New insights into the internal structure of GJ 1214 b informed by JWST

TL;DR

This study reevaluates GJ 1214 b's internal structure using JWST atmospheric data, revealing diverse possible compositions and emphasizing the importance of atmospheric characterization for understanding sub-Neptune interiors.

Contribution

It provides the first comprehensive internal structure models of GJ 1214 b constrained by JWST atmospheric observations, exploring various compositions and formation scenarios.

Findings

Minimum envelope mass fraction of 8.1% needed

Maximum H/He mass fraction is 5.8%

Pure H2O envelope scenario requires high ice-to-rock ratio

Abstract

Recent JWST observations of the sub-Neptune GJ 1214 b suggest that it hosts a high-metallicity (>100x solar), hazy atmosphere. Emission spectra of the planet show molecular absorption features, most likely due to atmospheric H2O. In light of this new information, we conduct a thorough reevaluation of the planet's internal structure. We consider interior models with mixed H/He/H2O envelopes of varying composition, informed by atmospheric constraints from the JWST phase curve, in order to determine possible bulk compositions and internal structures. Self-consistent atmospheric models consistent with the JWST observations are used to set boundary conditions for the interior. We find that a total envelope mass fraction of at least 8.1% is required to explain the planet's mass and radius. Regardless of H2O content, the maximum H/He mass fraction of the planet is 5.8%. We find that a 1:1 ice-to-rock ratio along with 3.4-4.8% H/He is also a permissible solution. In addition, we consider a pure H2O (steam) envelope and find that such a scenario is possible, albeit with a high ice-to-rock ratio of at least 3.76:1, which may be unrealistic from a planet formation standpoint. We discuss possible formation pathways for the different internal structures that are consistent with observations. Since our results depend strongly on the atmospheric composition and haze properties, more precise observations of the planet's atmosphere would allow for further constraints on its internal structure. This type of analysis can be applied to any sub-Neptune with atmospheric constraints to better understand its interior.