User:John R. Brews/Sample: Difference between revisions

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:<math>\Phi(\boldsymbol r , \ t) =\left. \frac{q}{(1-\mathbf{\hat u \cdot }\boldsymbol \beta )|\boldsymbol r - \boldsymbol \tilde r |}\right|_{\tilde t} =\left. \frac{q}{(1-\mathbf{\hat u \cdot }\boldsymbol \beta )R}\right|_{\tilde t} \ , </math>
:<math>\Phi(\boldsymbol r , \ t) =\left. \frac{q}{(1-\mathbf{\hat u \cdot }\boldsymbol \beta )|\boldsymbol r - \boldsymbol \tilde r |}\right|_{\tilde t} =\left. \frac{q}{(1-\mathbf{\hat u \cdot }\boldsymbol \beta )R}\right|_{\tilde t} \ , </math>
where the tilde {{nowrap|‘ '''<sup>~</sup>''' ’}} denotes evaluation at the ''retarded time'' ,
where the tilde {{nowrap|‘ '''<sup>~</sup>''' ’}} denotes evaluation at the ''retarded time'' ,
:<math>\tilde t = t - \frac{\boldsymbol r - \boldsymbol r_0(\tilde t)|}{c} \ , </math>
 
:<math>\tilde t = t - \frac{|\boldsymbol r - \boldsymbol r_0(\tilde t)|}{c} \ , </math>
 
''c'' being the speed of light, '''''r''''' the location of the observation point, and  '''''r<sub>O</sub>'''''  being the location of the particle on its trajectory.
''c'' being the speed of light, '''''r''''' the location of the observation point, and  '''''r<sub>O</sub>'''''  being the location of the particle on its trajectory.



Revision as of 16:05, 23 April 2011

Liénard–Wiechert potentials


Define β in terms of the velocity of a point charge at time t as:

and unit vector û as

where R is the vector joining the observation point P to the moving charge q at the time of observation. Then the Liénard–Wiechert potentials consist of a scalar potential Φ and a vector potential A. The scalar potential is:[1]

where the tilde ~ denotes evaluation at the retarded time ,

c being the speed of light, r the location of the observation point, and rO being the location of the particle on its trajectory.

The vector potential is:

With these potentials the electric field and the magnetic flux density are found to be (dots over symbols are time derivatives):[1]

Notes

  1. 1.0 1.1 Fulvio Melia (2001). “§4.6.1 Point currents and Liénard-Wiechert potentials”, Electrodynamics. University of Chicago Press, pp. 101. ISBN 0226519570. 

Feynman Belušević Gould Schwartz Schwartz Oughstun Eichler Müller-Kirsten Panat Palit Camara Smith classical distributed charge Florian Scheck Radiation reaction Fulvio Melia Radiative reaction Fulvio Melia Barut Radiative reaction Distributed charges: history Lorentz-Dirac equation Gould Fourier space description