Bound states of cc9Be within cc+α+α cluster models based on state-of-the-art HAL QCD charmonium-nucleon interactions

Abstract

The possible bound state of the cc9Be, a charmonium-nucleus system, is investigated. The analysis is carried out within a three-cluster model, where its binary subsystems are represented as cc+α and α+α. The hyperspherical harmonics method is employed to facilitate a convenient description of this three-cluster configuration. The calculations are done by employing the effective cc-α potentials. These potentials were derived recently based on state-of-the-art lattice QCD calculations, which provided interactions for the spin 3/2 J/ N , spin 1/2 J/ N , spin 1/2 ηcN and spin-averaged J/ N interactions, all obtained with nearly physical pion masses. The Coulomb interaction was also incorporated into the current calculations. It is determined that, despite neither the cc5He nor the 8Be binary subsystems being bound, a bound state of the cc- αα nuclear system could potentially exist. The maximum central binding energy is found to be approximately 1.71 MeV, based on the spin 1/2 J/ N interaction, while a minimum value of about 0.56 MeV is obtained from calculations involving the spin 1/2 ηcN interaction.