Li abundances in F stars: planets, rotation and galactic evolution

TL;DR

This study investigates how planet presence, stellar rotation, and galactic evolution influence lithium abundances in F stars, revealing significant effects of planet formation and rotation on Li depletion across different stellar ages and metallicities.

Contribution

It provides new insights into the relationships between planet hosting, stellar rotation, and lithium depletion, extending the understanding of Li evolution with metallicity and age in F stars.

Findings

Hot Jupiter hosts show lower Li abundances by 0.14 dex with 7σ significance.

Rotationally-induced mixing may cause Li depletion more than planet presence.

Li abundance peaks at solar metallicity and decreases in the most metal-rich stars.

Abstract

We find that hot jupiter host stars within the T$_\mathrm{eff}$ range 5900-6300K show lower Li abundances, by 0.14 dex, than stars without detected planets. This offset has a significance at the level 7$\sigma$, pointing to a stronger effect of planet formation on Li abundances when the planets are more massive and migrate close to the star. However, we also find that the average v \textit{sin}i of (a fraction of) stars with hot jupiters is higher on average than for single stars in the same T$_\mathrm{eff}$ region, suggesting that rotationally-induced mixing (and not the presence of planets) might be the cause for a greater depletion of Li. We confirm that the mass-metallicity dependence of the Li dip is extended towards [Fe/H] $\sim$ 0.4 dex (beginning at [Fe/H] $\sim$ -0.4 dex for our stars) and that probably reflects the mass-metallicity correlation of stars of the same T$_\mathrm{eff}$ on the Main Sequence. We find that for the youngest stars ($<$ 1.5 Gyr) around the Li dip, the depletion of Li increases with v \textit{sin}i values, as proposed by rotationally-induced depletion models. This suggests that the Li dip consists of fast rotators at young ages whereas the most Li-depleted old stars show lower rotation rates (probably caused by the spin-down during their long lifes). We have also explored the Li evolution with [Fe/H] taking advantage of the metal-rich stars included in our sample. We find that Li abundance reaches its maximum around solar metallicity but decreases in the most metal-rich stars, as predicted by some models of Li Galactic production.