Variability Timescales of H$\alpha$ on Active Mid-to-Late M dwarfs

TL;DR

This study investigates the variability timescales of Hα emission in active mid-to-late M dwarfs, finding that flares likely dominate the observed short-term variability rather than stable magnetic structures.

Contribution

It provides the first detailed analysis of Hα variability timescales in fully-convective M dwarfs, highlighting the role of flares over magnetic structures in causing emission changes.

Findings

Most stars show no correlation between Hα variability and rotation.

One star exhibits a clear rotational phase relationship with Hα.

Short-term variability (20-45 min) likely caused by flares.

Abstract

We present a study of the variation timescales of the chromospheric activity indicator H$\alpha$ on a sample of 13 fully-convective, active mid-to-late M stars with masses between 0.1--0.3 solar masses. Our goal was to determine the dominant variability timescale and, by inference, a possible mechanism responsible for the variation. We gathered 10 or more high-resolution spectra each of 10 stars using the TRES spectrograph at times chosen to span all phases of stellar rotation, as determined from photometric data from the MEarth Observatories. All stars varied in their H$\alpha$ emission. For 9 of these stars, we found no correlation between H$\alpha$ and rotational phase, indicating that constant emission from fixed magnetic structures, such as starspots and plage, are unlikely to be the dominant source of H$\alpha$ emission variability. In contrast, one star, G 7-34, shows a clear relationship between H$\alpha$ and stellar rotational phase. Intriguingly, we found that this star is a member of the AB Doradus moving group and hence has the young age of 149 Myr. High-cadence spectroscopic observations of three additional stars revealed that they are variable on timescales ranging from 20--45 minutes, which we posit may be due to flaring behavior. For one star, GJ 1111, simultaneous TESS photometry and spectroscopic monitoring show an increase in H$\alpha$ emission with increased photometric brightness. We conclude that low-energy flares are able to produce variation in H$\alpha$ on the timescales we observe and thus may be the dominant source of H$\alpha$ variability on active fully-convective M dwarfs.