The JWST Weather Report: retrieving temperature variations, auroral heating, and static cloud coverage on SIMP-0136

TL;DR

This study uses JWST time-series spectra to analyze atmospheric variability in the brown dwarf SIMP-0136, revealing temperature changes, auroral heating, and cloud coverage effects, advancing understanding of substellar atmospheres.

Contribution

First application of JWST spectral data to perform atmospheric retrievals on SIMP-0136, identifying auroral heating and temperature-driven variability mechanisms.

Findings

Detected a ~250 K thermal inversion likely caused by auroral energy deposition.

Temperature profile changes at pressures >10 mbar drive spectral variability.

Patchy silicate clouds are present but do not vary systematically with longitude.

Abstract

SIMP-0136 is a T2.5 brown dwarf whose young age ($200\pm50$~Myr) and low mass ($15\pm3$~M$_{\rm Jup}$) make it an ideal analogue for the directly imaged exoplanet population. With a 2.4 hour period, it is known to be variable in both the infrared and the radio, which has been attributed to changes in the cloud coverage and the presence of an aurora respectively. To quantify the changes in the atmospheric state that drive this variability, we obtained time-series spectra of SIMP-0136 covering one full rotation with both NIRSpec/PRISM and the MIRI/LRS on board JWST. We performed a series of time-resolved atmospheric retrievals using petitRADTRANS in order to measure changes in the temperature structure, chemistry, and cloudiness. We inferred the presence of a ~250 K thermal inversion above 10 mbar of SIMP-0136 at all phases, and propose that this inversion is due to the deposition of energy into the upper atmosphere by an aurora. Statistical tests were performed in order to determine which parameters drive the observed spectroscopic variability. The primary contribution was due to changes in the temperature profile at pressures deeper than 10 mbar, which resulted in variation of the effective temperature from 1243 K to 1248 K. This changing effective temperature was also correlated to observed changes in the abundances of CO2 and H2S, while all other chemical species were consistent with being homogeneous throughout the atmosphere. Patchy silicate clouds were required to fit the observed spectra, but the cloud properties were not found to systematically vary with longitude. This work paints a portrait of an L/T transition object where the primary variability mechanisms are magnetic and thermodynamic in nature, rather than due to inhomogeneous cloud coverage.