On the Spatially Resolved Star Formation History in M51. II. X-Ray Binary Population Evolution

• Published in: The Astrophysical journal Vol. 851; no. 1; pp. 11 - 29
• Main Authors: Lehmer, B. D., Eufrasio, R. T., Markwardt, L., Zezas, A., Basu-Zych, A., Fragos, T., Hornschemeier, A. E., Ptak, A., Tzanavaris, P., Yukita, M.
• Format: Journal Article
• Language: English
• Published: Philadelphia The American Astronomical Society 10.12.2017; IOP Publishing
• Subjects: Age; Astronomical models; Astrophysics; Binary stars; Galaxies; galaxies: evolution; galaxies: individual (M51); Luminosity; Spiral galaxies; Star & galaxy formation; Star formation; Star formation rate; Stars & galaxies; Stellar age; Stellar evolution; Stellar mass; Stellar models; Stellar populations; X ray binaries; X ray sources; X ray stars; X-rays: binaries; X-rays: galaxies
• ISSN: 0004-637X; 1538-4357
• DOI: 10.3847/1538-4357/aa9578

We present a new technique for empirically calibrating how the X-ray luminosity function (XLF) of X-ray binary (XRB) populations evolves following a star formation event. We first utilize detailed stellar population synthesis modeling of far-UV-to-far-IR photometry of the nearby face-on spiral galaxy M51 to construct maps of the star formation histories (SFHs) on subgalactic ( 400 pc) scales. Next, we use the 850 ks cumulative Chandra exposure of M51 to identify and isolate 2-7 keV detected point sources within the galaxy, and we use our SFH maps to recover the local properties of the stellar populations in which each X-ray source is located. We then divide the galaxy into various subregions based on their SFH properties (e.g., star formation rate (SFR) per stellar mass and mass-weighted stellar age) and group the X-ray point sources according to the characteristics of the regions in which they are found. Finally, we construct and fit a parameterized XLF model that quantifies how the XLF shape and normalization evolves as a function of the XRB population age Our best-fit model indicates that the XRB XLF per unit stellar mass declines in normalization, by ∼3-3.5 dex, and steepens in slope from 10 Myr to 10 Gyr. We find that our technique recovers results from past studies of how XRB XLFs and XRB luminosity scaling relations vary with age and provides a self-consistent picture for how XRB XLFs evolve with age.