88 research outputs found
Shear Stress Correlations in Hard and Soft Sphere Fluids
The shear stress autocorrelation function has been studied recently by
molecular dynamics simulation using the 1/q^n potential for very large n. The
results are analyzed and interpreted here by comparing them to the shear stress
response function for hard spheres. It is shown that the hard sphere response
function has a singular contribution and that this is reproduced accurately by
the simulations for large n. A simple model for the stress autocorrelation
function at finite n is proposed, based on the required hard sphere limiting
form.Comment: 14 pages, 2 figures; submitted for special issue of Molecular Physic
Response Functions for a Granular Fluid
The response of an isolated granular fluid to small perturbations of the
hydrodynamic fields is considered. The corresponding linear response functions
are identified in terms of a formal solution to the Liouville equation
including the effects of the cooling reference state. These functions are
evaluated exactly in the asymptotic long wavelength limit and shown to
represent hydrodynamic modes. More generally, the linear granular Navier-Stokes
equations for the response functions and related Langevin equations are
obtained from an extension of Mori's identity. The resulting Green-Kubo
expressions for transport coefficients are compared and contrasted with those
for a molecular fluid. Next the response functions are described in terms of an
effective dynamics in the single particle phase space. A closed linear kinetic
equation is obtained formally in terms of a linear two particle functional.
This closure is evaluated for two examples: a short time Markovian
approximation, and a low density expansion on length and time scales of the
mean free time and mean free path. The former is a generalization of the
revised Enskog kinetic theory to include velocity correlations. The latter is
an extension of the Boltzmann equation to include the effects of recollisions
(rings) among the particles.Comment: To appear in the proceedings of YKIS2009 Frontiers in Nonequilibrium
Physics, Progress in Theoretical Physics supplement 201
Hard Sphere Dynamics for Normal and Granular Fluids
A fluid of N smooth, hard spheres is considered as a model for normal
(elastic collisions) and granular (inelastic collisions) fluids. The potential
energy is discontinuous for hard spheres so the pairwise forces are singular
and the usual forms of Newtonian and Hamiltonian mechanics do not apply.
Nevertheless, particle trajectories in the N particle phase space are well
defined and the generators for these trajectories can be identified. The first
part of this presentation is a review of the generators for the dynamics of
observables and probability densities. The new results presented in the second
part refer to applications of these generators to the Liouville dynamics for
granular fluids. A set of eigenvalues and eigenfunctions of the generator for
this Liouville dynamics is identified in a special "stationary representation".
This provides a class of exact solutions to the Liouville equation that are
closely related to hydrodynamics for granular fluids.Comment: Submitted for publication in the Proceedings of Workshop on Nonlinear
Dynamics in Astronomy and Physics, eds. S. Gottesmann and J. R. Buchler
(Annals of the New York Academy of Sciences, 2005
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