Extreme mass loss during common envelope evolution: the origin of the double low-mass white dwarf system J2102--4145

TL;DR

This study analyzes the double white dwarf system J2102-4145 to understand extreme mass loss during common envelope evolution, providing new constraints on hydrogen-envelope retention in low-mass white dwarfs.

Contribution

It offers the first detailed observational constraints on hydrogen-envelope mass in post-CE low-mass white dwarfs, challenging existing envelope ejection models.

Findings

The primary white dwarf's properties align with stable Roche-lobe overflow models.

The secondary's extremely thin hydrogen envelope suggests more efficient envelope ejection than standard models predict.

The system's evolutionary history supports a sequence of stable Roche-lobe overflow followed by a common envelope phase.

Abstract

Eclipsing close double white dwarf (WD) systems provide a unique opportunity to directly constrain hydrogen-envelope retention and test common-envelope (CE) evolution in low-mass stars, since they allow precise determinations of stellar masses and radii. We analyze J2102-4145, an eclipsing binary composed of two low-mass helium-core white dwarfs in a 2.4-hour orbit. By comparing the observed radii and effective temperatures with updated evolutionary models for CE evolution and stable Roche-lobe overflow (SRLOF), we confirm that both stars are helium-core white dwarfs. The primary, with a mass of 0.375 solar masses, is consistent with SRLOF models that retain thick hydrogen envelopes and sustain residual nuclear burning, whereas the secondary, with a mass of 0.314 solar masses, can only be reproduced by CE models in which the hydrogen envelope is almost completely removed. The inferred cooling ages (approximately 220 Myr for the secondary and between about 260 and 510 Myr for the primary, depending on the contribution of residual nuclear burning) support a formation sequence in which the primary formed first through SRLOF, followed by a CE phase that produced the compact secondary. Reconstruction of the CE energy budget yields progenitor and orbital parameters consistent with this evolutionary picture. The unusually small radius of the secondary requires an extremely thin hydrogen envelope, with a mass below about 10e-7 solar masses, well below the values predicted by standard bifurcation criteria. J2102-4145 therefore provides one of the strongest observational constraints on the hydrogen-envelope mass of post-CE low-mass white dwarfs and represents a benchmark challenge for current prescriptions of envelope ejection.