Detection of Planetary Emission from the Exoplanet TrES-2 using Spitzer /IRAC

TL;DR

This study reports the detection of planetary emission from TrES-2 during secondary eclipses using Spitzer IRAC, analyzing flux ratios across four infrared wavelengths to infer atmospheric properties and orbital characteristics.

Contribution

It provides the first infrared emission measurements of TrES-2, exploring atmospheric models with and without thermal inversion, and confirms the planet's likely circular orbit.

Findings

Flux contrasts fit a black body spectrum at 1500 K

Data consistent with models with or without thermal inversion

Secondary eclipse timings match a circular orbit

Abstract

We present here the results of our observations of TrES-2 using the Infrared Array Camera on Spitzer. We monitored this transiting system during two secondary eclipses, when the planetary emission is blocked by the star. The resulting decrease in flux is 0.127%+-0.021%, 0.230%+-0.024%, 0.199%+-0.054%, and 0.359%+-0.060%, at 3.6 microns, 4.5 microns, 5.8 microns, and 8.0 microns, respectively. We show that three of these flux contrasts are well fit by a black body spectrum with T_{eff}=1500 K, as well as by a more detailed model spectrum of a planetary atmosphere. The observed planet-to-star flux ratios in all four IRAC channels can be explained by models with and without a thermal inversion in the atmosphere of TrES-2, although with different atmospheric chemistry. Based on the assumption of thermochemical equilibrium, the chemical composition of the inversion model seems more plausible, making it a more favorable scenario. TrES-2 also falls in the category of highly irradiated planets which have been theoretically predicted to exhibit thermal inversions. However, more observations at infrared and visible wavelengths would be needed to confirm a thermal inversion in this system. Furthermore, we find that the times of the secondary eclipses are consistent with previously published times of transit and the expectation from a circular orbit. This implies that TrES-2 most likely has a circular orbit, and thus does not obtain additional thermal energy from tidal dissipation of a non-zero orbital eccentricity, a proposed explanation for the large radius of this planet.