Folding procedure for Ω-α potential
Abstract
Using the folding procedure, we investigate the bound state of the Ω+α system based on Ω-N (5S2) HAL QCD potential. Previous theoretical analyses have indicated the existence of a deeply bound ground state, which is attributed to the strong Ω-nucleon interaction. By employing well-established parameterizations of nucleon density within the alpha particle, and the central HAL QCD Ω-N potential, we performed numerical calculations for the folding Ω-α potential. Our results show that the VΩα(r) potential can be accurately fitted using a Woods-Saxon function, with a phenomenological parameter R = 1.1A1/3 ≈ 1.74 fm (A=4) in the asymptotic region where 2 < r < 3 fm. We provide a thorough description of the corresponding numerical procedure. Our evaluation of the binding energy of the Ω+α system within the cluster model is consistent with both previous and recent reported findings. To further validate the folding procedure, we also calculated the Ξ-α folding potential based on a simulation of the ESC08c Y-N Nijmegen model. A comprehensive comparison between the Ξ-α folding and Ξ- α phenomenological potentials is presented and discussed.
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