Turbulent transport in a strongly stratified forced shear layer with thermal diffusion

TL;DR

This study investigates shear-induced turbulence in strongly stratified, thermally diffusive environments, revealing conditions for instability, energy transport efficiency, and validating a mixing model relevant to stellar outer layers.

Contribution

It identifies criteria for secular shear instabilities in stratified flows with high thermal diffusivity and validates a mixing coefficient model applicable to stellar environments.

Findings

Only about 10% of input power contributes to heat transport.

Effective mixing coefficient aligns with Zahn's model, D ≈ 0.02 κ_T / J.

Instabilities occur when thermal diffusivity exceeds 10^{14} cm^2/s.

Abstract

This work presents numerical results on the transport of heat and chemical species by shear-induced turbulence in strongly stratified but thermally diffusive environments. The shear instabilities driven in this regime are sometimes called "secular" shear instabilities, and can take place even when the gradient Richardson number of the flow (the square of the ratio of the buoyancy frequency to the shearing rate) is large, provided the P\'eclet number (the ratio of the thermal diffusion timescale to the turnover timescale of the turbulent eddies) is small. We have identified a set of simple criteria to determine whether these instabilities can take place or not. Generally speaking, we find that they may be relevant whenever the thermal diffusivity of the fluid is very large (typically larger than $10^{14}$cm$^2$/s), which is the case in the outer layers of high-mass stars ($M\ge 10 M_\odot$) for instance. Using a simple model setup in which the shear is forced by a spatially sinusoidal, constant-amplitude body-force, we have identified several regimes ranging from effectively unstratified to very strongly stratified, each with its own set of dynamical properties. Unless the system is in one of the two extreme regimes (effectively unstratified or completely stable), however, we find that (1) only about 10% of the input power is used towards heat transport, while the remaining 90% is viscously dissipated; (2) that the effective compositional mixing coefficient is well-approximated by the model of Zahn (1992), with $D \simeq 0.02 \kappa_T /J$ where $\kappa_T$ is the thermal diffusivity and $J$ is the gradient Richardson number. These results need to be confirmed, however, with simulations in different model setups and at higher effective Reynolds number.