Direct measurements of the effects of salt and surfactant on interaction forces between colloidal particles at water-oil interfaces

TL;DR

This study investigates how salt and surfactant influence the electrostatic forces between colloidal particles at water-oil interfaces, revealing time-dependent and anisotropic interactions that affect aggregation behavior.

Contribution

It demonstrates that electrolyte and surfactant concentrations affect interparticle forces, highlighting the significant role of water-side charges and the time evolution of interactions.

Findings

Increased electrolyte reduces interaction force magnitude.

Higher SDS concentration decreases repulsion.

Interactions become anisotropic and time-dependent.

Abstract

The forces between colloidal particles at a decane-water interface, in the presence of low concentrations of a monovalent salt (NaCl) and of the surfactant sodium dodecylsulfate (SDS) in the aqueous subphase, have been studied using laser tweezers. In the absence of electrolyte and surfactant, particle interactions exhibit a long-range repulsion, yet the variation of the interaction for different particle pairs is found to be considerable. Averaging over several particle pairs was hence found to be necessary to obtain reliable assessment of the effects of salt and surfactant. It has previously been suggested that the repulsion is consistent with electrostatic interactions between a small number of dissociated charges in the oil phase, leading to a decay with distance to the power -4 and an absence of any effect of electrolyte concentration. However, the present work demonstrates that increasing the electrolyte concentration does yield, on average, a reduction of the magnitude of the interaction force with electrolyte concentration. This implies that charges on the water side also contribute significantly to the electrostatic interactions. An increase in the concentration of SDS leads to a similar decrease of the interaction force. Moreover the repulsion at fixed SDS concentrations decreases over longer times. Finally, measurements of three-body interactions provide insight into the anisotropic nature of the interactions. The unique time-dependent and anisotropic interactions between particles at the oil-water interface allow tailoring of the aggregation kinetics and structure of the suspension structure.