Fingering convection induced by atomic diffusion in stars: 3D numerical computations and applications to stellar models

TL;DR

This study combines 3D numerical simulations and stellar modeling to understand how atomic diffusion and fingering convection influence iron layer formation in stars, affecting stellar pulsations and evolution.

Contribution

It validates a fingering convection mixing prescription via 3D simulations and applies it to stellar models, revealing effects of helium settling on iron accumulation and stellar opacity.

Findings

Fingering convection efficiently mixes iron, leading to weak iron layers.

Helium settling stabilizes iron profiles, allowing large iron overabundances.

Increased opacity can trigger dynamical convection in stellar layers.

Abstract

Iron-rich layers are known to form in the stellar subsurface through a combination of gravitational settling and radiative levitation. Their presence, nature and detailed structure can affect the excitation process of various stellar pulsation modes, and must therefore be modeled carefully in order to better interpret Kepler asteroseismic data. In this paper, we study the interplay between atomic diffusion and fingering convection in A-type stars, and its role in the establishment and evolution of iron accumulation layers. To do so, we use a combination of three-dimensional idealized numerical simulations of fingering convection, and one-dimensional realistic stellar models. Using the three-dimensional simulations, we first validate the mixing prescription for fingering convection recently proposed by Brown et al. (2013), and identify what system parameters (total mass of iron, iron diffusivity, thermal diffusivity, etc.) play a role in the overall evolution of the layer. We then implement the Brown et al. (2013) prescription in the Toulouse-Geneva Evolution code to study the evolution of the iron abundance profile beneath the stellar surface. We find, as first discussed by Th\'eado et al. (2009), that when the concurrent settling of helium is ignored, this accumulation rapidly causes an inversion in the mean molecular weight profile, which then drives fingering convection. The latter mixes iron with the surrounding material very efficiently, and the resulting iron layer is very weak. However, taking helium settling into account partially stabilizes the iron profile against fingering convection, and a large iron overabundance can accumulate. The opacity also increases significantly as a result, and in some cases ultimately triggers dynamical convection.