Contribution of electrostatic interactions to the concentration dependence of the self-diffusion coefficient of brownian particles

## Abstract The free‐volume theory of diffusion is used to predict the effect of the glass transition on the concentration dependence of the solvent self‐diffusion coefficient at constant temperature. The theoretical prediction is in agreement with experimental data. © 2003 Wiley Periodicals, Inc.

The diffusion coefficient of '%r in natural krypton has been measured as a function of density. T'hc results deviate significantly from the values predicted by the Enskog theory. At low densities. the behaviour can be described by regarding the gas as a monomer-dimer mixture.

Starting from the hydrodynamic continuity equation, the variation up to C 3/2 of the self-and tracer-diffusion coefficient in electrolytic solution was obtained for a supporting electrolyte whose mobilities are equal.

The dependence of the kinetics of trapping of Brownian particles on the concentration of random sinks is studied. It is shown that competition among sinks which slows down the trapping of particles increases with increasing volume fraction of sinks. Taking account of the impenetrability of sinks spe