A framework to combine low- and high-resolution spectroscopy for the atmospheres of transiting exoplanets

TL;DR

This paper introduces a novel framework that combines low- and high-resolution spectroscopy data to better characterize exoplanet atmospheres, demonstrated through analysis of HD 209458b, revealing insights into its chemical composition and atmospheric properties.

Contribution

It presents the first combined analysis method for low- and high-resolution spectra of exoplanets, enabling more precise atmospheric composition constraints.

Findings

No confident detection of H2O at high resolution

Water abundance deviates from solar composition expectations by 1.9 sigma

Atmosphere is strongly oxygen-rich with C/O<1 at 3.5 sigma

Abstract

Current observations of the atmospheres of close-in exoplanets are predominantly obtained with two techniques: low-resolution spectroscopy with space telescopes and high-resolution spectroscopy from the ground. Although the observables delivered by the two methods are in principle highly complementary, no attempt has ever been made to combine them, perhaps due to the different modeling approaches that are typically used in their interpretation. Here we present the first combined analysis of previously-published dayside spectra of the exoplanet HD 209458b obtained at low resolution with HST/WFC3 and Spitzer/IRAC, and at high resolution with VLT/CRIRES. By utilizing a novel retrieval algorithm capable of computing the joint probability distribution of low- and high-resolution spectra, we obtain tight constraints on the chemical composition of the planet's atmosphere. In contrast to the WFC3 data, we do not confidently detect H2O at high spectral resolution. The retrieved water abundance from the combined analysis deviates by 1.9 sigma from the expectations for a solar-composition atmosphere in chemical equilibrium. Measured relative molecular abundances of CO and H2O strongly favor an oxygen-rich atmosphere (C/O<1 at 3.5 sigma) for the planet when compared to equilibrium calculations including O rainout. From the abundances of the seven molecular species included in this study we constrain the planet metallicity to 0.1-1.0x the stellar value (1 sigma). This study opens the way to coordinated exoplanet surveys between the flagship ground- and space-based facilities, which ultimately will be crucial for characterizing potentially-habitable planets.