Skyrmion Stars: Astrophysical motivations and implications
Abstract
We study mass-radius relations for compact stars employing an equation of state (EOS) of dense matter based on a Skyrme fluid. The zero-temperature mean-field model is based on mesonic excitations, incorporates the scale breaking of QCD, and accommodates baryons (nucleons) which arise as a solitonic configuration of mesonic fields. Stable configurations are obtained for central densities c/n≤ 5.0 where n=2.575× 1014 g/cc is the nuclear saturation density. These Skyrmion Stars are mostly fluid, with a crust which we describe by the EOS of Baym, Pethick and Sutherland. Their masses and radii are in the range 0.4 M/M 3.6 and 13 km R 23 km, respectively. The minimum spin period is computed to be between 0.7 ms P 2.1 ms. They appear to have a mass-radius curve quite different from either neutron or quark stars, and provide a suitable description of the heavier mass neutron stars discovered recently due to the inherently stiff EOS. Within the same model, we compute the dominant neutrino emissivity in neutron-rich β-equilibrated matter, and determine the cooling behaviour of Skyrmion stars.
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