Macroscopic heterogeneities in electroosmotic and pressure-driven flow through fixed beds at low column-to-particle diameter ratio

By using dynamic NMR microscopy with 40 mum spatial resolution we have demo nstrated the existence of specific wall effects in electroosmotic and press ure-driven flows through a fixed bed at low column-to-particle diameter rat io. While the geometrical wall effect encountered in pressure-driven flow t hrough the packed capillary is due to the radial distribution of interstiti al porosity, with increasing void space closer to the wall, the electrokine tic wall effect is caused by different values of the zeta-potential associa ted with the inner surface of the capillary and those of the particles. It is shown that these wall effects are very systematic along the column axis for both types of fluid flow. They can cause a persistent (i.e., tong-time) disequilibrium in the axial dispersion behavior, and associated correlatio n lengths of the flow field may cover the total radius of the packed capill ary needing trans-column equilibration. The characteristic times of these m acroscopic flow heterogeneities in electroosmotic and pressure-driven flows exceed by far those of the stagnant mobile phase mass transfer in the bed as we show by complementary pulsed field gradient NMR measurements.