Surveying Ultra-hot Jupiters using Phase Curves with Twinkle
Abstract
Due to their high equilibrium temperatures (Teq > 2000 K), ultra-hot Jupiters (UHJs) are the best characterized exoplanets to date. However, many questions about their formation, evolution, and atmospheres remain unanswered. Phase curve observations can reveal answers to these questions by constraining multiple atmospheric properties including circulation, albedo, and chemistry. To this end, we simulate and forecast a survey of UHJ atmospheres via phase curve observations with the upcoming Twinkle mission. Twinkle is a spectroscopic satellite covering 0.5--4.5 micron with a spectral resolving power of R 50--70. Using a physically motivated model, we simulate white-light photometric phase curve observations for 14 UHJs in Twinkle's field of regard. We project that Twinkle will be able to detect all phase curve signals in our survey. Additionally, we simulate spectroscopic phase curves for the UHJ, WASP-189b. From our simulated spectroscopic phase curves, we generate mock phase-resolved emission spectra. Previously detected UHJ molecules (e.g. H2O, CO and CO2) produce notable features in the resulting spectra, allowing for detailed atmospheric characterization to study the 3D structure of UHJ atmospheric chemistry and dynamics. For planets with hotspot phase offsets, Twinkle will be capable of detecting them both in the optical and infrared wavelength ranges. This future survey would represent the first UHJ phase curve survey with simultaneous coverage in optical and infrared wavelengths and will provide new constraints and reveal intriguing trends in these extreme environments.
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