Binary orbit, physical properties, and evolutionary state of Capella (alpha Aurigae)

TL;DR

This study provides precise measurements of Capella's binary components, revealing discrepancies with current stellar evolution models and highlighting gaps in understanding advanced stellar evolution stages.

Contribution

It offers highly accurate orbital, physical, and chemical data for Capella's components, challenging existing models of stellar evolution and tidal interactions.

Findings

Masses measured with less than 1% error

Chemical composition and isotopic ratios detailed for both stars

Models fail to simultaneously match all observed properties at a single age

Abstract

We report extensive radial-velocity measurements of the two giant components of the detached, 104-day period binary system of Capella. Our highly accurate three-dimensional orbital solution based on all existing spectroscopic and astrometric observations including our own yields much improved masses of 2.466 +/- 0.018 M_Sun and 2.443 +/- 0.013 M_Sun for the primary and secondary (relative errors of 0.7% and 0.5%). Improved values are derived also for the radii (11.87 +/- 0.56 R_Sun and 8.75 +/- 0.32 R_Sun), effective temperatures (4920 +/- 70 K and 5680 +/- 70 K), and luminosities (79.5 +/- 4.8 L_Sun and 72.1 +/- 3.6 L_Sun). The distance is determined to be 13.042 +/- 0.028 pc. Capella is unique among evolved stars in that, in addition to all of the above, the chemical composition is known, including the overall metallicity [m/H], the carbon isotope ratio 12C/13C for the primary, and the lithium abundance and C/N ratios for both components. The latter three quantities are sensitive diagnostics of evolution, and change drastically for giants as a result of the deepening of the convective envelope during the first dredge-up. The secondary is crossing the Hertzprung gap, while the primary is believed to be in the longer-lived core-helium burning phase. However, we find that current stellar evolution models are unable to match all of the observations for both components at the same time, and at a single age, for any evolutionary state of the primary. Similar problems are found when testing the rotational synchronization, spin axis alignment, and orbital circularization of the system against tidal theory. We conclude that our understanding of the advanced stages of stellar evolution is still very incomplete. [Abridged]