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 (20Mββ<M<20MJβ) whose stellar
insolation is low enough (Fββ<2Γ108ergsβ1cmβ2, or roughly Teffβ<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 Mzβ and the total planet mass, approximately of the form MzββMβ. 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
Zplanetβ/Zstarβ and the planetary mass, but see no relation in
Zplanetβ/Zstarβ with planet orbital properties or stellar mass.
The large heavy element masses of many planets (>50Mββ) 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 Zplanetβ/Zstarβ.Comment: Accepted to The Astrophysical Journal. This revision adds a
substantial amount of discussion; the results are the sam