ELemental abundances of Planets and brown dwarfs Imaged around Stars (ELPIS): II. The Jupiter-like Inhomogeneous Atmosphere of the First Directly Imaged Planetary-Mass Companion 2MASS 1207 b

TL;DR

This study uses JWST data and advanced atmospheric models to reveal the complex, inhomogeneous cloud structures and compositions of the first directly imaged planetary-mass companion, 2MASS 1207 b, providing insights into its atmospheric dynamics and composition.

Contribution

It introduces a new atmospheric inhomogeneity framework and applies it to 2MASS 1207 b, revealing detailed cloud coverage and composition, advancing understanding of exoplanet atmospheres.

Findings

Patchy cloud model best fits the spectrum

Atmosphere has ~9% thin iron clouds and 91% thick clouds

Weak CO absorption explained by patchy thick clouds

Abstract

2MASS 1207 b, the first directly imaged planetary-mass companion, has been instrumental in advancing our understanding of exoplanets and brown dwarfs over the past 20 years. We have performed extensive atmospheric retrieval analyses of 2MASS 1207 b's JWST/NIRSpec spectrum using petitRADTRANS and a new atmospheric inhomogeneity framework, which characterizes homogeneous atmospheres, patchy clouds, cloud-free hot spots, or the combination of patchy clouds and spots. Among 24 retrieval runs with various assumptions, the most statistically preferred model corresponds to the patchy cloud scheme, with Teff$=1174^{+4}_{-3}$ K, log(g)=$3.62^{+0.03}_{-0.02}$ dex, and R$=1.399^{+0.008}_{-0.010}$ R$_{\rm Jup}$, along with near-solar atmospheric compositions of [M/H]$=-0.05\pm0.03$ dex and C/O$=0.440\pm0.012$. This model suggests ~9% of 2MASS 1207 b's atmosphere is covered by thin iron clouds, producing L-dwarf-like spectra, while the remaining 91% consists of thick silicate and iron clouds, emitting blackbody-like spectra. These thin-cloud and thick-cloud regions resemble Jupiter's belts and zones, respectively; this scenario is consistently supported by other retrieval runs incorporating inhomogeneous atmospheres. We demonstrate that 2MASS 1207 b's weak CO absorption can be explained by the veiling effects of patchy thick clouds; the absence of 3.3um CH4 absorption is attributed to its hot thermal structure, which naturally leads to a CO-dominant, CH4-deficient atmosphere. The retrieved atmospheric models also match the observed variability amplitudes of 2MASS 1207 b. Our analysis reveals that the inferred atmospheric properties show significant scatter in less statistically preferred retrieval runs but converge to consistent values among the preferred ones. This underscores the importance of exploring diverse assumptions in retrievals to avoid biased interpretations of atmospheres and formation.