Dynamics of particle aggregation in dewetting films of complex liquids

TL;DR

This paper models the complex interplay between dewetting and particle aggregation in colloidal suspensions on surfaces, revealing how attractive interactions lead to diverse dynamic behaviors and pattern formations.

Contribution

It introduces a coupled PDE model for film and colloid evolution, analyzing phase behavior, stability, and bifurcations in dewetting films of complex liquids.

Findings

Identification of parameter regimes for agglomerate formation

Bifurcation diagrams illustrating stability and pattern transitions

Numerical confirmation of theoretical predictions

Abstract

We consider the dynamic wetting and dewetting processes of films and droplets of complex liquids on planar surfaces, focusing on the case of colloidal suspensions, where the particle interactions can be sufficiently attractive to cause agglomeration of the colloids within the film. This leads to an interesting array of dynamic behaviours within the liquid and of the liquid-air interface. Incorporating concepts from thermodynamics and using the thin-film approximation, we construct a model consisting of a pair of coupled partial differential equations that represent the evolution of the liquid film and the effective colloidal height profiles. We determine the relevant phase behaviour of the uniform system, including finding associated binodal and spinodal curves, helping to uncover how the emerging behaviour depends on the particle interactions. Performing a linear stability analysis of our system enables us to identify parameter regimes where agglomerates form, which we independently confirm through numerical simulations and continuation of steady states, to construct bifurcation diagrams. We obtain various dynamics such as uniform colloidal profiles in an unstable situation evolving into agglomerates and thus elucidate the interplay between dewetting and particle aggregation in complex liquids on surfaces.