Tracking the Stellar Longitudes of Starspots in Short-Period Kepler Binaries

TL;DR

This paper introduces a new phase-tracking method for starspots in short-period Kepler binaries, revealing complex starspot motions and partial asynchrony with orbital periods, enhancing understanding of stellar surface activity.

Contribution

The study develops and applies a novel phase-tracking technique to analyze starspot motions in 414 Kepler binary systems, providing new insights into stellar surface dynamics.

Findings

Approximately 34% of systems show retrograde spot rotation.

About 13% exhibit significant prograde spot rotation.

Over 50% of systems display starspot motions not synchronized with orbital periods.

Abstract

We report on a new method for tracking the phases of the orbital modulations in very short-period, near-contact, and contact binary systems systems in order to follow starspots. We apply this technique to Kepler light curves for 414 binary systems that were identified as having anticorrelated O-C curves for the midtimes of the primary and secondary eclipses, or in the case of non-eclipsing systems, their light-curve minima. This phase tracking approach extracts more information about starspot and binary system behavior than may be easily obtained from the O-C curves. We confirm the hypothesis of Tran et al. (2013) that we can successfully follow the rotational motions of spots on the surfaces of the stars in these binaries. In ~34% of the systems, the spot rotation is retrograde as viewed in the frame rotating with the orbital motion, while ~13% show significant prograde spot rotation. The remaining systems show either little spot rotation or erratic behavior, or sometimes include intervals of both types of behavior. We discuss the possibility that the relative motions of spots are related to differential rotation of the stars. It is clear from this study that the motions of the starspots in at least 50% of these short-period binaries are not exactly synchronized with the orbits.