English

Polynomial potentials and nilpotent groups

Mathematical Physics 2025-04-21 v2 math.MP

Abstract

This paper deals with the partial solution of the energy-eigenvalue problem for one-dimensional Schr\"odinger operators of the form HN=X02+VNH_N=X_0^2+V_N, where VN=XN2+αXN1V_N=X_N^2+\alpha X_{N-1} is a polynomial potential of degree (2N2)(2N-2) and XiX_i are the generators of an irreducible representation of a particular nilpotent group GN\mathcal{G}_N. Algebraization of the eigenvalue problem is achieved for eigenfunctions of the form k=0MakX2kexp(dxXN)\sum_{k=0}^M a_k X_2^k \exp(-\int dx\, X_N). It is shown that the overdetermined linear system of equations for the coefficients aka_k has a nontrivial solution, if the parameter α\alpha and (N3)(N-3) Casimir invariants satisfy certain constraints. This general setting works for even N2N\geq 2 and can also be applied to odd N3N\geq 3, if the potential is symmetrized by considering it as function of x|x| rather than xx. It provides a unified approach to quasi-exactly solvable polynomial interactions, including the harmonic oscillator, and extends corresponding results known from the literature. Explicit expressions for energy eigenvalues and eigenfunctions are given for the quasi-exactly solvable sextic, octic and decatic potentials. The case of E=0E=0 solutions for general NN and MM is also discussed. As physical application, the movement of a charged particle in an electromagnetic field of pertinent polynomial form is shortly sketched.

Keywords

Cite

@article{arxiv.2412.11157,
  title  = {Polynomial potentials and nilpotent groups},
  author = {W. Schweiger and W. H. Klink},
  journal= {arXiv preprint arXiv:2412.11157},
  year   = {2025}
}

Comments

42 pages, 8 figures, revised and slightly extended version

R2 v1 2026-06-28T20:35:46.668Z