Constraints on the exosphere of CoRoT-7b

TL;DR

This study aims to detect and constrain the properties of CoRoT-7b's exosphere by high-resolution spectral observations, providing insights into surface material escape in rocky exoplanets.

Contribution

First attempt to observationally constrain the exosphere of a rocky exoplanet using high-resolution spectroscopy and setting upper limits on key spectral lines.

Findings

No exosphere lines detected, upper limits established.

Spectral lines from Ca I, Ca II, Na, and CaO constrained.

Method demonstrates feasibility for exosphere detection in rocky planets.

Abstract

CONTEXT: The small radius and high density of CoRoT-7b implies that this transiting planet belongs to a differen t species than all transiting planets previously found. Current models suggest that this is the first transiting rocky planet found outside the solar system. Given that the planet orbits a solar-like star at a distance of on ly 4.5 R*, it is expected that material released from its surface may then form an exosphere. AIMS: We constrai n the properties of the exosphere by observing the planet in- and out-of-transit. Detecting of the exosphere of CoRoT-7b would for the first time allow to study the material originating in the surface of a rocky extrasolar planet. We scan the entire optical spectrum for any lines originating from the planet, focusing particularly on spectral lines such as those detected in Mercury, and Io in our solar system. METHODS: Since lines originating in the exosphere are expected to be narrow, we observed CoRoT-7b at high resolution with UVES on the VLT. By subtracting the two spectra from each other, we search for emission and absorption lines originating in the exosph ere of CoRoT-7b. RESULTS: In the first step, we focus on Ca I, Ca II, Na, because these lines have been detected in Mercury. Since the signal-to-noise ratio (S/N) of the spectra is as high as 300, we derive firm upper limits for the flux-range between 1.6E-18 and 3.2E-18 Wm**-2. For CaO, we find an upper limit of E-17 Wm**-2. We also search for emission lines originating in the plasma torus fed by volcanic activity and derive upper limits for these lines. In the whole spectrum we finally try to identify other lines originating in the planet.