A systematic survey for hypervelocity runaways from thermonuclear supernovae

Abstract

The explosion of a white dwarf (WD) in a close binary can launch a surviving runaway star at velocities of 1000\, km\,s-1. Such runaways provide a direct probe of thermonuclear supernovae (SNe) in double-degenerate binaries. Several candidate runaways are known, but their evolutionary states and the demographics of the broader population are uncertain. To enable robust population inference, we carry out a systematic survey for hypervelocity runaways with a simple selection function, selecting candidates based on large Gaia-inferred tangential velocities and blue colors. We classify 100% of the resulting 92 candidates using a combination of spectroscopic follow-up and archival data. The search yields ten suspected D6 stars and three LP 40-365 stars. Three D6 stars are new discoveries, including two hot (T eff > 50,000 K) objects and one cool (T eff≈ 7,000 K) object. We forward-model our survey under several proposed D6 star evolutionary models, coupling each to a Galactic model and the survey selection function. No single model reproduces the observed diversity of D6 stars, which likely reflects a range of remnant masses, ages, and heating mechanisms. Models in which runaway companions are heated by SN shocks alone are too faint and short-lived to explain most of the observed sample, while fully reheated models are too luminous and long-lived. Models with intermediate heating, as occurs in some simulations of violent mergers and partially disrupted remnants, best match the observed magnitude, distance, and kinematic-age distributions. The inferred D6 star birth rate is model dependent, but the models that best match the observed population require rates of only a few percent of the Galactic SN Ia rate, perhaps implying that most SNe Ia result from WD binaries in which both components explode.