Pointlike electric charge in gravitational field theory

Abstract

The existence of charged elementary 'point particles' still is a basically unsolved puzzle in theoretical physics. The present work takes a fresh look at the problem by including gravity---without resorting to string theory. Using Einstein's equations for the gravitational fields in a general static isotropic metric with the full energy-momentum tensor (for the charged material mass and the electromagnetic fields) as the source term, a novel exact solution with a well-defined characteristic radius emerges where mass and charge accumulate: r c=r ero/2---with r e=Q2\!/4πεomc2 being the 'classical' radius associated with the total charge Q and where ro=2mG/c2 is the Schwarzschild radius belonging to the observable mass m (for the electron one has r e≈10-15m and ro≈\,10-57m). The resulting 'Einstein-Maxwell' gravitational electron radius can also be written as r c= Pα e, where P= G/c3≈10-35m is the fundamental Planck length and α e=e2\!/4πεo c≈1/137 the fine-structure constant, which yields r c electron=1.38063×10-36m.