Hyperon-nucleon three-body forces and strangeness in neutron stars

Abstract

Three-body forces acting on a hyperon in a nuclear medium are investigated, with special focus on the so-called hyperon puzzle in neutron stars. The hyperon-nucleon two-body interaction deduced from SU(3) chiral effective field theory is employed at next-to-leading order. Hyperon-nucleon three-body forces are approximated using saturation by decuplet baryons and are transcribed to density-dependent effective two-body interactions. These together are taken as input in a Brueckner-Bethe-Goldstone equation with explicit treatment of the N N and NN NN coupled channels. Single-particle potentials of a hyperon in symmetric nuclear matter and neutron matter are calculated. With parameters of the NN three-body force constrained by hypernuclear phenomenology, extrapolations to high baryon density are performed. By comparison of the and neutron chemical potentials at densities characteristic of the core of neutron stars it is found that the combined repulsive effects of two- and three-body correlations makes the appearance of hyperons in neutron stars energetically unfavourable, thus offering a possible solution to a longstanding question.