Thursday, April 14, 2022; 4:00 pm; Gardiner Hall 230

The Magnetic Connection Between Flares, Rotation, and Age for Fully Convective M Dwarfs

Fully convective M dwarfs display a diversity of magnetic phenomena, motivating questions of how these stars generate and sustain large scale coherent magnetic fields. Moreover, the most spectroscopically accessible terrestrial exoplanets orbit such stars, and their atmospheres are sculpted by the stellar radiation environment that is the product of the star’s magnetic field. We present an observational study that characterizes the relationship between age, stellar rotation, flares, and chromospheric activity for the volume-complete sample of M dwarfs with masses between 0.1 and 0.3 solar masses that reside within 15 parsecs. We find that these stars fall into two groups: The first set has ages less than 2 Gyr, flares frequently, and has short rotation periods, while the second group has ages in excess of 6 Gyr, with rotation periods exceeding 100 days, and flares very rarely. We find that all mid-to-late M dwarfs display the same slope for the frequency of flares as a function of energy, with an index sufficient to explain coronal heating. Although most of the known transiting terrestrial planets orbit inactive stars, an accurate interpretation of upcoming observations of their atmospheres, or lack thereof, requires that we reconstruct the history of their stellar radiation environment.