Lithium, rotation and metallicity in the open cluster M35

TL;DR

This study investigates how lithium depletion in G and K stars of the open cluster M35 is influenced by rotation and metallicity, revealing that rotation significantly affects lithium abundance while metallicity differences are minimal.

Contribution

It provides new measurements of lithium, rotation, and metallicity in M35, and clarifies the limited impact of metallicity on lithium depletion in young clusters.

Findings

Fast rotators are Li-rich compared to slow rotators.

Metallicity differences of 0.2-0.3 dex have little effect on Li distribution.

Li distribution in M35 is similar to Pleiades and M34 despite metallicity differences.

Abstract

Lithium (Li) abundance is an age indicator for G, K, and M stellar types, as its abundance decreases over time for these spectral types. However, despite the observational efforts made over the past few decades, the role of rotation, activity, and metallicity in the depletion of Li is still unclear. We have investigated how Li depletion is affected by rotation and metallicity in G and K members of the roughly Pleiades-aged open cluster M35. To do so, we have collected a sample of 165 candidate members observed with the WIYN/Hydra spectrograph. In addition, we have taken advantage of three previous spectroscopic studies of Li in M35. As a result, we have collected a final sample of 396 stars which we have classified as members and non-members of the cluster. We have measured iron abundances, Li equivalent widths, and Li abundances for the 110 M35 members added to the existing sample by this study. Finally, rotation periods for cluster members have been obtained from the literature or derived from Zwicky Transient Facility light curves. As a result, we have confirmed that fast G and K rotators are Li-rich in comparison with slow rotators of similar effective temperature. Furthermore, while we derived subsolar metallicity for M35 from our spectra, the distribution of Li in this cluster is similar to those observed for the Pleiades and M34, which have solar metallicity and slightly different ages. In addition, we have shown that an empirical relationship proposed to remove the contribution of the Fe I line at 670.75 nm to the blended feature at 670.78 nm overestimates the contribution of this iron line for M35 members. We conclude that a 0.2-0.3 dex difference in metallicity makes little difference in the Li distributions of open clusters with ages between 100 and 250 Myr.