Second Quantization for the Kepler Problem

Abstract

The Kepler problem concerns a point particle in an attractive inverse square force. After a brief review of the classical and quantum versions of this problem, focused on their hidden SU(2) × SU(2) symmetry, we discuss the quantum Kepler problem for a spin-12 particle. We show that the Hilbert space H of bound states for this problem is unitarily equivalent, as a representation of SU(2) × SU(2), to the Hilbert space of solutions of the Weyl equation on the spacetime R × S3. This equation describes a massless left-handed spin-12 particle. We then form the fermionic Fock space on H and show this is unitarily equivalent to the Hilbert space of a massless left-handed spin-12 free quantum field on R × S3, again as representations of SU(2) × SU(2). By modifying the Hamiltonian of this free field theory, we obtain the well-known "Madelung rules". These give a reasonable approximation to the observed filling of subshells as we consider elements with more and more electrons, and match the rough overall structure of the periodic table.