Predictions for gravity-mode periods and surface abundances in intermediate-mass dwarfs from shear mixing and radiative levitation

TL;DR

This paper introduces advanced stellar models incorporating shear mixing and radiative levitation, improving predictions of gravity-mode periods and surface abundances in intermediate-mass stars, aiding asteroseismic analysis and chemical evolution understanding.

Contribution

It presents a new implementation of radiative accelerations and shear mixing in MESA models, enhancing the accuracy of mode period and surface abundance predictions for intermediate-mass stars.

Findings

Shear mixing combined with atomic diffusion enables mode trapping.

Predicted N/C and C/O ratios correlate with stellar age.

Models show efficient surface abundance evolution detectable with high-precision measurements.

Abstract

The treatment of chemical mixing in the radiative envelopes of intermediate-mass stars has hardly been calibrated so far. Recent asteroseismic studies demonstrated that a constant diffusion coefficient in the radiative envelope is not able to explain the periods of trapped gravity modes in the oscillation spectra of $\gamma$ Doradus pulsators. We present a new generation of MESA stellar models with two major improvements. First, we present a new implementation for computing radiative accelerations and Rosseland mean opacities that requires significantly less CPU time. Second, the inclusion of shear mixing based on rotation profiles computed with the 2D stellar structure code ESTER is considered. We show predictions for the mode periods of these models covering stellar masses from 1.4 to 3.0${\rm M_\odot}$ across the main sequence (MS), computed for different metallicities. The morphology of the chemical mixing profile resulting from shear mixing in combination with atomic diffusion and radiative levitation does allow for mode trapping, while the diffusion coefficient in the outer envelope is large ($>10^{6}\,{\rm cm^2\,s^{-1}}$). Furthermore, we make predictions for the evolution of surface abundances for which radiative accelerations can be computed. We find that the N/C and C/O abundance ratios correlate with stellar age. We predict that these correlations are observable with precisions $\lesssim 0.1$ dex on these ratios, given that a precise age estimate can be made.