Kinetics of nonionic surfactant adsorption at a fluid-fluid interface from a micellar solution

Abstract: The kinetics of non-ionic surfactant adsorption at a fluid-fluid interface from a micellar solution is considered theoretically. Our model takes into account the effect of micelle relaxation on the diffusion of the free surfactant molecules. It is shown that non-ionic surfactants undergo either a diffusion or a kinetically limited adsorption according to the characteristic relaxation time of the micelles. This gives a new interpretation for the observed dynamical surface tension of micellar solutions.

“…Their approach is inherently sharp in that they set up equations for the interface, the sub-surface region, and the bulk. A later work [38] shows that this methodology can be extended to include also the region above the CMC. A great feature with this type of modeling is the fact that all properties of the model result from a single postulated entity; the system's free energy.…”

On Diffuse Interface Modeling and Simulation of Surfactants in Two-Phase Fluid Flow

“…Their approach is inherently sharp in that they set up equations for the interface, the sub-surface region, and the bulk. A later work [38] shows that this methodology can be extended to include also the region above the CMC. A great feature with this type of modeling is the fact that all properties of the model result from a single postulated entity; the system's free energy.…”

On Diffuse Interface Modeling and Simulation of Surfactants in Two-Phase Fluid Flow

“…Such unassociated surfactant molecules coexisting with micelles are often called unimers [4]. The micelles in this region are unstable and relax, releasing surfactant molecules in order to redress the equilibrium [33]. Thus the micelles behave like reservoirs of monomers that try to maintain the volume fraction of surfactant molecules at the CMC [33].…”

Using spin polarised positive muons for studying guest molecule partitioning in soft matter structures

“…They consist of a hydrophobic part, which is usually a hydrocarbon backbone, and a polar, hydrophilic part, known as the head group, which may also be charged. The most significant property of surfactants is the ability to adsorb at interfaces, [1][2][3][4][5][6][7][8][9][10][11] which can dramatically change the properties of the interface. The adsorption pathway and associated dynamics are very important, and the structures of the adsorbed layers can change significantly with time.…”

Self-assembly and adsorption of cetyltrimethylammonium bromide and didodecyldimethylammonium bromide surfactants at the mica–water interface