An optical transmission spectrum of the transiting hot Jupiter in the metal-poor WASP-98 planetary system

TL;DR

This study refines the physical and orbital parameters of the metal-poor star WASP-98 and its hot Jupiter, and presents an optical transmission spectrum revealing atmospheric features that suggest unknown absorbing species.

Contribution

It provides new multi-band photometry and spectroscopy data, refines stellar and planetary parameters, and analyzes the atmospheric composition through transmission spectroscopy of WASP-98b.

Findings

Refined stellar metallicity to [Fe/H]=-0.49

Detected a significant variation in planetary radius between passbands

Suggested the presence of an unknown optical-absorbing species in the atmosphere

Abstract

The WASP-98 planetary system represents a rare case of a hot Jupiter hosted by a metal-poor main-sequence star. We present a follow-up study of this system based on multi-band photometry and high-resolution spectroscopy. Two new transit events of WASP-98b were simultaneously observed in four passbands (g,r,i,z), using the telescope-defocussing technique, yielding eight high-precision light curves with point-to-point scatters of less than 1 mmag. We also collected three spectra of the parent star with a high-resolution spectrograph, which we used to remeasure its spectral characteristics, in particular its metallicity. We found this to be very low, Fe/H]=-0.49, but larger than was previously reported, [Fe/H]=-0.60. We used these new photometric and spectroscopic data to refine the orbital and physical properties of this planetary system, finding that the stellar and planetary mass measurements are significantly larger than those in the discovery paper. In addition, the multi-band light curves were used to construct an optical transmission spectrum of WASP-98b and probe the characteristics of its atmosphere at the terminator. We measured a lower radius at z compared with the other three passbands. The maximum variation is between the r and z bands, has a confidence level of roughly 6 sigma and equates to 5.5 pressure scale heights. We compared this spectrum to theoretical models, investigating several possible types of atmospheres, including hazy, cloudy, cloud-free, and clear atmospheres with titanium and vanadium oxide opacities. We could not find a good fit to the observations, except in the extreme case of a clear atmosphere with TiO and VO opacities, in which the condensation of Ti and V was suppressed. As this case is unrealistic, our results suggest the presence of an additional optical-absorbing species in the atmosphere of WASP-98b, of unknown chemical nature.