High-order Shakhov-like extension of the relaxation time approximation in relativistic kinetic theory

Abstract

In this paper we present a relativistic Shakhov-type generalization of the Anderson-Witting relaxation time model for the Boltzmann collision integral. The extension is performed by modifying the path on which the distribution function fk is taken towards local equilibrium f0k, by replacing fk - f0k via fk - f Sk. The Shakhov-like distribution f S k is constructed using f0k and the irreducible moments rμ1 ·s μ of fk and reduces to f0k in local equilibrium. Employing the method of moments, we derive systematic high-order Shakhov extensions that allow both the first- and the second-order transport coefficients to be controlled independently of each other. We illustrate the capabilities of the formalism by tweaking the shear-bulk coupling coefficient λ π in the frame of the Bjorken flow of massive particles, as well as the diffusion-shear transport coefficients Vπ, π V in the frame of sound wave propagation in an ultrarelativistic gas. Finally, we illustrate the importance of second-order transport coefficients by comparison with the results of the stochastic BAMPS method in the context of the one-dimensional Riemann problem.