Super-Earth ingestion can explain the anomalously high metal abundances of M67 Y2235

TL;DR

This study suggests that ingestion of super-Earth planets can explain the high metal abundances observed in a star in M67, highlighting the role of planetary dynamics and ingestion in stellar chemical peculiarities.

Contribution

It demonstrates that super-Earth ingestion can account for metal enhancements in stars and models the delivery mechanisms through planet-planet scattering and Lidov-Kozai cycles.

Findings

Super-Earth ingestion can cause a 0.128 dex metal increase.

Rocky planets dissolve in the stellar convective envelope under certain conditions.

Grazing orbits lead to planetary dissolution and metal enrichment.

Abstract

We investigate the hypothesis that ingestion of a terrestrial or super-Earth planet could cause the anomalously high metal abundances seen in a turn-off star in the open cluster M67, when compared to other turn-off stars in the same cluster. We show that the mass in convective envelope of the star is likely only $3.45\,\times 10^{-3}\,{\rm M}_\odot$, and hence $5.2\,{\rm M}_\oplus$ of rock is required to obtain the observed 0.128 dex metal enhancement. Rocky planets dissolve entirely in the convective envelope if they enter it with sufficiently tangential orbits: we find that the critical condition for dissolution is that the planet's radial speed must be less than 40% of its total velocity at the stellar surface; or, equivalently, the impact parameter must be greater than about 0.9. We model the delivery of rocky planets to the stellar surface both by planet-planet scattering in a realistic multi-planet system, and by Lidov-Kozai cycles driven by a more massive planetary or stellar companion. In both cases almost all planets that are ingested arrive at the star on grazing orbits and hence will dissolve in the surface convection zone. We conclude that super-Earth ingestion is a good explanation for the metal enhancement in M67 Y2235, and that a high-resolution spectroscopic survey of stellar abundances around the turn-off and main sequence of M67 has the potential to constrain the frequency of late-time dynamical instability in planetary systems.