Open AccessPreservation of logarithmic concavity by the Mellin transform and applications to the Schrödinger equation for certain classes of potentials
Author(s) -
A.K. Common,
A. Martin,
J. Stubbe
Publication year - 1990
Publication title -
communications in mathematical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.662
H-Index - 152
eISSN - 1432-0916
pISSN - 0010-3616
DOI - 10.1007/bf02098444
Subject(s) - wkb approximation , mellin transform , mathematics , convexity , ground state , logarithm , laplace transform , mathematical analysis , laplace operator , schrödinger equation , wave function , function (biology) , generalization , two sided laplace transform , mathematical physics , pure mathematics , physics , quantum mechanics , fourier transform , fractional fourier transform , fourier analysis , evolutionary biology , financial economics , economics , biology
We prove that the Mellin transform of a function log-concave (convex) is, after division by Γ(ν+1), where ν is the argument of the transform, itself log-concave (convex) in ν. This theorem is first applied to the moments of the ground state wave function of the Schrödinger equation where the Laplacian of the central potential has a given sign, and generalized to other situations. This is used to derive inequalities linking thelth derivative of the ground state wave function at the origin for angular momentuml and the expectation value of the kinetic energy, and applied to quarkonium physics. A generalization to higher radial excitations is shown to be plausible by using the WKB approximation. Finally, new bounds on ground-state energies in power potentials are obtained.
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