From Capillary Condensation to Interface Localization Transitions in Colloid Polymer Mixtures Confined in Thin Film Geometry

TL;DR

This study uses Monte Carlo simulations to explore how confinement and wall asymmetry influence phase transitions in colloid-polymer mixtures, revealing a transition from capillary condensation to interface localization.

Contribution

It introduces a detailed simulation analysis of asymmetric wall effects on phase behavior in confined colloid-polymer mixtures, extending current theoretical understanding.

Findings

Transition from capillary condensation to interface localization with increasing wall asymmetry.

Density profiles vary significantly across different phases and confinement conditions.

Critical behavior and interfacial fluctuations are characterized in confined geometries.

Abstract

Monte Carlo simulations of the Asakura-Oosawa (AO) model for colloid-polymer mixtures confined between two parallel repulsive structureless walls are presented and analyzed in the light of current theories on capillary condensation and interface localization transitions. Choosing a polymer to colloid size ratio of q=0.8 and studying ultrathin films in the range of D=3 to D=10 colloid diameters thickness, grand canonical Monte Carlo methods are used; phase transitions are analyzed via finite size scaling, as in previous work on bulk systems and under confinement between identical types of walls. Unlike the latter work, inequivalent walls are used here: while the left wall has a hard-core repulsion for both polymers and colloids, at the right wall an additional square-well repulsion of variable strength acting only on the colloids is present. We study how the phase separation into colloid-rich and colloid-poor phases occurring already in the bulk is modified by such a confinement. When the asymmetry of the wall-colloid interaction increases, the character of the transition smoothly changes from capillary condensation-type to interface localization-type. The critical behavior of these transitions is discussed, as well as the colloid and polymer density profiles across the film in the various phases, and the correlation of interfacial fluctuations in the direction parallel to the confining walls. The experimental observability of these phenomena also is briefly discussed.