Angular momentum and chemical transport by azimuthal magnetorotational instability in radiative stellar interiors

TL;DR

This study investigates how azimuthal magnetorotational instability (AMRI) influences angular momentum and chemical transport in stellar interiors using 3D MHD simulations, revealing new dynamo behavior and implications for stellar rotation and composition.

Contribution

It provides the first evidence of AMRI-driven dynamo action at low magnetic Prandtl numbers in a global setup and analyzes its nonlinear evolution under stratification.

Findings

AMRI-driven dynamo action at Pm 0.6-1

Transport of angular momentum is outward and Maxwell stress dominated

Chemical diffusion scales with stratification similarly to turbulent viscosity

Abstract

The transport of angular momentum (AM) and chemical elements within evolving stars remains poorly understood. Recent observations showed that the radiative cores of low mass main sequence stars and red giants rotate orders of magnitude slower than classical stellar evolution models predictions and that their surface light elements abundances are too small. Magnetohydrodynamic (MHD) turbulence can enhance the transport in radiative stellar interiors but its efficiency is still largely uncertain. Here we explore the transport of AM and chemical elements due to azimuthal magnetorotational instability (AMRI) using 3D MHD direct numerical simulations in a spherical shell. First, we provide evidence of AMRI in the parameter regime expected from local and global linear stability studies and then we analyze its nonlinear evolution. For unstratified flow, we observe AMRI-driven dynamo action at values of the magnetic Prandtl number Pm in the range $0.6-1$, the smallest ever reported in a global setup. When considering stable stratification (under the Boussinesq approximation) at $\text{Pm}=1$, the turbulence is instead transitional and becomes less homogeneous and isotropic upon increasing buoyancy effects. We find that the transport of AM occurs radially outwards and is dominated by the Maxwell stresses when stratification is large enough. The associated turbulent viscosity decreases when buoyancy effects strengthen and scales with the square root of the ratio of the rotation rate to the Brunt-V\"ais\"al\"a frequency, predicting that, for example, red giant cores may reach a state of uniform rotation in a few thousand years. A passive scalar allows us to study the transport of chemical elements. The chemical turbulent diffusion coefficient scales with stratification similarly to the turbulent viscosity but is lower in amplitude as suggested by recent stellar evolution models of low mass stars.