On the discrete Dirac spectrum of general-relativistic hydrogenic ions with anomalous magnetic moment

Abstract

The Reissner-Weyl-Nordstr\"om (RWN) spacetime of a point nucleus features a naked singularity for the empirically known nuclear charges Ze and masses M = A(Z,N)mp, where mp is the proton mass and A(Z,N)≈ Z+N the atomic mass number, with Z the number of protons and N the number of neutrons in the nucleus. The Dirac Hamiltonian for a test electron with mass me, charge -e, and anomalous magnetic moment μa (≈ - 14πe3me c2) in the electrostatic RWN spacetime of such a 'naked point nucleus' is known to be essentially self-adjoint, with a spectrum that consists of the union of the essential spectrum (-∞, me c2][me c2, ∞) and a discrete spectrum of infinitely many eigenvalues in the gap (-me c2,me c2), having me c2 as accumulation point. In this paper the discrete spectrum is characterized in detail for the first time, for all Z≤ 45 and A that cover all known isotopes. The eigenvalues are mapped one-to-one to those of the traditional Dirac Hydrogen spectrum. Numerical evaluations that go beyond Z=45 into the realm of not-yet-produced hydrogenic ions are presented, too. A list of challenging open problems concludes this publication.