Local direct numerical simulations of turbulent mixing in stellar radiative zones

V. Prat; F. Lignières

doi:10.1051/eas/1363030

All issues

Volume 63 (2013)

EAS Publications Series, 63 (2013) 263-268

Abstract

Issue		EAS Publications Series Volume 63, 2013 New Advances in Stellar Physics: From Microscopic to Macroscopic Processes


Page(s)		263 - 268
Section		Hydrodynamics, Mixing Processes and Transport of Angular Momentum in Stars
DOI		https://doi.org/10.1051/eas/1363030
Published online		19 December 2013

New Advances in Stellar Physics: From Microscopic to Macroscopic Processes
G. Alecian, Y. Lebreton, O. Richard and G. Vauclair (eds)
EAS Publications Series, 63 (2013) 263–268

Local direct numerical simulations of turbulent mixing in stellar radiative zones

V. Prat¹^,2 and F. Lignières¹^,2

¹ Université de Toulouse, UPS-OMP, IRAP, Toulouse, France
² CNRS, IRAP, 14 avenue Édouard Belin, 31400 Toulouse, France

Abstract

One of the key issues of stellar evolution theory is the influence of the transport processes related to rotationally driven macroscopic motions on the internal structure and the evolution of stars. Turbulent mixing of chemical elements due to differential rotation in stellar radiative zones is currently taken into account in many stellar evolution codes through transport coefficients firstly derived by Zahn (1992, A&A, 265, 115). The purpose of our work is to constrain one of these coefficients, the radial diffusion coefficient driven by radial differential rotation through local direct numerical simulations of steady homogeneous stably stratified sheared turbulence, and to compare the results with phenomenological models. In particular, we have determined the dependence of the turbulent diffusion coefficient on thermal diffusivity and chemical stratification.