Population synthesis of accreting white dwarfs: II. X-ray and UV emission

TL;DR

This study models accreting white dwarf populations to estimate their X-ray and UV emissions, comparing predictions with observations and discussing potential reasons for discrepancies in galaxy age-related emission levels.

Contribution

It provides a detailed population synthesis model for accreting white dwarfs' X-ray and UV emissions, incorporating evolutionary tracks and star formation histories, and compares results with observational data.

Findings

Predicted soft X-ray and He II line ratios match observations for ~10 Gyr old galaxies.

Model overpredicts emissions for galaxies younger than 4-8 Gyr.

Discrepancies may be due to assumptions about mass loss in giant stars.

Abstract

Accreting white dwarfs (WDs) with non-degenerate companions are expected to emit in soft X-rays and the UV, if accreted H-rich material burns stably. They are an important component of the unresolved emission of elliptical galaxies, and their combined ionizing luminosity may significantly influence the optical line emission from warm ISM. In an earlier paper we modeled populations of accreting WDs, first generating WD with main-sequence, Hertzsprung gap and red giant companions with the population synthesis code \textsc{BSE}, and then following their evolution with a grid of evolutionary tracks computed with \textsc{MESA}. Now we use these results to estimate the soft X-ray (0.3-0.7keV), H- and He II-ionizing luminosities of nuclear burning WDs and the number of super-soft X-ray sources for galaxies with different star formation histories. For the starburst case, these quantities peak at $\sim 1$ Gyr and decline by $\sim 1-3$ orders of magnitude by the age of 10 Gyr. For stellar ages of $\sim$~10 Gyr, predictions of our model are consistent with soft X-ray luminosities observed by Chandra in nearby elliptical galaxies and He II 4686$\AA/\rm{H}{\beta}$ line ratio measured in stacked SDSS spectra of retired galaxies, the latter characterising the strength and hardness of the UV radiation field. However, the soft X-ray luminosity and He~II~4686$\AA/\rm{H}{\beta}$ ratio are significantly overpredicted for stellar ages of $\lesssim 4-8$ Gyr. We discuss various possibilities to resolve this discrepancy and tentatively conclude that it may be resolved by a modification of the typically used criteria of dynamically unstable mass loss for giant stars.