Physical properties and optical-infrared transmission spectrum of the giant planet XO-1b

TL;DR

This study presents high-precision optical and infrared transmission spectra of exoplanet XO-1b, analyzing its atmospheric composition, orbital parameters, and stellar interactions with detailed modeling and comparison to existing data.

Contribution

It provides a comprehensive transmission spectrum from optical to near-infrared, revealing atmospheric components and refining orbital and stellar parameters for XO-1b.

Findings

Detection of water vapor in the atmosphere with 3.05σ confidence

No significant improvement in atmospheric constraints when combining optical and near-infrared data

Refined orbital ephemeris and constraints on stellar tidal quality factor

Abstract

We present ten high-precision light curves of four transits in the XO-1 planetary system, obtained using $u$, $g$, $r$, redshifted H$\alpha$, $I$ and $z$ filters. We use these to measure the physical properties, orbital ephemeris, and a transmission spectrum of the planet covering the full optical wavelength range. We augment this with published HST/WFC3 observations to construct a transmission spectrum of the planet covering 0.37 to 1.65 $\mu$m. Our best-fitting model to this spectrum is for a H$_2$/He-rich atmosphere containing water (3.05$\sigma$ confidence), nitrogen-bearing molecules NH$_3$ and HCN (1.5$\sigma$) and patchy cloud (1.3$\sigma$). We find that adding the optical to the near-infrared data does not lead to more precise constraints on the planetary atmosphere in this case. We conduct a detailed investigation into the effect of stellar limb darkening on our results, concluding that the choice of limb darkening law and coefficients is unimportant; such conclusions may not hold for other systems so should be reassessed for all high-quality datasets. The planet radius we measure in the $g$-band is anomalously low and should be investigated with future observations at a higher spectral resolution. From the measured times of transit we determine an improved orbital ephemeris, calculate a lower limit on the modified stellar tidal quality factor of $Q_\star^{\,\prime} > 10^{5.6}$, and rule out a previously postulated sinusoidal variation in the transit times.