Simulations of Flare Chemistry in Brown Dwarf Companions to Active M Dwarfs

Abstract

Brown dwarfs that are short period (<10\,day) companions to actively flaring M dwarfs may provide a context to directly observe flare-driven photochemistry and structural changes in an extrasolar planet-like atmosphere. To assess the viability of directly observing flare impacts in the atmosphere of a brown dwarf, we perform self-consistent temperature-chemistry modeling of the atmospheric response to individual energetic superflares. We modified the existing open-source VULCAN chemical-kinetics and HELIOS radiative-transfer codes for this purpose. Similar to previous studies of flare impacts on hydrogen dominated atmospheres, we find flares are capable of orders-of-magnitude changes in the mixing abundances of many chemical species, including important opacity sources like CH4 and CO2. However, due to fast chemical timescales resulting from high temperatures and densities in brown dwarf atmospheres, these changes last for a short-period of time, generally less than a day, and are only plausibly observable via high resolution emission spectroscopy. We find that the most observable, short-term spectral changes in hot (Teff2000\,K), high-gravity (g5), cloudless brown dwarfs are the photolysis of H2O and enhancement of CO2, which can result in part-per-thousands spectral changes in the hours after a flare.