Probing φ N interaction through bound states of φN-α system

Abstract

The possible bound state of the φ N α system is explored within the framework of the three-body cluster model. The calculations are done by employing the state-of-the-art φ N interactions obtained from the analysis of the pure elastic scattering and the coupled-channel in the φ p correlation functions. The φα potentials are constructed by two methods: the single-folding potential (SFP) method for the given spin-averaged φ N potentials in coordinate space, and the optical model potential (OMP) approximation within the multiple-scattering framework for the given scattering length of the φ N interaction. It is found that, when only the single-channel φ N interactions are employed, the φ N α system could be bound with a binding energy in the interval [3-26] MeV. However, the coupled-channel φ p interaction, which is most consistent with experimental measurements, does not yield any bound state, even when the spin-averaged φ N potential is employed, and this potential is found to be more attractive than the corresponding coupled-channel counterpart. It is essential to consider the contributions from the dynamics of the vector-baryon coupled channels φ p interaction. This effect is capable of playing a decisive role in the existence of mesic nuclei.