Impact of the Tayler magnetic instability on the surface abundance of boron in massive stars

TL;DR

This study explores how the Tayler magnetic instability influences surface boron levels in massive stars, showing it can explain observed abundances and internal angular momentum transport better than purely hydrodynamic models.

Contribution

It demonstrates that including the Tayler instability in stellar models improves agreement with observed boron surface abundances and internal rotation profiles in massive B-type stars.

Findings

Models with only hydrodynamic processes overestimate boron depletion.

Tayler instability models align well with observed boron levels and rotation.

Magnetic field effects at low rotation may be overestimated in current models.

Abstract

Context: The surface abundances of massive stars show evidence of internal mixing, while asteroseismic data suggest that efficient angular momentum (AM) transport occurs in stellar interiors. It is of interest to find a consistent physical framework that is able to account for both of these effects simultaneously. Aims: We investigate the impact of the Tayler instability on the surface abundance of boron in massive B-type stars as predicted by rotating stellar models accounting for the advective nature of meridional currents. Methods: We used the Geneva stellar evolution code to compute models of 9, 12, and 15 Msun stars at different rotational velocities and with and without magnetic fields. We compared the surface boron abundances predicted by these models with those of observed B-type stars. Results: We find that models with only hydrodynamic transport processes overestimate the amount of boron depletion for stars with high rotation rates, in disagreement with observational constraints. We show that this excessively high mixing efficiency is a consequence of the high degree of differential rotation predicted by purely hydrodynamic models. We thus conclude that surface abundances of boron indicate that a more efficient AM transport is needed in stellar radiative zones. We then studied the impact of the Tayler instability as a possible physical explanation to this issue. Models including this instability are found to be in good agreement with constraints on the surface boron abundances, the evolutionary state, and the projected rotational velocity of moderately and fast-rotating B-type stars. Finally, we note that at low rotational velocities, models with magnetic fields do not predict sufficient depletion to be consistent with the observations. This could suggest that the current prescriptions for the Tayler instability may overestimate the AM transport in slow-rotating B-type stars.