Evolution of neutron stars in wide eccentric low-mass binary systems

TL;DR

This paper models the evolution of neutron stars in wide, eccentric low-mass binary systems, showing how orbital eccentricity influences the timing of accretion onset and the neutron star's evolutionary stages.

Contribution

It introduces a detailed model of magneto-rotational evolution of neutron stars considering orbital eccentricity, highlighting how eccentricity affects accretion timing.

Findings

Higher eccentricity shortens the ejector stage, enabling earlier accretion.

Neutron stars with stronger magnetic fields start accreting sooner.

Eccentricity and magnetic field strength significantly influence neutron star evolution.

Abstract

Precise astrometric measurement with Gaia satellite resulted in the discovery of tens of wide binary systems consisting of a Sun-like star and an invisible component. The latter can be a white dwarf, a neutron star, or a black hole. In this paper, we model magneto-rotational evolution of neutron stars in wide low-mass binaries accounting for the orbital eccentricity. We aim to calculate when neutron stars in such systems can start to accrete matter from the stellar wind of the companion. We show that the transition from the ejector to the propeller stage occurs earlier in more eccentric systems, thus increasing the time that neutron stars can spend accreting matter. Our calculations show that in the case of efficient spin-down at the propeller stage, a neutron star in an eccentric orbit with $e\gtrsim0.6$ and a standard magnetic field $B=10^{12}$ G can start accreting within a few Gyr. For neutron stars with $B=10^{13}$ G the onset of accretion occurs earlier regardless of the orbital eccentricity. Otherwise, with a lower spin-down rate, such a neutron star will remain at the propeller stage for most of its life.