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The short- and long-time behavior of the velocity-correlation functions characteristic for the coefficient of self-diffusion, and the kinetic parts of the coefficient of viscosity, and thermal conductivity, respectively, are computed approximately as a function of the density for a gas of hard disks or hard spheres on the basis of kinetic theory. The results obtained here are a generalization to higher densities of those obtained in an earlier paper, and reduce to them in the low-density limit. The density dependence is obtained by taking into account a larger number of dynamical events than previously considered. It is found that for short times the correlation functions decay exponentially, but that for longer times t, the correlation functions decay ^ (d) (n) (t{{t₀}) }^d{2} where n is the density, t₀ the mean free time between collisions, and d is the number of dimensions. The coefficient ^ (d) (n) is determined by the transport coefficients of the Enskog theory for a dense gas of hard disks or hard spheres and is in very good agreement with existing computer experiments.
Dorfman et al. (Tue,) studied this question.
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