Population Synthesis for Symbiotic X-ray Binaries

TL;DR

This study uses population synthesis modeling to estimate the birthrate and number of symbiotic X-ray binaries in the Galaxy, highlighting the influence of stellar wind velocity on their observational properties.

Contribution

It introduces a detailed simulation approach for symbiotic X-ray binaries, focusing on parameters affecting their observability and estimating their Galactic population.

Findings

Estimated Galactic SyXB population: 100-1000 systems.

Stellar wind velocity from cool giants significantly impacts SyXB population.

Identified candidate systems with long spin periods potentially hosting quasi-spherical accreting neutron stars.

Abstract

Symbiotic X-ray binaries (SyXBs) comprise a rare class of low-mass X-ray binaries. We study the Galactic SyXBs, which we consider as detached binaries composed of low-mass giants and wind-fed neutron star companions, by simulation of the interaction of a magnetized neutron star (NS) with its environment and utilizing a population synthesis code. We focus mainly on the parameters that influence observational appearance of the SyXB: the donor wind velocity (vw) and the angular momentum distribution in the shell of matter settling onto NS. We estimate the birthrate of SyXB as $\sim 4.1\times 10^{-5}$ yr$^{-1}$ to $ \sim 6.6\times 10^{-6}$ yr$^{-1}$ and their number in the Galaxy as $\sim$(100 -- 1000). Assumed stellar wind velocity from cool giants is the input parameter that influences the model SyXBs population most. Among known SyXBs or candidate systems, 4U 1954+31 and IGR J16358-4724 in which NS have very long spin periods may host quasi-spherically accreting NSs. GX 1+4 has a peculiar long-term spin behaviour and it may also be a quasi-spherical wind-accreting source. We cannot identify whether there are wind-fed accretion disks in 4U 1700+24, Sct X-1, IRXS J180431.1-273932 and 2XMM J174016.0-290337.