Modeling X-ray binary evolution in normal galaxies: Insights from SINGS

TL;DR

This study compares observed and theoretical X-ray binary populations in galaxies, using Chandra data and population synthesis models, to improve understanding of XRB evolution and their relation to galaxy properties.

Contribution

It provides the largest-scale comparison between observed and modeled extragalactic XRB populations, identifying model limitations and key parameters influencing XRB evolution.

Findings

Models reproduce about half of observed XLFs.

Best models suggest specific common envelope and initial mass-ratio parameters.

Galaxy X-ray luminosity correlates with star formation rate and stellar mass.

Abstract

We present the largest-scale comparison to date between observed extragalactic X-ray binary (XRB) populations and theoretical models of their production. We construct observational X-ray luminosity functions (oXLFs) using Chandra observations of 12 late-type galaxies from the Spitzer Infrared Nearby Galaxy Survey (SINGS). For each galaxy, we obtain theoretical XLFs (tXLFs) by combining XRB synthetic models, constructed with the population synthesis code StarTrack, with observational star formation histories (SFHs). We identify highest-likelihood models both for individual galaxies and globally, averaged over the full galaxy sample. Individual tXLFs successfully reproduce about half of oXLFs, but for some galaxies we are unable to find underlying source populations, indicating that galaxy SFHs and metallicities are not well matched and/or XRB modeling requires calibration on larger observational samples. Given these limitations, we find that best models are consistent with a product of common envelope ejection efficiency and central donor concentration ~=0.1, and a 50% uniform -- 50% "twins" initial mass-ratio distribution. We present and discuss constituent subpopulations of tXLFs according to donor, accretor and stellar population characteristics. The galaxy-wide X-ray luminosity due to low-mass and high-mass XRBs, estimated via our best global model tXLF, follows the general trend expected from the L_x - star formation rate and L_x - stellar mass relations of Lehmer et al 2010. Our best models are also in agreement with modeling of the evolution both of XRBs over cosmic time and of the galaxy X-ray luminosity with redshift.