Helium White Dwarfs in Cataclysmic Variables

TL;DR

This paper investigates the evolution and observational signatures of helium core white dwarfs in cataclysmic variables, predicting rare nova events and long-term stable burning phases that could explain certain supersoft X-ray sources.

Contribution

It provides the first detailed modeling of helium white dwarf accretion in CVs, predicting nova characteristics and potential observational signatures distinct from hydrogen-rich systems.

Findings

Helium WDs accumulate ~10^-3 M_sun of hydrogen before thermonuclear runaway.

Predicted nova events are rare, with only a few hundred expected per system.

Long stable burning phases (>1000 years) may explain some supersoft X-ray sources.

Abstract

Binary evolution predicts a population of helium core (M < 0.5 Msol) white dwarfs (WDs) that are slowly accreting hydrogen-rich material from low mass main sequence or brown dwarf donors with orbital periods less than four hours. Four binaries are presently known in the Milky Way that will reach such a mass-transferring state in a few Gyr. Despite these predictions and observations of progenitor binaries, there are still no secure cases of helium core WDs among the mass-transferring cataclysmic variables (CVs). This led us to calculate the fate of He WDs once accretion begins at a rate Mdot < 1e-10 Msol/yr set by angular momentum losses. We show here that the cold He core temperatures (T_c < 1e7 K) and low Mdot result in ~ 1e-3 Msol of accumulated H-rich material at the onset of the thermonuclear runaway. Shara and collaborators noted that these large accumulated masses may lead to exceptionally long classical nova (CN) events. For a typical donor star of 0.2 Msol, such binaries will only yield a few hundred CNe, making these events rare amongst all CNe. We calculate the reheating of the accreting WD, allowing a comparison to the measured WD effective temperatures in quiescent dwarf novae and raising the possibility that WD seismology may be the best way to confirm the presence of a He WD. We also find that a very long (> 1000 yr) stable burning phase occurs after the CN outburst, potentially explaining enigmatic short orbital period supersoft sources like RX J0537-7034 (P_orb = 3.5 hr) and 1E 0035.4-7230 (P_orb = 4.1 hr).