electromagnetic interaction between the two particles, determine
the radiation cross section in the center of mass system for a collision between
these identical particles to the lowest nonvanishing approximation. Show that the
...
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Contents
Introduction to Electrostatics | 1 |
Nš 3 | 3 |
Greens theorem | 14 |
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