Evolution of low mass close binary systems with a neutron star: its dependence with the initial neutron star mass

TL;DR

This study models the evolution of low-mass close binary systems with neutron stars, examining how initial neutron star mass influences their development and final configurations, including ultra-compact and millisecond pulsar-white dwarf pairs.

Contribution

It introduces a comprehensive set of binary evolution models considering various initial neutron star masses, revealing their impact on system evolution and proposing a new period-mass relation.

Findings

Evolution heavily depends on initial neutron star mass.

Final orbital period-white dwarf mass relation is insensitive to initial neutron star mass.

New period-mass relation aligns well with existing literature.

Abstract

We construct a set of binary evolutionary sequences for systems composed by a normal, solar composition, donor star together with a neutron star. We consider a variety of masses for each star as well as for the initial orbital period corresponding to systems that evolve to ultra-compact or millisecond pulsar-helium white dwarf pairs. Specifically, we select a set of donor star masses of 0.50, 0.65, 0.80, 1.00, 1.25, 1.50, 1.75, 2.00, 2.25, 2.50, 3.00, and 3.50 solar masses, whereas for the accreting neutron star we consider initial masses values of 0.8, 1.0, 1.2, and 1.4 solar masses. The considered initial orbital period interval ranges from 0.5 to 12 days. It is found that the evolution of systems, with fixed initial values for the orbital period and the mass of the normal donor star, heavily depends upon the mass of the neutron star. In some cases, varying the initial value of the neutron star mass, we obtain evolved configurations ranging from ultra-compact to widely separated objects. We also analyse the dependence of the final orbital period with the mass of the white dwarf. In agreement with previous expectations, our calculations show that the final orbital period-white dwarf mass relation is fairly insensitive to the initial neutron star mass value. A new period-mass relation based on our own calculations is proposed, which is in good agreement with period-mass relations available in the literature. As consequence of considering a set of values for the initial neutron star mass, these models allow finding different plausible initial configurations (donor and neutron star masses and orbital period interval) for some of the best observed binary systems of the kind we are interested in here. We apply our calculations to analyse the case of PSR J0437-4715.