Abstract
We have analyzed Warm Spitzer/IRAC observations of the secondary eclipses of three planets, XO-4b, HAT-P-6b and HAT-P-8b. We measure secondary eclipse amplitudes at 3.6{\mu}m and 4.5{\mu}m for each target. XO-4b exhibits a stronger eclipse depth at 4.5{\mu}m than at 3.6{\mu}m, which is consistent with the presence of a temperature inversion. HAT-P-8b shows a stronger eclipse amplitude at 3.6{\mu}m, and is best-described by models without a temperature inversion. The eclipse depths of HAT-P-6b can be fitted with models with a small or no temperature inversion. We consider our results in the context of a postulated relationship between stellar activity and temperature inversions and a relationship between irradiation level and planet dayside temperature, as discussed by Knutson et al. (2010) and Cowan & Agol (2011), respectively. Our results are consistent with these hypotheses, but do not significantly strengthen them. To measure accurate secondary eclipse central phases, we require accurate ephemerides. We obtain primary transit observations and supplement them with publicly available observations to update the orbital ephemerides of the three planets. Based on the secondary eclipse timing, we set upper boundaries for e cos(\omega) for HAT-P-6b, HAT-P-8b and XO-4b and find that the values are consistent with circular orbits.
Highlights
The Spitzer Space Telescope has enabled direct measurements of light emitted by exoplanets known as “hot Jupiters” through time series photometry during secondary eclipse
Due to the new transit timings, the contribution of the ephemerides uncertainties to the secondary eclipse time uncertainties for our data sets is reduced from ∼67 to ∼65 s for XO-4b, from ∼160 to ∼49 s for HAT-P-6b, and from ∼91s to ∼44s for HAT-P-8b
The explored Fortney models include or not TiO/VO in the upper atmosphere and have f-values ranging from 0.25 to 0.67, we find that models with f = 0.5 generally apply to our results, except in the case of HAT-P-6b, where a value of 0.63 appears to be a better match
Summary
The Spitzer Space Telescope has enabled direct measurements of light emitted by exoplanets known as “hot Jupiters” through time series photometry during secondary eclipse. Measuring the eclipse depth at multiple wavelengths allows the construction of very low resolution, infrared emergent spectra of the day side of the planet (Charbonneau et al 2008; Grillmair et al 2008). Comparison of these measurements to models suggests that there are two subclasses of hot Jupiters, based on the presence or absence of strong temperature inversions in the upper layers of their atmospheres (e.g., Knutson et al 2008; Machalek et al 2009; Todorov et al 2010; Beerer et al 2011; Deming et al 2011).
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