U-spin symmetry energy and hyperon puzzle

Abstract

By combining the (u,d) I-spin doublets or (d,s) U-spin doublets, the SU(3) flavor symmetry of light quarks can be decomposed into SU(2)I×U(1)Y or SU(2)U×U(1)Q subgroups, which have been widely adopted to categorize hadrons and their decay properties. The I-spin counterpart for the interactions among nucleons has been extensively investigated, i.e., the nuclear symmetry energy Esym(nb), which characterizes the variation of binding energy as the neutron to proton ratio in a nuclear system. In this work, we propose U-spin symmetry energy EU(nb) for hyperonic matter to characterize the variation of binding energy with the inclusion of hyperons. In particular, being the lightest hyperon, Λ hyperons are included in dense matter, where the U-spin symmetry energy EU(nb) is fixed according to state-of-the-art constraints from nuclear physics and astrophysical observations using Bayesian inference approach. It is found that EU(nb) is much smaller than that of Esym(nb), indicating much stronger proton-neutron attraction than that of nucleon-hyperon pairs. Consequently, the Λ hyperon potential increases significantly with density and becomes repulsive at high densities. The results indicate that there is more than 50\% probability for the emergence of Λ hyperons in posterior EOSs, which are likely to vanish at densities nb 5\,n0. In scenarios where Λ hyperons do emerge, the onset density nbΛ is typically within the range of 2\,n0--5\,n0, corresponding to neutron stars more massive than 1.0\,M.