Diffusion of brownian particles in shear flow

Macroscopic behavior of a system of brownian particles interacting with each other through potential forces is described by a generalized diffusion equation (GDE) for the density of particles. The diffusion coefficient in the GDE is given by the generalized Stokes-Einstein relation and generally dep

liquids (2) and specifically by the Derjaguin-Landau-Ver-A colloidal system of strongly charged particles, confined bewey-Oberbeek (DLVO) model to account for the interactween two charged walls, is studied under static conditions and tions between colloidal particles in the bulk (3). However, in the

example, the walls expand and contract with time leading In this study, an idealized pore model is used to examine the to unsteady-state gas flow in the lung airways (3). Small, salient features of Brownian particle adsorption onto the inner Brownian particles less than 1 mm in diameter may find the

on the modeling of the later stages of aggregation. A kinetic The disaggregation of biospecifically interacting particles in model of the ligand-receptor bond breakup is considered in shear flow is studied on the basis of kinetic modeling of formation Section 2. In Section 3 the breakup of multipart