General comparison theorems for the Klein-Gordon equation in d dimensions

Abstract

We study bound-state solutions of the Klein-Gordon equation (x) =[m2-(E-v\,f(x))2] (x), for bounded vector potentials which in one spatial dimension have the form V(x) = v\,f(x), where f(x) 0 is the shape of a finite symmetric central potential that is monotone non-decreasing on [0, ∞) and vanishes as x→∞. Two principal results are reported. First, it is shown that the eigenvalue problem in the coupling parameter v leads to spectral functions of the form v= G(E) which are concave, and at most uni-modal with a maximum near the lower limit E = -m of the eigenenergy E ∈ (-m, \, m). This formulation of the spectral problem immediately extends to central potentials in d > 1 spatial dimensions. Secondly, for each of the dimension cases, d=1 and d 2, a comparison theorem is proven, to the effect that if two potential shapes are ordered f1(r) ≤ f2(r), then so are the corresponding pairs of spectral functions G1(E) ≤ G2(E) for each of the existing eigenvalues. These results remove the restriction to positive eigenvalues necessitated by earlier comparison theorems for the Klein--Gordon equation.