Formation of millisecond pulsars with CO white dwarf companions - I. PSR J1614-2230: Evidence for a neutron star born massive

TL;DR

This paper investigates the progenitor evolution of the massive millisecond pulsar PSR J1614-2230, suggesting it was born with a mass significantly higher than typical neutron stars, which impacts understanding of neutron star formation and supernovae.

Contribution

It presents detailed stellar evolution models for the progenitor binary system of PSR J1614-2230, proposing new formation scenarios and neutron star birth mass estimates.

Findings

Neutron star likely born with ~1.95 M_sun or 1.7±0.15 M_sun.

Progenitor star probably more massive than 20 M_sun.

Two viable formation pathways identified involving different binary evolution processes.

Abstract

The recent discovery of a 2 M_sun binary millisecond pulsar (Demorest et al. 2010) has not only important consequences for the equation-of-state of nuclear matter at high densities but also raises the interesting question if the neutron star PSR J1614-2230 was born massive. The answer is vital for understanding neutron star formation in core collapse supernovae. Furthermore, this system raises interesting issues about the nature of the progenitor binary and how it evolved during its mass exchanging X-ray phase. In this paper we discuss the progenitor evolution of PSR J1614-2230. We have performed detailed stellar evolution modelling of intermediate-mass X-ray binaries undergoing Case A Roche-lobe overflow (RLO) and applied an analytic parameterization for calculating the outcome of either a common envelope evolution or the highly super-Eddington isotropic re-emission mode. We find two viable possibilities for the formation of the PSR J1614-2230 system: either it contained a 2.2-2.6 M_sun giant donor star and evolved through a common envelope and spiral-in phase or, more likely, it descended from a close binary system with a 4.0-5.0 M_sun main sequence donor star via Case A RLO. We conclude that the neutron star must have been born with a mass of ~1.95 M_sun or 1.7+-0.15 M_sun, respectively - which significantly exceeds neutron star birth masses in previously discovered radio pulsar systems. Based on the expected neutron star birth masses from considerations of stellar evolution and explosion models, we find that the progenitor star of PSR J1614-2230 is likely to have been more massive than 20 M_sun.