English

Turbulent Heating in a Stratified Medium

Astrophysics of Galaxies 2023-01-18 v1

Abstract

There is considerable evidence for widespread subsonic turbulence in galaxy clusters, most notably from {\it Hitomi}. Turbulence is often invoked to offset radiative losses in cluster cores, both by direct dissipation and by enabling turbulent heat diffusion. However, in a stratified medium, buoyancy forces oppose radial motions, making turbulence anisotropic. This can be quantified via the Froude number Fr{\rm Fr}, which decreases inward in clusters as stratification increases. We exploit analogies with MHD turbulence to show that wave-turbulence interactions increase cascade times and reduces dissipation rates ϵFr\epsilon \propto {\rm Fr}. Equivalently, for a given energy injection/dissipation rate ϵ\epsilon, turbulent velocities uu must be higher compared to Kolmogorov scalings. High resolution hydrodynamic simulations show excellent agreement with the ϵFr\epsilon \propto {\rm Fr} scaling, which sets in for Fr<0.1{\rm Fr} < 0.1. We also compare previously predicted scalings for the turbulent diffusion coefficient DFr2D \propto {\rm Fr}^2 and find excellent agreement, for Fr<1{\rm Fr} < 1. However, we find a different normalization, corresponding to stronger diffusive suppression by more than an order of magnitude. Our results imply that turbulent diffusion is more heavily suppressed by stratification, over a much wider radial range, than turbulent dissipation. Thus, the latter potentially dominates. Furthermore, this shift implies significantly higher turbulent velocities required to offset cooling, compared to previous models. These results are potentially relevant to turbulent metal diffusion (which is likewise suppressed), and to planetary atmospheres.

Keywords

Cite

@article{arxiv.2205.01732,
  title  = {Turbulent Heating in a Stratified Medium},
  author = {Chaoran Wang and S. Peng Oh and M. Ruszkowski},
  journal= {arXiv preprint arXiv:2205.01732},
  year   = {2023}
}
R2 v1 2026-06-24T11:06:20.467Z