New high precision orbital and physical parameters of the double-lined low-mass spectroscopic binary BY Draconis

TL;DR

This paper provides the most precise orbital and physical parameters for the BY Draconis binary system, revealing insights into its stellar properties, orbital dynamics, and potential spin-orbit misalignment, challenging existing tidal theories.

Contribution

It introduces a novel iodine-cell technique for double-lined binaries and combines spectroscopic and astrometric data for high-precision orbital solutions.

Findings

Achieved 0.2-0.5% precision in mass and parallax measurements.

Discovered probable spin-orbit misalignment in BY Dra.

Suggested the presence of a substellar companion affecting system dynamics.

Abstract

We present the most precise to date orbital and physical parameters of the well known short period (P=5.975 d), eccentric (e=0.3) double-lined spectroscopic binary BY Draconis, a prototype of a class of late-type, active, spotted flare stars. We calculate the full spectroscopic/astrometric orbital solution by combining our precise radial velocities (RVs) and the archival astrometric measurements from the Palomar Testbed Interferometer (PTI). The RVs were derived based on the high resolution echelle spectra taken between 2004 and 2008 with the Keck I/HIRES, Shane/CAT/HamSpec and TNG/SARG telescopes/spectrographs using our novel iodine-cell technique for double-lined binary stars. The RVs and available PTI astrometric data spanning over 8 years allow us to reach 0.2-0.5% level of precision in M sin3(i) and the parallax but the geometry of the orbit (i=154 deg) hampers the absolute mass precision to 3.3%, which is still an order of magnitude better than for previous studies. We compare our results with a set of Yonsei-Yale theoretical stellar isochrones and conclude that BY Dra is probably a main sequence system more metal-rich than the Sun. Using the orbital inclination and the available rotational velocities of the components, we also conclude that the rotational axes of the components are likely misaligned with the orbital angular momentum. Given BY Dra's main sequence status, late spectral type and the relatively short orbital period, its high orbital eccentricity and probable spin-orbit misalignment are not in agreement with the tidal theory. This disagreement may possibly be explained by smaller rotational velocities of the components and the presence of a substellar mass companion to BY Dra AB.