Detailed Abundances of Stars with Small Planets Discovered by Kepler I: The First Sample

TL;DR

This study analyzes the detailed chemical abundances of seven stars hosting small, likely rocky planets discovered by Kepler, finding their compositions similar to stars without planets and challenging the idea of a chemical signature for rocky planet formation.

Contribution

First detailed abundance analysis of stars with small planets from Kepler, showing their compositions are similar to stars without planets and questioning previous signatures of rocky planet formation.

Findings

Stars with small planets have subsolar to solar metallicities.

No clear chemical signature of rocky planet formation was detected.

Small planets may be common around a wide range of stellar compositions.

Abstract

We present newly derived stellar parameters and the detailed abundances of 19 elements of seven stars with small planets discovered by NASA's Kepler Mission. Each star save one has at least one planet with a radius <= 1.6 R_Earth, suggesting a primarily rocky composition. The stellar parameters and abundances are derived from high signal-to-noise ratio, high-resolution echelle spectroscopy obtained with the 10-m Keck I telescope and HIRES spectrometer using standard spectroscopic techniques. The metallicities of the seven stars range from -0.32 dex to +0.13 dex, with an average metallicity that is subsolar, supporting previous suggestions that, unlike Jupiter-type giant planets, small planets do not form preferentially around metal-rich stars. The abundances of elements other than iron are in line with a population of Galactic disk stars, and despite our modest sample size, we find hints that the compositions of stars with small planets are similar to stars without known planets and with Neptune-size planets, but not to those of stars with giant planets. This suggests that the formation of small planets does not require exceptional host-star compositions and that small planets may be ubiquitous in the Galaxy. We compare our derived abundances (which have typical uncertainties of <= 0.04 dex) to the condensation temperature of the elements; a correlation between the two has been suggested as a possible signature of rocky planet formation. None of the stars demonstrate the putative rocky planet signature, despite at least three of the stars having rocky planets estimated to contain enough refractory material to produce the signature, if real. More detailed abundance analyses of stars known to host small planets are needed to verify our results and place ever more stringent constraints on planet formation models.