Binary white dwarfs in the halo of the Milky Way

TL;DR

This study models the evolution of halo white dwarfs in the Milky Way to understand their origins, star formation history, and binary fraction, using simulations and comparing with observational data from the SuperCOSMOS Sky Survey and Gaia.

Contribution

It introduces detailed simulations of halo white dwarf populations with different initial conditions and predicts observable properties, aiding interpretation of upcoming Gaia data.

Findings

A standard IMF aligns better with observations than a top-heavy IMF.

A star formation burst 13 Gyr ago fits the data slightly better than other models.

Gaia will help constrain the bright end of the halo white dwarf luminosity function.

Abstract

Aims: We study single and binary white dwarfs in the inner halo of the Milky Way in order to learn more about the conditions under which the population of halo stars was born, such as the initial mass function (IMF), the star formation history, or the binary fraction. Methods: We simulate the evolution of low-metallicity halo stars at distances up to ~ 3 kpc using the binary population synthesis code SeBa. We use two different white dwarf cooling models to predict the present-day luminosities of halo white dwarfs. We determine the white dwarf luminosity functions (WDLFs) for eight different halo models and compare these with the observed halo WDLF of white dwarfs in the SuperCOSMOS Sky Survey. Furthermore, we predict the properties of binary white dwarfs in the halo and determine the number of halo white dwarfs that is expected to be observed with the Gaia satellite. Results: By comparing the WDLFs, we find that a standard IMF matches the observations more accurately than a top-heavy one, but the difference with a bottom-heavy IMF is small. A burst of star formation 13 Gyr ago fits slightly better than a star formation burst 10 Gyr ago and also slightly better than continuous star formation $10-13$ Gyrs ago. Gaia will be the first instrument to constrain the bright end of the field halo WDLF, where contributions from binary WDs are considerable. Many of these will have He cores, of which a handful have atypical surface gravities ($\log g < 6$) and reach luminosities $\log(L/L_\odot) > 0$ in our standard model for WD cooling. These so called pre-WDs, if observed, can help us to constrain white dwarf cooling models and might teach us something about the fraction of halo stars that reside in binaries.