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The Mass-Metallicity Relation for Giant Planets

Abstract

Exoplanet discoveries of recent years have provided a great deal of new data for studying the bulk compositions of giant planets. Here we identify 47 transiting giant planets (20MβŠ•<M<20MJ20 M_\oplus < M < 20 M_{\mathrm{J}}) whose stellar insolation is low enough (Fβˆ—<2Γ—108β€…β€Šergβ€…β€Šsβˆ’1β€…β€Šcmβˆ’2F_* < 2\times10^8\; \text{erg}\; \text{s}^{-1}\; \text{cm}^{-2}, or roughly Teff<1000T_\text{eff} < 1000) that they are not affected by the hot Jupiter radius inflation mechanism(s). We compute a set of new thermal and structural evolution models and use these models in comparison with properties of the 47 transiting planets (mass, radius, age) to determine their heavy element masses. A clear correlation emerges between the planetary heavy element mass MzM_z and the total planet mass, approximately of the form Mz∝MM_z \propto \sqrt{M}. This finding is consistent with the core accretion model of planet formation. We also study how stellar metallicity [Fe/H] affects planetary metal-enrichment and find a weaker correlation than has been previously reported from studies with smaller sample sizes. We confirm a strong relationship between the planetary metal-enrichment relative to the parent star Zplanet/ZstarZ_{\rm planet}/Z_{\rm star} and the planetary mass, but see no relation in Zplanet/ZstarZ_{\rm planet}/Z_{\rm star} with planet orbital properties or stellar mass. The large heavy element masses of many planets (>50>50 MβŠ•M_{\oplus}) suggest significant amounts of heavy elements in H/He envelopes, rather than cores, such that metal-enriched giant planet atmospheres should be the rule. We also discuss a model of core-accretion planet formation in a one-dimensional disk and show that it agrees well with our derived relation between mass and Zplanet/ZstarZ_{\rm planet}/Z_{\rm star}.Comment: Accepted to The Astrophysical Journal. This revision adds a substantial amount of discussion; the results are the sam

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