The ELM Survey. I. A Complete Sample of Extremely Low Mass White Dwarfs

TL;DR

This study presents a complete sample of extremely low-mass white dwarfs, revealing their binary nature, potential merger outcomes, and implications for gravitational wave sources and supernovae.

Contribution

It provides the first complete, well-defined sample of ELM white dwarfs, analyzing their binary properties, merger times, and potential as progenitors for various astrophysical phenomena.

Findings

11 of 12 WDs are in short-period binaries

Several systems will merge within a Hubble time

Some systems may evolve into stable AM CVn binaries

Abstract

We analyze radial velocity observations of the 12 extremely low-mass <0.25 Msol white dwarfs (WDs) in the MMT Hypervelocity Star Survey. Eleven of the 12 WDs are binaries with orbital periods shorter than 14 hours; the one non-variable WD is possibly a pole-on system among our non-kinematically selected targets. Our sample is unique: it is complete in a well-defined range of apparent magnitude and color. The orbital mass functions imply that the unseen companions are most likely other WDs, although neutron star companions cannot be excluded. Six of the 11 systems with orbital solutions will merge within a Hubble time due to the loss of angular momentum through gravitational wave radiation. The quickest merger is J0923+3028, a g=15.7 ELM WD binary with a 1.08 hr orbital period and a <130 Myr merger time. The chance of a supernova Ia event among our ELM WDs is only 1%-7%, however. Three binary systems (J0755+4906, J1233+1602, and J2119-0018) have extreme mass ratios and will most likely form stable mass-transfer AM CVn systems. Two of these objects, SDSS J1233+1602 and J2119-0018, are the lowest surface gravity WDs ever found; both show Ca II absorption likely from accretion of circumbinary material. We predict that at least one of our WDs is an eclipsing detached double WD system, important for constraining helium core WD models.