Discovery of the Eclipsing Detached Double White Dwarf Binary NLTT 11748

TL;DR

This paper reports the discovery of the first eclipsing detached double white dwarf binary, providing valuable data on WD properties and binary evolution, with implications for gravitational wave detection and stellar modeling.

Contribution

The paper presents the first detection of an eclipsing detached double white dwarf binary, enabling precise measurements of component masses and radii, and advancing understanding of WD binary systems.

Findings

Confirmed the binary nature through radial velocity and eclipse observations.

Measured the primary and secondary eclipse depths and durations.

Estimated the masses and radii of both white dwarfs, consistent with theoretical models.

Abstract

We report the discovery of the first eclipsing detached double white dwarf (WD) binary. In a pulsation search, the low-mass helium core WD NLTT 11748 was targeted for fast (approx 1 minute) differential photometry with the Las Cumbres Observatory's Faulkes Telescope North. Rather than pulsations, we discovered approx 180 s 3%-6% dips in the photometry. Subsequent radial velocity measurements of the primary white dwarf from the Keck telescope found variations with a semi-amplitude K_1 = 271 +/- 3 km/s, and confirmed the dips as eclipses caused by an orbiting WD with a mass M_2 = 0.648-0.771 M_sun for M_1 = 0.1-0.2 M_sun. We detect both the primary and secondary eclipses during the P_orb = 5.64 hr orbit and measure the secondary's brightness to be 3.5% +/- 0.3% of the primary at SDSS-g'. Assuming that the secondary follows the mass-radius relation of a cold C/O WD and including the effects of microlensing in the binary, the primary eclipse yields a primary radius of R_1 = 0.043-0.039 R_sun for M_1 = 0.1-0.2 M_sun, consistent with the theoretically expected values for a helium core WD with a thick, stably burning hydrogen envelope. Though nearby (at approx 150 pc), the gravitational wave strain from NLTT 11748 is likely not adequate for direct detection by the Laser Interferometer Space Antenna. Future observational efforts will determine M_1, yielding accurate WD mass-radius measurement of both components, as well as a clearer indication of the binary's fate once contact is reached.