Convexity and potential sums for Salpeter-like Hamiltonians

Abstract

The semirelativistic Hamiltonian H = βm2 + p2 + V(r), where V(r) is a central potential in R3, is concave in p2 and convex in p. This fact enables us to obtain complementary energy bounds for the discrete spectrum of H. By extending the notion of 'kinetic potential' we are able to find general energy bounds on the ground-state energy E corresponding to potentials with the form V = sumiaif(i)(r). In the case of sums of powers and the log potential, where V(r) = sumq 0 a(q) sgn(q)rq + a(0)ln(r), the bounds can all be expressed in the semi-classical form E ≈ rβm2 + 1/r2 + sumq 0 a(q)sgn(q)(rP(q))q + a(0)ln(rP(0)). 'Upper' and 'lower' P-numbers are provided for q = -1,1,2, and for the log potential q = 0. Some specific examples are discussed, to show the quality of the bounds.

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