TY - JOUR
T1 - Enhanced constraints on the interior composition and structure of terrestrial exoplanets
AU - Wang, H. S.
AU - Liu, F.
AU - Ireland, T. R.
AU - Brasser, R.
AU - Yong, D.
AU - Lineweaver, C. H.
N1 - Funding Information:
We thank the anonymous referee whose comments greatly improved the quality of the paper. We acknowledge valuable discussions with William F. McDonough, Thomas Nordlander, and Stephen Mojz-sis. HSW was supported by the Prime Minister’s Australia Asia Endeavour Award (No. PMPGI-DCD-4014-2014) from Australian Government Department of Education and Training. FL was supported by the Märta and Eric Holmberg Endowment from the Royal Physiographic Society of Lund. This work has made use of the Hypatia Catalog Database at hypatiacatalog.com, which was supported by NASA’s Nexus for Exoplanet System Science (NExSS) research coordination network and the Vanderbilt Initiative in Data-Intensive Astrophysics (VIDA).
Funding Information:
We thank the anonymous referee whose comments greatly improved the quality of the paper. We acknowledge valuable discussions with William F. McDonough, Thomas Nordlander, and Stephen Mojzsis. HSW was supported by the Prime Minister's Australia Asia Endeavour Award (No. PMPGI-DCD-4014-2014) from Australian Government Department of Education and Training. FL was supported by the Märta and Eric Holmberg Endowment from the Royal Physiographic Society of Lund. This work has made use of the Hypatia Catalog Database at hypatiacatalog.com, which was supported by NASA's Nexus for Exoplanet System Science (NExSS) research coordination network and the Vanderbilt Initiative in Data-Intensive Astrophysics (VIDA).
Publisher Copyright:
© 2018 The Author(s) Published by Oxford University Press on behalf of the Royal Astronomical Society.
PY - 2019/1/11
Y1 - 2019/1/11
N2 - Exoplanet interior modelling usually makes the assumption that the elemental abundances of a planet are identical to those of its host star. Host stellar abundances are good proxies of planetary abundances, but only for refractory elements. This is particularly true for terrestrial planets, as evidenced by the relative differences in bulk chemical composition between the Sun and the Earth and other inner Solar system bodies. The elemental abundances of a planet host star must therefore be devolatilized in order to correctly represent the bulk chemical composition of its terrestrial planets. Furthermore, nickel and light elements make an important contribution alongside iron to the core of terrestrial planets. We therefore adopt an extended chemical network of the core, constrained by an Fe/Ni ratio of 18 ± 4 (by number). By applying these constraints to the Sun, our modelling reproduces the composition of the mantle and core, as well as the core mass fraction of the Earth. We also apply our modelling to four exoplanet host stars with precisely measured elemental abundances: Kepler-10, Kepler-20, Kepler-21, and Kepler-100. If these stars would also host terrestrial planets in their habitable zone, we find that such planets orbiting Kepler-21 would be the most Earth-like, while those orbiting Kepler-10 would be the least. To assess the similarity of a rocky exoplanet to the Earth in terms of interior composition and structure, high-precision host stellar abundances are critical. Our modelling implies that abundance uncertainties should be better than ∼0.04 dex for such an assessment to be made.
AB - Exoplanet interior modelling usually makes the assumption that the elemental abundances of a planet are identical to those of its host star. Host stellar abundances are good proxies of planetary abundances, but only for refractory elements. This is particularly true for terrestrial planets, as evidenced by the relative differences in bulk chemical composition between the Sun and the Earth and other inner Solar system bodies. The elemental abundances of a planet host star must therefore be devolatilized in order to correctly represent the bulk chemical composition of its terrestrial planets. Furthermore, nickel and light elements make an important contribution alongside iron to the core of terrestrial planets. We therefore adopt an extended chemical network of the core, constrained by an Fe/Ni ratio of 18 ± 4 (by number). By applying these constraints to the Sun, our modelling reproduces the composition of the mantle and core, as well as the core mass fraction of the Earth. We also apply our modelling to four exoplanet host stars with precisely measured elemental abundances: Kepler-10, Kepler-20, Kepler-21, and Kepler-100. If these stars would also host terrestrial planets in their habitable zone, we find that such planets orbiting Kepler-21 would be the most Earth-like, while those orbiting Kepler-10 would be the least. To assess the similarity of a rocky exoplanet to the Earth in terms of interior composition and structure, high-precision host stellar abundances are critical. Our modelling implies that abundance uncertainties should be better than ∼0.04 dex for such an assessment to be made.
KW - Planets and satellites: composition
KW - Planets and satellites: interiors
KW - Planets and satellites: terrestrial planets
KW - Stars: abundances
UR - http://www.scopus.com/inward/record.url?scp=85066923168&partnerID=8YFLogxK
U2 - 10.1093/mnras/sty2749
DO - 10.1093/mnras/sty2749
M3 - Article
AN - SCOPUS:85066923168
SN - 0035-8711
VL - 482
SP - 2222
EP - 2233
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 2
ER -