Compositional Imprints in Density–Distance–Time: A Rocky Composition for Close-in Low-mass Exoplanets from the Location of the Valley of Evaporation

Jin, Sheng; Mordasini, Christoph (2018). Compositional Imprints in Density–Distance–Time: A Rocky Composition for Close-in Low-mass Exoplanets from the Location of the Valley of Evaporation. Astrophysical journal, 853(2), p. 163. Institute of Physics Publishing IOP 10.3847/1538-4357/aa9f1e

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We use an end-to-end model of planet formation, thermodynamic evolution, and atmospheric escape to investigate how the statistical imprints of evaporation depend on the bulk composition of planetary cores (rocky vs. icy). We find that the population-wide imprints like the location of the "evaporation valley" in the distance-radius plane and the corresponding bimodal radius distribution clearly differ depending on the bulk composition of the cores. Comparison with the observed position of the valley (Fulton et al. 2017) suggests that close-in low-mass Kepler planets have a predominately Earth-like rocky composition. Combined with the excess of period ratios outside of MMR, this suggests that low-mass Kepler planets formed inside of the water iceline, but still undergoing orbital migration. The core radius becomes visible for planets losing all primordial H/He. For planets in this "triangle of evaporation" in the distance-radius plane, the degeneracy in compositions is reduced. In the observed diagram, we identify a trend to more volatile-rich compositions with increasing radius (R/R_Earth<1.6 rocky; 1.6-3.0 ices and/or H/He; >3: H/He). The mass-density diagram contains important information about formation and evolution. Its characteristic broken V-shape reveals the transitions from solid planets to low-mass core-dominated planets with H/He and finally to gas-dominated giants. Evaporation causes density and orbital distance to be anti-correlated for low-mass planets, in contrast to giants, where closer-in planets are less dense, likely due to inflation. The temporal evolution of the statistical properties reported here will be of interest for the PLATO 2.0 mission which will observe the temporal dimension.

Item Type:	Journal Article (Original Article)
Division/Institute:	08 Faculty of Science > Physics Institute > NCCR PlanetS 08 Faculty of Science > Physics Institute 08 Faculty of Science > Physics Institute > Space Research and Planetary Sciences
UniBE Contributor:	Mordasini, Christoph
Subjects:	500 Science 500 Science > 520 Astronomy 500 Science > 530 Physics 600 Technology > 620 Engineering
ISSN:	0004-637X
Publisher:	Institute of Physics Publishing IOP
Language:	English
Submitter:	Janine Jungo
Date Deposited:	04 Apr 2018 13:14
Last Modified:	05 Dec 2022 15:11
Publisher DOI:	10.3847/1538-4357/aa9f1e
BORIS DOI:	10.7892/boris.112371
URI:	https://boris.unibe.ch/id/eprint/112371

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Compositional Imprints in Density–Distance–Time: A Rocky Composition for Close-in Low-mass Exoplanets from the Location of the Valley of Evaporation

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