Retarded potential

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The scalar or vector potential electromagnetic of a time varying current or charge distribution.

These are the electromagnetic retarded potentials for an arbitrary source in free space (vacuum). They satisfy the inhomogeneous wave equations for V and \mathbf A in the Lorenz gauge.

\mathit t_r \equiv \mathit t - \frac{|\mathbf r - \mathbf r'|}{\mathit c}
\mathit V (\mathbf r ,\mathit t) = \frac{1}{4\pi\epsilon_0}\int \frac{\rho (\mathbf r' , \mathit t_r)}{|\mathbf r - \mathbf r'|}\, d\tau'
\mathbf A (\mathbf r ,\mathit t) = \frac{\mu_0}{4\pi}\int \frac{\mathbf J (\mathbf r' , \mathit t_r)}{|\mathbf r - \mathbf r'|}\, d\tau'

Here, \mathbf r is location, t is time, and c is the speed of light in a vacuum. tr is the "retarded time"; the time at which light must be emitted from location r' in order to reaches location r at time t. \rho (\mathbf r, \mathit t) is the electric charge density, and \mathbf J(\mathbf r, \mathit t) is the current density. ε0 is the dielectric constant of free space, and μ0 is the magnetic permeability of free space. V (\mathbf r ,\mathit t) is the electrical potential, and \mathbf A(\mathbf r ,\mathit t) is the vector potential.

The advanced potentials are:


\mathit V_a (\mathbf r ,\mathit t) = \frac{1}{4\pi\epsilon_0}\int \frac{\rho (\mathbf r' , \mathit t_a)}{|\mathbf r - \mathbf r'|}\, d\tau'
\mathbf A_a (\mathbf r ,\mathit t) = \frac{\mu_0}{4\pi}\int \frac{\mathbf J (\mathbf r' , \mathit t_a)}{|\mathbf r - \mathbf r'|}\, d\tau'


\mathit t_a \equiv \mathit t + \frac{|\mathbf r - \mathbf r'|}{\mathit c}

The subscript a stands for advanced, and ta is the "advanced time".


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