Shear viscosity of a binary mixture for a relativistic fluid at high temperature

Gabriele Parisi; Vincenzo Nugara; Salvatore Plumari; Vincenzo Greco

Paper

Shear viscosity of a binary mixture for a relativistic fluid at high temperature

Abstract

The determination of the shear viscosity is a central topic in various areas of modern physics. In particular, it is often necessary to evaluate the shear viscosity

of fluids made up of more than one species, all interacting with different cross sections. Since it may be difficult to extract information on the interaction among different species, various combinations of the viscosities of the individual components are often used. We work in the Chapman-Enskog framework and investigate on binary mixtures, by comparing such single component combinations with a full 2-component formalism: we find that, in most cases, the full viscosity is well approximated by a weighted linear average of the single component viscosities, although this result is far from being general. Moreover, we validate our 2-component Chapman-Enskog results for

by comparing them with an independent numerical simulation of the Boltzmann equation, which estimates the shear viscosity via a Green-Kubo formula, in the case of a quasi-particle system that reproduces lattice QCD thermodynamics. We see that the temperature dependence of

of such system of quarks and gluons is not well described by combinations of the individual components, highlighting the importance of inter-species scattering.