Glimpsing the Compositions of Sub-Neptune-Size Exoplanets
Leslie Rogers
Caltech
Sub-Neptune and super-Earth sized planets are a new planet category. They account for 80% of the planet candidates discovered by Kepler, and 0% of the planets in the Solar System. What is the nature of these
sub-Neptune-size planets, how did they form, and why are they so numerous? I will review some of the highlights from the complement of exotic sub-Neptune-size planets discovered to date and present an updated planet mass-radius diagram, including new Keck radial velocity mass constraints for 42 small Kepler transiting planet candidates. From
the observed planet mass-radius distribution, I'll theorize about why parts of the distribution are unpopulated and about whether this could be a signature of planet formation and evolution. I'll focus on the intriguing transition between rocky exoplanets (comprised of iron and silicates) and planets with voluminous layers of volatiles (H/He or
astrophysical ices), and explore how the current census of planets constrains this transition. Applying a hierarchical Bayesian model, I will show that the majority of 1.6 Earth-radii planets are not rocky.
Date: | Thursday, 3 April 2014 |
Time: | 11:30 |
Where: | Université de Montréal |
| Pavillon Roger-Gaudry, local D-460 |
Contact: | René Doyon |
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