A Singular One-Dimensional Bound State Problem and its Degeneracies
Abstract
We give a brief exposition of the formulation of the bound state problem for the one-dimensional system of attractive Dirac delta potentials, as an matrix eigenvalue problem (). The main aim of this paper is to illustrate that the non-degeneracy theorem in one dimension breaks down for the equidistantly distributed Dirac delta potential, where the matrix becomes a special form of the circulant matrix. We then give an elementary proof that the ground state is always non-degenerate and the associated wave function may be chosen to be positive by using the Perron-Frobenius theorem. We also prove that removing a single center from the system of delta centers shifts all the bound state energy levels upward as a simple consequence of the Cauchy interlacing theorem.
Cite
@article{arxiv.1703.03345,
title = {A Singular One-Dimensional Bound State Problem and its Degeneracies},
author = {F. Erman and M. Gadella and Ş. Tunalı and H. Uncu},
journal= {arXiv preprint arXiv:1703.03345},
year = {2017}
}
Comments
Major modifications: title changed, typos corrected, clarifications added, published version