James W. Dufty, J. Javier Brey
Published 2003-02-10Version 1
The eigenfunctions and eigenvalues of the linearized Boltzmann equation for inelastic hard spheres (d=3) or disks (d=2) corresponding to d+2 hydrodynamic modes, are calculated in the long wavelength limit for a granular gas. The transport coefficients are identified and found to agree with those from the Chapman-Enskog solution. The dominance of hydrodynamic modes at long times and long wavelengths is studied via an exactly solvable kinetic model. A collisional continuum is bounded away from the hydrodynamic spectrum, assuring a hydrodynamic description at long times. The bound is closely related to the power law decay of the velocity distribution in the reference homogeneous cooling state.
Origins of Hydrodynamics for a Granular Gas
Hydrodynamic modes, Green-Kubo relations, and velocity correlations in dilute granular gases
Scaling and universality of critical fluctuations in granular gases
