Lithium and the evolution of intermediate-mass T Tauri and Herbig stars. Rotation, accretion, and planets

TL;DR

This study analyzes lithium content in 71 intermediate-mass young stars, revealing insights into their evolution, rotation, accretion, and potential links to planet formation, supported by spectroscopic data and stellar models.

Contribution

It provides the first comprehensive analysis of lithium in intermediate-mass T Tauri and Herbig stars, highlighting the role of disk-locking and magnetospheric evolution.

Findings

Li is less depleted in intermediate-mass stars than in lower-mass stars.

25-30% of stars show Li abundances below the cosmic value.

Disk-locking operates in these stars with a shorter timescale than in lower-mass stars.

Abstract

(Abridged) We contribute to our understanding of the evolution of young intermediate-mass stars by providing a comprehensive analysis of their lithium (Li) content. A sample of 71 intermediate-mass T Tauri (IMTT) and Herbig stars within the mass range 1.5 -- 3.5 M$_{\odot}$ was carefully selected for the analysis. Metallicities, rotational velocities, and accretion rates were obtained from spectra. The curves of growth for stars hotter than 8000 K were built to infer the Li abundances, which were interpreted considering standard models of stellar interiors and non-standard processes affecting Li depletion. Li is generally less strongly depleted in intermediate-mass stars than in their lower-mass counterparts, as expected from standard evolution models. However, Li abundances significantly below the cosmic value are observed in 25 -- 30$\%$ of intermediate-mass stars. It is also unexpected that the results show no significant difference between the 1.5 --2.5 M$_{\odot}$ and 2.5 -- 3.5 M$_{\odot}$ subsamples. Evidence is provided showing that disk-locking works in young intermediate-mass stars. This constitutes independent support for the hypothesis that magnetospheric accretion scenario operates in these sources. We found that disk-locking is effective for a timescale that is about twice shorter than for lower-mass stars, before magnetospheres reduce their sizes during the transition from the IMTT to the Herbig regime. This contraction of the magnetosphere can explain the increase in rotation by a factor of about 3 and in accretion by a factor of about 4 that is observed during this transition. We propose a complex scenario linking rotation, accretion, and the surface Li abundance. Finally, we tentatively suggest that the known relation between the presence of planets and Li depletion might also be present in intermediate-mass main sequence (MS) stars and might originate in the pre-MS.