English

$\Omega$-deuteron Interaction in Folding Model

Nuclear Theory 2021-12-14 v5

Abstract

A simple single folding model for Ω\Omega-deuteron with maximal spin (I)JP=(0)5/2+\left(I\right)J^{P}=\left(0\right)5/2^{+} is investigated. Ω\Omega is assumed to orbit an unperturbed deuteron in a Ω\Omega-deuteron potential based on a separable Ω\Omega-nucleon potential from lattice QCD. We show that the effective central folding potential of Ωd\Omega d in the 5S2^{5}S_{2} channel has a simple Wood-Saxon form, and approximate the upper bound for the binding energy of Ω\Omega particle on a deuteron. In order to investigate how changes in the wave functions affect the results, we consider four analytical forms for SS-state deuteron wave functions, i.e., two widely used Hulth\'en forms, as well as the modified Reid93 and Argonne v18 forms. Our calculations of binding energy from simple two-body approximation are compared with the results reported for the three-body problem; it is confirmed that the Ωd\Omega d system is deeply bound. Although the single folding model reduces the three-body problem to a two-body problem, this simplification is inadequate.

Keywords

Cite

@article{arxiv.1908.11484,
  title  = {$\Omega$-deuteron Interaction in Folding Model},
  author = {Faisal Etminan and Mohammad Mehdi Firoozabadi},
  journal= {arXiv preprint arXiv:1908.11484},
  year   = {2021}
}
R2 v1 2026-06-23T11:00:29.930Z