Rapidly rotating neutron star progenitors
Abstract
Rotating proto-neutron stars can be important sources of gravitational waves to be searched for by present-day and future interferometric detectors. It was demonstrated by Imshennik that in extreme cases the rapid rotation of a collapsing stellar core may lead to fission and formation of a binary proto-neutron star which subsequently merges due to gravitational wave emission. In the present paper, we show that such dynamically unstable collapsing stellar cores may be the product of a former merger process of two stellar cores in a common envelope. We applied population synthesis calculations to assess the expected fraction of such rapidly rotating stellar cores which may lead to fission and formation of a pair of proto-neutron stars. We have used the BSE population synthesis code supplemented with a new treatment of stellar core rotation during the evolution via effective core-envelope coupling, characterized by the coupling time, . The validity of this approach is checked by direct MESA calculations of the evolution of a rotating 15 star. From comparison of the calculated spin distribution of young neutron stars with the observed one, reported by Popov and Turolla, we infer the value years. We show that merging of stellar cores in common envelopes can lead to collapses with dynamically unstable proto-neutron stars, with their formation rate being of the total core collapses, depending on the common envelope efficiency.
Cite
@article{arxiv.1608.04548,
title = {Rapidly rotating neutron star progenitors},
author = {K. A. Postnov and A. G. Kuranov and D. A. Kolesnikov and S. B. Popov and N. K. Porayko},
journal= {arXiv preprint arXiv:1608.04548},
year = {2016}
}
Comments
10 pages, 4 figures, accepted for publication in MNRAS