The Hubble PanCET Program: Transit and Eclipse Spectroscopy of the Strongly Irradiated Giant Exoplanet WASP-76b

Fu, Guangwei; Deming, Drake; Lothringer, Joshua; Nikolov, Nikolay; Sing, David K.; Kempton, Eliza M.-R.; Ih, Jegug; Evans, Thomas M.; Stevenson, Kevin; Wakeford, H. R.; Rodriguez, Joseph E.; Eastman, Jason D.; Stassun, Keivan; Henry, Gregory W.; López-Morales, Mercedes; Lendl, Monika; Conti, Dennis M.; Stockdale, Chris; Collins, Karen; Kielkopf, John; Barstow, Joanna K.; Sanz-Forcada, Jorge; Ehrenreich, David; Bourrier, Vincent and dos Santos, Leonardo A. (2021). The Hubble PanCET Program: Transit and Eclipse Spectroscopy of the Strongly Irradiated Giant Exoplanet WASP-76b. The Astronomical Journal, 162(3), article no. 108.



Ultra-hot Jupiters with equilibrium temperatures greater than 2000 K are uniquely interesting targets as they provide us crucial insights into how atmospheres behave under extreme conditions. This class of giant planets receives intense radiation from their host star and usually has strongly irradiated and highly inflated atmospheres. At such a high temperature, cloud formation is expected to be suppressed and thermal dissociation of water vapor could occur. We observed the ultra-hot Jupiter WASP-76b with seven transits and five eclipses using the Hubble Space Telescope and the Spitzer Space Telescope (Spitzer) for a comprehensive study of its atmospheric chemical and physical processes. We detected TiO and H2O absorption in the optical and near-infrared transit spectrum. Additional absorption by a number of neutral and ionized heavy metals like Fe, Ni, Ti, and SiO help explain the short-wavelength transit spectrum. The secondary eclipse spectrum shows muted water feature but a strong CO emission feature in Spitzer's 4.5 μm band indicating an inverted temperature pressure profile. We analyzed both the transit and eclipse spectra with a combination of self-consistent PHOENIX models and atmospheric retrieval. Both spectra were well fitted by the self-consistent PHOENIX forward atmosphere model in chemical and radiative equilibrium at solar metallicity, adding to the growing evidence that both TiO/VO and NUV heavy metals opacity are prominent NUV-optical opacity sources in the stratospheres of ultra-hot Jupiters.

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