http://arxiv.org/abs/1510.07582
An exoplanet’s structure and composition are first-order controls of the planet’s habitability. We explore which aspects of bulk terrestrial planet composition and interior structure affect the chief observables of an exoplanet: its mass and radius. We apply these perturbations to the Earth, the planet we know best. Using the mineral physics toolkit BurnMan to self-consistently calculate mass-radius models, we find that core radius, presence of light elements in the core and an upper-mantle consisting of low-pressure silicates have the largest effect on the final calculated mass at a given radius, with mantle composition being secondary. We further apply this model to determine the interior composition of Kepler-36b, finding that it is likely structurally similar to the Earth with Si/Fe = 1.14 compared to Earth’s Si/Fe = 1 and Sun’s Si/Fe = 1.19. We expand these results provide a grid of terrestrial mass-radius models for determining whether exoplanets are indeed “Earth-like” as bound by their composition and structure.
C. Unterborn, E. Dismukes and W. Panero
Tue, 27 Oct 15
40/76
Comments: 7 pages, 8 figures, 2 tables; Submitted to ApJ
You must be logged in to post a comment.