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Detection of the phase curve and occultation of WASP-100b with <i>TESS</i>

Tiffany Jansen, David Kipping

2020Monthly Notices of the Royal Astronomical Society25 citationsDOIOpen Access PDF

Abstract

ABSTRACT We report the detection of the full orbital phase curve and occultation of the hot-Jupiter WASP-100b using TESS photometry. The phase curve is isolated by suppressing low-frequency stellar and instrumental modes using both a non-parametric harmonic notch filter (phasma) and semi-sector long polynomials. This yields a phase-curve signal of (73 ± 9) ppm amplitude, preferred over a null-model by ΔBIC = 25, indicating very strong evidence for an observed effect. We recover the occultation event with a suite of five temporally localized tools, including Gaussian processes and cosine filtering. This allows us to infer an occultation depth of (100 ± 14) ppm, with an additional ±16 ppm systematic error from the differences between methods. We regress a model including atmospheric reflection, emission, ellipsoidal variations, and Doppler beaming to the combined phase-curve and occultation data. This allows us to infer that WASP-100b has a geometric albedo of $A_g = 0.16^{+0.04}_{-0.03}$ in the TESS bandpass, with a maximum dayside brightness temperature of (2710 ± 100) K and a warm nightside temperature of $(2380^{+170}_{-200})$ K. Additionally, we find evidence that WASP-100b has a high thermal redistribution efficiency, manifesting as a substantial eastward hotspot offset of $(71^{+2}_{-4})^{\circ }$. These results present the first measurement of a thermal phase shift among the phase curves observed by TESS so far, and challenge the predicted efficiency of heat transport in the atmospheres of ultra-hot-Jupiters.

Topics & Concepts

PhysicsOccultationHot JupiterLight curveAmplitudeGeometric albedoRadio occultationAstrophysicsPhotometry (optics)BrightnessAstronomyPlanetExoplanetOpticsStarsCOSMIC cancer databaseStellar, planetary, and galactic studiesAstro and Planetary ScienceAstrophysics and Star Formation Studies