Abstract
A systematic theory for the dynamics of hard-sphere suspensions of interacting Brownian particles with both hydrodynamic and direct interactions is presented. A generalized diffusion equation is derived for concentrated suspensions. The volume fraction (φ) dependence of the short- and long-time self-diffusion coefficients are thus explored from a unifying point of view. The long-range hydrodynamic interactions due to the Oseen tensor are shown to play a crucial role in both coefficients, while the short-range hydrodynamic interactions just lead to corrections. The importance of the correlation effects between particles due to the long-range hydrodynamic interactions is also stressed. The nonlocal correlation effect is an important factor, leading to the behavior of the long-time self-diffusion coefficient ( D S L) as D S L ∼ (1 − φ/ φ 0) 2 near the volume fraction of φ 0 = 0.5718. The direct interactions are also found to be drastically reduced by the short-range hydrodynamic interactions.
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More From: Physica A: Statistical Mechanics and its Applications
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