NN input to neutron stars from hypernuclear data
Abstract
This work is a sequel to our two 2023 publications [PLB 837 137669, NPA 1039 122725] where fitting 14 1s and 1p single-particle binding energies in hypernuclei across the periodic table led to a well-defined -nucleus optical potential. The potential consists of a Pauli modified linear-density ( N) and a quadratic-density ( NN) terms. The present work reports on extending the above analysis to 21 single-particle data points input by including 1d and 1f states in medium-weight and heavy hypernuclei. The upgraded results for the N and NN potential depths at nuclear-matter density 0=0.17~fm-3, D(2)=-37.5 0.7~MeV and D(3)=+9.8 1.2~MeV together with the total depth D=-27.7 0.5~MeV, agree within errors with the earlier results. The hypernuclear overbinding associated with the N-induced potential depth D(2) agrees quantitatively with a recent combined analysis of low-energy p scattering data and correlation functions [PLB 850 (2024) 138550]. These results, particularly the size of the repulsive D(3), provide an essential input towards resolving the 'hyperon puzzle' in the core of neutron stars. We also show that a key property of our NN-induced potential term, i.e. a need to suppress the quadratic-density NN term involving an excess neutron and a N=Z core nucleon, can be tested in the forthcoming JLab E12-15-008 experiment.
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