Hubble's Multi-Year Search for Exospheres in the TRAPPIST-1 System Reveals Frequent Microflares

Abstract

Ly-α observations provide a powerful probe of stellar activity and atmospheric escape in exoplanetary systems. We present here an analysis of 104 HST/STIS orbits monitoring the TRAPPIST-1 system between 2017 and 2022, covering 3--5 transits for each of its seven planets. We rule out transit depths 20\%, which translates into an upper limit on the escape rate of 1064~EOH/Gyr for planet b (1~EOH is the Earth-ocean-equivalent hydrogen content), in agreement with recent claims that planet b should be airless. These upper limits are 3 times larger than expected from the photon noise due to a large baseline scatter, which we ultimately link to TRAPPIST-1's intrinsic Ly-α variability from frequent ``microflares.'' While JWST observations of TRAPPIST-1 in the near infrared have shown that 1030-erg flares occur every 6 hours, we report here 1029-erg flares on sub-hour timescales in the HST/STIS and also Very Large Telescope (VLT) g' observations. The FUV and optical amplitudes (400\% vs 3\%, respectively) for flares with similar waiting-times indicate flare temperatures of 11000+4200-3100~K over 0.011+0.03-0.01\% of the stellar disk. Finally, our multi-year baseline reveals a variability with P = 3.27 0.04 days, providing further validation of the previously reported 3.295-day rotation period for TRAPPIST-1. These results highlight the importance of accounting for stellar microvariability when searching for exospheres around active M dwarfs.