Journal
ASTROPHYSICAL JOURNAL LETTERS
Volume 836, Issue 2, Pages -Publisher
IOP PUBLISHING LTD
DOI: 10.3847/2041-8213/aa5d9f
Keywords
planets and satellites: atmospheres; stars: individual (WASP-18); techniques: photometric; techniques: spectroscopic
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Funding
- Belgian Fund for Scientific Research (F.R.S.-FNRS) [FRFC 2.5.594.09.F]
- F.R.I.A. fund of the F.R.S-FNRS
- Leverhulme Trust through the award of an Early Career Fellowship
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The WASP-18 system, with its massive and extremely close-in planet, WASP-18b (M-p = 10.3M(J), a = 0.02 au, P = 22.6 hr), is one of the best-known exoplanet laboratories to directly measure Q', the modified tidal quality factor and proxy for efficiency of tidal dissipation, of the host star. Previous analysis predicted a rapid orbital decay of the planet toward its host star that should be measurable on the timescale of a few years, if the star is as dissipative as is inferred from the circularization of close-in solar-type binary stars. We have compiled published transit and secondary eclipse timing (as observed by WASP, TRAPPIST, and Spitzer) with more recent unpublished light curves (as observed by TRAPPIST and Hubble Space Telescope) with coverage spanning nine years. We find no signature of a rapid decay. We conclude that the absence of rapid orbital decay most likely derives from Q' being larger than was inferred from solar-type stars and find that Q' >= 1 x 10(6), at 95% confidence; this supports previous work suggesting that F stars, with their convective cores and thin convective envelopes, are significantly less tidally dissipative than solar-type stars, with radiative cores and large convective envelopes.
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