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Lambda-nuclear interactions and hyperon puzzle in neutron stars

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arxiv 1612.03758 v2 pith:JZUPRNBW submitted 2016-12-12 nucl-th astro-ph.HE

Lambda-nuclear interactions and hyperon puzzle in neutron stars

classification nucl-th astro-ph.HE
keywords lambdahyperonneutroninteractionsstarschiraleffectivematter
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Brueckner theory is used to investigate the in-medium properties of a $\Lambda$-hyperon in nuclear and neutron matter, based on hyperon-nucleon interactions derived within SU(3) chiral effective field theory (EFT). It is shown that the resulting $\Lambda$ single-particle potential $U_\Lambda(p_\Lambda =0,\rho)$ becomes strongly repulsive for densities $\rho$ of two-to-three times that of normal nuclear matter. Adding a density-dependent effective $\Lambda N$-interaction constructed from chiral $\Lambda NN$ three-body forces increases the repulsion further. Consequences of these findings for neutron stars are discussed. It is argued that for hyperon-nuclear interactions with properties such as those deduced from the SU(3) EFT potentials, the onset for hyperon formation in the core of neutron stars is expected to be shifted to extremely high baryon density, thus potentially resolving the so-called hyperon puzzle.

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  1. Astrophysical constraints on the cold equation of state of the strongly interacting matter

    astro-ph.HE 2025-12 unverdicted novelty 4.0

    Neutron star observations, especially the heaviest known pulsar masses and GW170817 tidal deformability, provide the strongest restrictions on the allowed cold dense matter equation of state.