Spectroscopic and seismic analysis of red giants in eclipsing binaries discovered by Kepler

TL;DR

This study discovers 16 red giant stars in eclipsing binaries from Kepler data, analyzes their oscillations and surface activity, and refines asteroseismic measurement techniques for binary systems.

Contribution

It reports new red giant eclipsing binaries, assesses biases in asteroseismic scaling relations, and explores tidal dissipation and stellar parameters in binary systems.

Findings

Asteroseismic scaling relations overestimate RG masses and radii by 15% and 5%.

Close binarity suppresses solar-like oscillations and reduces mode lifetimes.

Identifies systems with circular orbits despite young ages, indicating alternative tidal dissipation mechanisms.

Abstract

Eclipsing binaries (EBs) are unique benchmarks for stellar evolution. On the one hand, detached EBs hosting at least one star with detectable solar-like oscillations constitute ideal test objects to calibrate asteroseismic measurements. On the other hand, the oscillations and surface activity of stars that belong to EBs offer unique information about the evolution of binary systems. This paper builds upon previous works dedicated to red giant stars (RG) in EBs -- 20 known systems so far -- discovered by the NASA Kepler mission. Here we report the discovery of 16 RGs in EBs also from the Kepler data. This new sample includes three SB2-EBs with oscillations and six close systems where the RG display a clear surface activity and complete oscillation suppression. Based on dedicated high-resolution spectroscopic observations (Apache Point Observatory, Observatoire de Haute Provence), we focus on three main aspects. From the extended sample of 14 SB2-EBs, we first confirm that the simple application of the asteroseismic scaling relations to RGs overestimates masses and radii of RGs, by about 15% and 5%. This bias can be reduced by employing either new asteroseismic reference values for RGs, or model-based corrections of the asteroseismic parameters. Secondly, we confirm that close binarity leads to a high level of photometric modulation (up to 10%), and a suppression of solar-like oscillations. In particular, we show that it reduces the lifetime of radial modes by a factor of up to 10. Thirdly, we use our 16 new systems to complement previous observational studies that aimed at constraining tidal dissipation in interacting binaries. In particular, we identify systems with circular orbits despite relatively young ages, which suggests exploring complementary tidal dissipation mechanisms in the future. Finally, we report the measurements of mass, radius, and age of three M-dwarf companion stars.