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تسجيل مستخدم جديدDynamics of heterogeneous hard spheres in a file
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Ophir Flomenbom
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Normal dynamics in a quasi-one-dimensional channel of length L (toinfty) of N hard spheres are analyzed. The spheres are heterogeneous: each has a diffusion coefficient D that is drawn from a probability density function (PDF), W D^(-{gamma}), for small D, where 0leq{gamma}<1. The initial spheres density {rho} is non-uniform and scales with the distance (from the origin) l as, {rho} l^(-a), 0leqaleq1. An approximation for the N-particle PDF for this problem is derived. From this solution, scaling law analysis and numerical simulations, we show here that the mean square displacement for a particle in such a system obeys, <r^2>~t^(1-{gamma})/(2c-{gamma}), where c=1/(1+a). The PDF of the tagged particle is Gaussian in position. Generalizations of these results are considered.
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