Electrodynamics in geometric algebra

Abstract

We consider the electrodynamics of electric charges and currents in vacuum and then generalise our results to the description of a dielectric and magnetic material medium : first in spatial algebra (SA) and then in space-time algebra (STA). Introducing a polarisation multivector P = p -\,1c\,M and an auxiliary electromagnetic field multivector G = 0\,F + P, we express the Maxwell equation in the material medium in SA. Introducing a bound current vector J = J -\,c\,∇·P in space-time, the Maxwell equation is then expressed in STA. The wave equation in the material medium is obtained by taking the gradient of the Maxwell equation. For a uniform electromagnetic medium consisting of induced electric and magnetic dipoles, the stress-energy momentum vector is written as T(∇) = 1c\,J · F = f where f is the electromagnetic force density vector in space-time. Finally, the Maxwell equation in the material medium can be written in STA as a wave equation for the potential vector A.