Constraints from hypernuclei on the NN content of the -nucleus potential

Abstract

A depth of D≈ -28 MeV for the -nucleus potential was confirmed in 1988 by studying binding energies deduced from (π+,K+) spectra measured across the periodic table. Modern two-body hyperon-nucleon interaction models require additional interaction terms, most likely NN three-body terms, to reproduce D. In this work we apply a suitably constructed -nucleus density dependent optical potential to binding energy calculations of observed 1s and 1p states in the mass range 12≤ A≤ 208. The resulting NN contribution to D, about 14 MeV repulsion at symmetric nuclear matter density 0=0.17 fm-3, makes D increasingly repulsive at 30, leading possibly to little or no hyperon content of neutron-star matter. This suggests in some models a stiff equation of state that may support two solar-mass neutron stars.