Exact Rheology of Uniform Shear Flow in a Gas of Inelastic and Rough Maxwell Particles

TL;DR

This paper provides exact analytical expressions for the rheological properties of a granular gas composed of inelastic and rough Maxwell particles under steady shear flow, revealing complex non-Newtonian behavior influenced by roughness and restitution coefficients.

Contribution

It derives exact solutions for stress, spin tensors, and rheological properties of inelastic, rough Maxwell particles, extending previous models to include roughness effects.

Findings

Explicit formulas for shear viscosity and normal stresses.

Non-Newtonian rheological behavior depending on roughness.

Reduction to known models in special limits.

Abstract

We investigate the steady uniform shear flow of a granular gas composed of inelastic and rough Maxwell particles. Exploiting the mean-field character of the model, we derive exact expressions for the collisional production rates of the second-degree moments and obtain a closed nonlinear solution for the stress and spin-spin tensors. The rotational-to-translational temperature ratio and the proportionality between the spin-spin and stress tensors are shown to be independent of the coefficient of normal restitution and determined solely by roughness and moment of inertia. The reduced normal stresses, shear stress, and shear rate are obtained explicitly in terms of two effective parameters generalizing the cooling and stress relaxation rates of the smooth model. From these results we derive exact expressions for the non-Newtonian shear viscosity, the first viscometric function, and the friction coefficient. The dependence of the rheological properties on the normal and tangential restitution coefficients is analyzed in detail, revealing strong non-Newtonian behavior and nonmonotonic effects of roughness. The results reduce, in the appropriate limits, to those of the inelastic Maxwell model for smooth particles and to the Pidduck gas in the elastic perfectly rough case.