Longitudinal Viscous Flow in Granular Gases

Abstract

The flow characterized by a linear longitudinal velocity field ux(x,t)=a(t)x, where a(t)=a0/(1+a0t), a uniform density n(t) a(t), and a uniform temperature T(t) is analyzed for dilute granular gases by means of a BGK-like model kinetic equation in d dimensions. For a given value of the coefficient of normal restitution α, the relevant control parameter of the problem is the reduced deformation rate a*(t)=a(t)/(t) (which plays the role of the Knudsen number), where (t) n(t)T(t) is an effective collision frequency. The relevant response parameter is a nonlinear viscosity function η*(a*) defined from the difference between the normal stress Pxx(t) and the hydrostatic pressure p(t)=n(t)T(t). The main results of the paper are: (a) an exact first-order ordinary differential equation for η*(a*) is derived from the kinetic model; (b) a recursion relation for the coefficients of the Chapman--Enskog expansion of η*(a*) in powers of a* is obtained; (c) the Chapman--Enskog expansion is shown to diverge for elastic collisions (α=1) and converge for inelastic collisions (α<1), in the latter case with a radius of convergence that increases with inelasticity; (d) a simple approximate analytical solution for η*(a*), hardly distinguishable from the numerical solution of the differential equation, is constructed.