Abstract

ABSTRACT We present the discovery and characterization of an eclipsing binary identified by the Next Generation Transit Survey in the ∼115-Myr-old Blanco 1 open cluster. NGTS J0002−29 comprises three M dwarfs: a short-period binary and a companion in a wider orbit. This system is the first well-characterized, low-mass eclipsing binary in Blanco 1. With a low mass ratio, a tertiary companion, and binary components that straddle the fully convective boundary, it is an important benchmark system, and one of only two well-characterized, low-mass eclipsing binaries at this age. We simultaneously model light curves from NGTS, TESS, SPECULOOS, and SAAO, radial velocities from VLT/UVES and Keck/HIRES, and the system’s spectral energy distribution. We find that the binary components travel on circular orbits around their common centre of mass in Porb = 1.098 005 24 ± 0.000 000 38 d, and have masses Mpri = 0.3978 ± 0.0033 M⊙ and Msec = 0.2245 ± 0.0018 M⊙, radii Rpri = 0.4037 ± 0.0048 R⊙ and Rsec = 0.2759 ± 0.0055 R⊙, and effective temperatures $T_{\rm pri}=\mbox{$3372\, ^{+44}_{-37}$}$ K and $T_{\rm sec}=\mbox{$3231\, ^{+38}_{-31}$}$ K. We compare these properties to the predictions of seven stellar evolution models, which typically imply an inflated primary. The system joins a list of 19 well-characterized, low-mass, sub-Gyr, stellar-mass eclipsing binaries, which constitute some of the strongest observational tests of stellar evolution theory at low masses and young ages.

Highlights

  • Theories of stellar evolution are integral to our understanding of observational astrophysics

  • We simultaneously model light curves from Next Generation Transit Survey (NGTS), Transiting Exoplanet Survey Satellite (TESS), SPECULOOS and South African Astronomical Observatory (SAAO), radial velocities from VLT/UVES and Keck/HIRES, and the system’s spectral energy distribution

  • We simultaneously modelled the NGTS, TESS, SPECULOOS and SAAO light curves, UVES and HIRES radial velocity (RV), and system spectral energy distribution (SED) with Gaussian process (GP)-EBOP

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Summary

INTRODUCTION

Theories of stellar evolution are integral to our understanding of observational astrophysics. Mann et al (2015) found, in their study of 183 nearby K7–M7 single stars, comparable discrepancies with models as found for EBs, suggesting that underlying model assumptions to do with opacity or convective mixing length are more likely to be the root cause In their exploration of the radius inflation problem for M dwarfs on the main sequence, Morrell & Naylor (2019) took an all-sky sample of >15 000 stars and employed a spectral energy distribution (SED) fitting method, using Gaia DR2 distances and multiwave-band photometry, to determine empirical relations between luminosity, temperature and radius.

OBSERVATIONS
NGTS photometry
TESS photometry
SPECULOOS photometry
SAAO photometry
HIRES spectroscopy
UVES spectroscopy
Global modelling
Light curves
Gravity darkening
Spectral energy distribution
RESULTS
Mass–radius relation for low-mass EBs
Context
50 Myr 120 Myr 1 Gyr
Mass ratios
Triple systems and the tertiary component
20 Myr 50 Myr 120 Myr 800 Myr
The fully convective boundary
Comparison with stellar evolution models
Activity
Age of NGTS J0002-29
Distance to NGTS J0002-29
Differences between using BT-Settl and PHOENIX atmosphere models
Another EB in Blanco 1?
CONCLUSIONS

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