An extremely low-density exoplanet spins slow
Abstract
We present constraints on the shape of Kepler-51d, which is a super-puff with a mass 6\,M and a radius 9\,R, based on detailed modeling of the transit light curve from JWST NIRSpec. The projected shape of this extremely low-density planet is consistent with being spherical, and a projected oblateness f>0.2 can be excluded regardless of the spin obliquity angles. If this is taken as the limit on the true shape of the planet, Kepler-51d is rotating at 50\% of its break-up spin rate, or its rotation period is 33\,hr. In the more plausible situation that the planetary spin is aligned with its orbital direction to within 30, then its oblateness is <0.08, which corresponds to a dimensionless spin rate 30\% of the break-up rotation and a dimensional rotation period 53\,hr. This seems to contradict the theoretical expectation that planets with such low masses may be spinning near break-up. We point out the usefulness of the stellar mean density and the orbital eccentricity in constraining the shape of the transiting planet, so planets with well-characterized host and orbital parameters are preferred in the detection of planetary oblateness with the JWST transit method.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.