How to Distinguish between Cloudy Mini-Neptunes and Water/Volatile-Dominated Super-Earths

TL;DR

This study presents a method to distinguish between cloudy mini-Neptunes and volatile-rich super-Earths using moderate-resolution NIR transmission spectra, emphasizing the importance of spectral feature analysis and measurement precision.

Contribution

The paper introduces a new approach utilizing spectral wing steepness and absorption feature depths to differentiate planetary atmospheres, supported by a Bayesian retrieval framework and scaling laws.

Findings

Distinguishing atmospheres is possible with reduced measurement uncertainties.

Stacking multiple transits can achieve the necessary spectral precision.

Current instruments can potentially meet the required measurement accuracy.

Abstract

One of the most profound questions about the newly discovered class of low-density super-Earths is whether these exoplanets are predominately H2-dominated mini-Neptunes or volatile-rich worlds with gas envelopes dominated by H2O, CO2, CO, CH4, or N2. Transit observations of the super-Earth GJ 1214b rule out a cloud-free H2-dominated atmosphere, but are not able to determine whether the lack of deep spectral features is due to high-altitude clouds or the presence of a high mean molecular mass atmosphere. Here, we demonstrate that one can unambiguously distinguish between cloudy mini-Neptunes and volatile-dominated worlds based on the differences in the wing steepness and relative depths of water absorption features in moderate-resolution NIR transmission spectra (R~100). In a numerical retrieval study, we show for GJ 1214b that an unambiguous distinction between a cloudy H2-dominated atmosphere and cloud-free H2 atmosphere will be possible if the uncertainties in the spectral transit depth measurements can be reduced by a factor of ~3 compared to the published HST WFC3 and VLT transit observations. We argue that the required precision for the distinction may be achievable with currently available instrumentation by stacking 10-15 transit observations. We provide a scaling law that scales our quantitative results to other transiting super-Earths and Neptunes such as HD 97658b, 55 Cnc e, and GJ 436b. The analysis is performed using an improved version of our Bayesian atmospheric retrieval framework. The new framework not only constrains the gas composition and cloud/haze parameters, but also determines our confidence in having detected molecules and cloud/haze species through Bayesian model comparison. Using the Bayesian tool, we demonstrate quantitatively that the subtle transit depth variation in the Berta et al. (2012) data is not sufficient to claim the detection of water absorption.