A New Proof of Existence of a Bound State in the Quantum Coulomb Field

Abstract

Let S(x) be a massless scalar quantum field which lives on the three-dimensional hyperboloid xx= (x0)2-(x1)2-(x2)2-(x3)2=-1. The classical action is assumed to be (=1=c)(8π e2)-1∫ dx gik∂i S∂k S, where e2 is the coupling constant, dx is the invariant measure on the de Sitter hyperboloid xx=-1 and gik, i,k=1,2,3, is the internal metric on this hyperboloid. Let u be a fixed four-velocity. The field S(u)=(1/4 π)∫ dxδ(ux)S(x)is smooth enough to be exponentiated. We prove that if 0<e2<π, then the state |u>=(-iS(u)) 0>, where 0> is the Lorentz invariant vacuum state, contains a normalizable eigenstate of the Casimir operator C1=-(1/2)MμMμ; Mμ are generators of the proper orthochronous Lorentz group. This theorem was first proven by the Author in 1992 in his contribution to the Czyz Festschrift, see Erratum Acta Phys. Pol. B 23, 959 (1992). In this paper a completely different proof is given: we derive the partial, differential equation satisfied by the matrix element <u (-σ C1) u>, σ > 0, and show that the function (z)· (1-z)· [-σ z (2-z)], z= e2/ π, is an exact solution of this differential equation, recovering thus both the eigenvalue and the probability of occurrence of the bound state.