A possible signature of terrestrial planet formation in the chemical composition of solar analogs

TL;DR

This study investigates whether the elemental abundance patterns in solar analogs serve as signatures of terrestrial planet formation, finding consistent evidence across multiple surveys and clarifying previous conflicting claims.

Contribution

It confirms the Tc trend as a potential signature of terrestrial planet formation in solar analogs using data from six independent surveys.

Findings

Elemental abundances in solar analogs align with the Tc trend.

The Tc trend is more statistically significant than FIP correlation.

Reanalysis of stars with super-Earths supports the planet formation signature.

Abstract

Recent studies have shown that the elemental abundances in the Sun are anomalous when compared to most (about 85%) nearby solar twin stars. Compared to its twins, the Sun exhibits a deficiency of refractory elements (those with condensation temperatures Tc>900K) relative to volatiles (Tc<900K). This finding is speculated to be a signature of the planet formation that occurred more efficiently around the Sun compared with the majority of solar twins. Furthermore, within this scenario, it seems more likely that the abundance patterns found are specifically related to the formation of terrestrial planets. In this work we analyze abundance results from six large independent stellar abundance surveys to determine whether they confirm or reject this observational finding. We show that the elemental abundances derived for solar analogs in these six studies are consistent with the Tc trend suggested as a planet formation signature. The same conclusion is reached when those results are averaged heterogeneously. We also investigate the dependency of the abundances with first ionization potential (FIP), which correlates well with Tc. A trend with FIP would suggest a different origin for the abundance patterns found, but we show that the correlation with Tc is statistically more significant. We encourage similar investigations of metal-rich solar analogs and late F-type dwarf stars, for which the hypothesis of a planet formation signature in the elemental abundances makes very specific predictions. Finally, we examine a recent paper that claims that the abundance patterns of two stars hosting super-Earth like planets contradict the planet formation signature hypothesis. Instead, we find that the chemical compositions of these two stars are fully compatible with our hypothesis.