Characterizing the thermosphere of HD209458b with UV transit observations

TL;DR

This study models the thermosphere of exoplanet HD209458b using UV transit data, revealing its temperature, composition, and escape dynamics, and highlights the need for further observations to refine these findings.

Contribution

Introduces an empirical model for analyzing UV transit depths, providing new insights into the thermosphere's temperature, composition, and escape processes of HD209458b.

Findings

Thermosphere temperature is 8,000-11,000 K.

H2/H dissociation front at 0.1-1 microbar pressure.

Atmosphere overflows the Roche lobe and shows signs of hydrodynamic escape.

Abstract

Transmission spectroscopy at UV wavelengths is a rich and largely unexplored source of information about the upper atmospheres of extrasolar planets. So far, UV transit observations have led to the detection of atomic hydrogen, oxygen and ionized carbon in the upper atmosphere of HD209458b. The interpretation of these observations is controversial - it is not clear if the absorption arises from an escaping atmosphere interacting with the stellar radiation and stellar wind, or the thermosphere inside the Roche lobe. Here we introduce an empirical model that can be used to analyze UV transit depths of extrasolar planets and use it to interpret the transits of HD209458b in the H Ly alpha and the OI triplet emission lines. The results indicate that the mean temperature of the thermosphere is 8,000-11,000 K and that the H2/H dissociation front is located at pressures between 0.1-1 microbar, which correspond to an altitude of 1.1 Rp. The upper boundary of the model thermosphere is located at altitudes between 2.7-3 Rp, above which the atmosphere is mostly ionized. We find that the HI transit depth reflects the optical depth of the thermosphere in the wings of the H Ly alpha line but that the atmosphere also overflows the Roche lobe. By assuming a solar mixing ratio of oxygen, we obtain an OI transit depth that is statistically consistent with the observations. An OI transit depth comparable to or slightly larger than the HI transit depth is possible if the atmosphere is undergoing fast hydrodynamic escape, the O/H ratio is supersolar, or if a significant quantity of neutral oxygen is found outside the Roche lobe. Due to the large uncertainty in the data, repeated observations are necessary to better constrain the OI transit depths and thus the composition of the thermosphere.