Precise Estimates of the Physical Parameters for the Exoplanet System HD-17156 Enabled by HST FGS Transit and Asteroseismic Observations

Abstract

We present observations of three distinct transits of HD 17156b obtained with the Fine Guidance Sensors (FGS) on board the Hubble Space Telescope (HST). We analyzed both the transit photometry and previously published radial velocities to find the planet-star radius ratio Rp/Rs = 0.07454 +/- 0.00035, inclination i=86.49 +0.24/-0.20 deg, and scaled semi-major axis a/R = 23.19 +0.32/-0.27. This last value translates directly to a mean stellar density determination of 0.522 +0.021/-0.018 g cm-3. Analysis of asteroseismology observations by the companion paper of Gilliland et al. (2009) provides a consistent but significantly refined measurement of the stellar mean density. We compare stellar isochrones to this density estimate and find Ms = 1.275 +/- 0.018 Msun and a stellar age of $3.37 +0.20/-0.47 Gyr. Using this estimate of Ms and incorporating the density constraint from asteroseismology, we model both the photometry and published radial velocities to estimate the planet radius Rp= 1.0870 +/- 0.0066 Jupiter radii and the stellar radius Rs = 1.5007 +/- 0.0076 Rsun. The planet radius is larger than that found in previous studies and consistent with theoretical models of a solar-composition gas giant of the same mass and equilibrium temperature. For the three transits, we determine the times of mid-transit to a precision of 6.2 s, 7.6 s, and 6.9 s, and the transit times for HD 17156 do not show any significant departures from a constant period. The joint analysis of transit photometry and asteroseismology presages similar studies that will be enabled by the NASA Kepler Mission.