Direction-dependent dynamics of colloidal particle pairs and the Stokes-Einstein relation in quasi-two-dimensional fluids

Hydrodynamics and correlated motion of colloids in the near-field interactions are not fully understood. The authors report the motion of particles in particle-pairs is direction-dependent in the near-field and that the Stokes-Einstein relation is not applicable in this case. Hydrodynamic interactions are important for diverse fluids, especially those with low Reynolds number such as microbial and particle-laden suspensions, and proteins diffusing in membranes. Unfortunately, while far-field (asymptotic) hydrodynamic interactions are fully understood in two- and three-dimensions, near-field interactions are not, and thus our understanding of motions in dense fluid suspensions is still lacking. In this contribution, we experimentally explore the hydrodynamic correlations between particles in quasi-two-dimensional colloidal fluids in the near-field. Surprisingly, the measured displacement and relaxation of particle pairs in the body frame exhibit direction-dependent dynamics that can be connected quantitatively to the measured near-field hydrodynamic interactions. These findings, in turn, suggest a mechanism for how and when hydrodynamics can lead to a breakdown of the ubiquitous Stokes-Einstein relation (SER). We observe this breakdown, and we show that the direction-dependent breakdown of the SER is ameliorated along directions where hydrodynamic correlations are smallest. In total, the work uncovers significant ramifications of near-field hydrodynamics on transport and dynamic restructuring of fluids in two-dimensions.

Automated summary

The authors report that the hydrodynamics and correlated motion of colloids in the near-field interactions are not fully understood, and demonstrate that the motion of particle-pairs in the near-field is direction-dependent and not governed by the Stokes-Einstein relation. They experimentally explore the hydrodynamic correlations between particles in quasi-two-dimensional colloidal fluids and uncover significant ramifications of near-field hydrodynamics on transport and dynamic restructuring of fluids in two-dimensions.