Climate of an Ultra hot Jupiter: Spectroscopic phase curve of WASP-18b with HST/WFC3

TL;DR

This study presents a spectroscopic phase curve of the ultra hot Jupiter WASP-18b, revealing its atmospheric properties, day-night temperature contrast, and magnetic effects, and compares it with models and other UHJs.

Contribution

It provides the first detailed spectroscopic phase curve analysis of WASP-18b, constraining atmospheric dynamics, magnetic drag effects, and metallicity influences in ultra hot Jupiters.

Findings

Day-night luminosity contrast >0.96

Eastward brightness offset of 4.5 degrees

Magnetic drag from a 10 Gauss field explains circulation

Abstract

We present the analysis of a full-orbit, spectroscopic phase curve of the ultra hot Jupiter WASP-18b, obtained with the Wide Field Camera 3 aboard the Hubble Space Telescope. We measure the planet's normalized day-night contrast as >0.96 in luminosity: the disk-integrated dayside emission from the planet is at 964+-25 ppm, corresponding to 2894+-30 K, and we place an upper limit on the nightside emission of <32ppm or 1430K at the 3-sigma level. We also find that the peak of the phase curve exhibits a small, but significant offset in brightness of 4.5+-0.5 degrees eastward. We compare the extracted phase curve and phase resolved spectra to 3D Global Circulation Models and find that broadly the data can be well reproduced by some of these models. We find from this comparison several constraints on the atmospheric properties of the planet. Firstly we find that we need efficient drag to explain the very inefficient day-night re-circulation observed. We demonstrate that this drag could be due to Lorentz-force drag by a magnetic field as weak as 10 Gauss. Secondly, we show that a high metallicity is not required to match the large day-night temperature contrast. In fact, the effect of metallicity on the phase curve is different from cooler gas-giant counterparts, due to the high-temperature chemistry in WASP-18b's atmosphere. Additionally, we compare the current UHJ spectroscopic phase curves, WASP-18b and WASP-103b, and show that these two planets provide a consistent picture with remarkable similarities in their measured and inferred properties. However, key differences in these properties, such as their brightness offsets and radius anomalies, suggest that UHJ could be used to separate between competing theories for the inflation of gas-giant planets.