Novel Model of an Ultra-stripped Supernova Progenitor of a Double Neutron Star
Abstract
Recent discoveries of double neutron star (DNS) mergers and ultra-stripped supernovae (SNe) raise the questions of their origin and connection. We present the first 1D~model of a DNS progenitor system which is calculated self-consistently until an ultra-stripped iron core collapse. We apply the MESA code starting from a post-common envelope binary consisting of a 1.35\;M NS and a 3.20\;M zero-age main-sequence helium star and continue the modelling via Case~BB Roche-lobe overflow until the infall velocity of the collapsing iron core exceeds 1000\; km\,s-1. The exploding star has a total mass of 1.90\;M, consisting of a 0.29\;M He-rich envelope embedding a CO core of 1.61\;M and an iron-rich core of 1.50\;M. The resulting second-born NS has an estimated mass of 1.44\;M and we discuss the fate of the post-SN system, as well as the mild recycling of the first-born NS. Depending on the initial conditions, this family of systems is anticipated to reproduce the DNS mergers detected by the LIGO-network.
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