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A Regularized $(XP)^2$ Model

Quantum Physics 2024-02-08 v2 High Energy Physics - Phenomenology High Energy Physics - Theory Mathematical Physics math.MP

Abstract

We investigate a dynamic model described by the classical Hamiltonian H(x,p)=(x2+a2)(p2+a2)H(x,p)=(x^2+a^2)(p^2+a^2), where a2>0a^2>0, in classical, semi-classical, and quantum mechanics. In the high-energy EE limit, the phase path resembles that of the (XP)2(XP)^2 model. However, the non-zero value of aa acts as a regulator, removing the singularities that appear in the region where x,p0x, p \sim 0, resulting in a discrete spectrum characterized by a logarithmic increase in state density. Classical solutions are described by elliptic functions, with the period being determined by elliptic integrals. In semi-classical approximation, we speculate that the asymptotic Riemann-Siegel formula may be interpreted as summing over contributions from multiply phase paths. We present three different forms of quantized Hamiltonians, and reformulate them into the standard Schr\" odinger equation with cosh2x\cosh 2x-like potentials. Numerical evaluations of the spectra for these forms are carried out and reveal minor differences in energy levels. Among them, one interesting form possesses Hamiltonian in the Schr\" odinger equation that is identical to its classical version. In such scenarios, the eigenvalue equations can be expressed as the vanishing of the Mathieu functions' value at ii\infty points, and furthermore, the Mathieu functions can be represented as the wave functions.

Keywords

Cite

@article{arxiv.2308.11648,
  title  = {A Regularized $(XP)^2$ Model},
  author = {Yu-Qi Chen and Zhao-Feng Ge},
  journal= {arXiv preprint arXiv:2308.11648},
  year   = {2024}
}
R2 v1 2026-06-28T12:01:47.216Z