Complex-Distance Potential Theory and Hyperbolic Equations
Abstract
An extension of potential theory in Rn is obtained by continuing the Euclidean distance function holomorphically to Cn. The resulting Newtonian potential is generated by an extended source distribution D(z) in Cn whose restriction to Rn is the delta function. This provides a natural model for extended particles in physics. In Cn, interpreted as complex spacetime, D(z) acts as a propagator generating solutions of the wave equation from their initial values. This gives a new connection between elliptic and hyperbolic equations that does not assume analyticity of the Cauchy data. Generalized to Clifford analysis, it induces a similar connection between solutions of elliptic and hyperbolic Dirac equations. There is a natural application to the time-dependent, inhomogeneous Dirac and Maxwell equations, and the `electromagnetic wavelets' introduced previously are an example.
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