Discovery and Atmospheric Characterization of Giant Planet Kepler-12b: An Inflated Radius Outlier

TL;DR

Kepler-12b is a highly inflated giant planet with a low density, detected via multiple methods, providing insights into planetary atmospheres and inflation mechanisms, with no evidence of a temperature inversion.

Contribution

This study reports the discovery and atmospheric characterization of Kepler-12b, highlighting its inflated radius, low density, and the first detection of its occultation in multiple wavelengths.

Findings

Kepler-12b has an inflated radius of 1.695 RJ and low density.

The planet's occultation was detected in Kepler, Spitzer 3.6 and 4.5 μm bands.

No evidence of a dayside temperature inversion was found.

Abstract

We report the discovery of planet Kepler-12b (KOI-20), which at 1.695\pm0.030 RJ is among the handful of planets with super-inflated radii above 1.65 RJ. Orbiting its slightly evolved G0 host with a 4.438-day period, this 0.431\pm0.041 MJ planet is the least-irradiated within this largest-planet-radius group, which has important implications for planetary physics. The planet's inflated radius and low mass lead to a very low density of 0.111\pm0.010 g cm-3. We detect the occultation of the planet at a significance of 3.7{\sigma} in the Kepler bandpass. This yields a geometric albedo of 0.14\pm0.04; the planetary flux is due to a combination of scattered light and emitted thermal flux. We use multiple observations with Warm Spitzer to detect the occultation at 7{\sigma} and 4{\sigma} in the 3.6 and 4.5 {\mu}m bandpasses, respectively. The occultation photometry timing is consistent with a circular orbit, at e < 0.01 (1{\sigma}), and e < 0.09 (3{\sigma}). The occultation detections across the three bands favor an atmospheric model with no dayside temperature inversion. The Kepler occultation detection provides significant leverage, but conclusions regarding temperature structure are preliminary, given our ignorance of opacity sources at optical wavelengths in hot Jupiter atmospheres. If Kepler-12b and HD 209458b, which intercept similar incident stellar fluxes, have the same heavy element masses, the interior energy source needed to explain the large radius of Kepler-12b is three times larger than that of HD 209458b. This may suggest that more than one radius-inflation mechanism is at work for Kepler-12b, or that it is less heavy-element rich than other transiting planets.