Critical Casimir Forces and Colloidal Phase Transitions in a Near-Critical Solvent: A Simple Model Reveals a Rich Phase Diagram
Publication date
2015-01-21
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Abstract
From experimental studies, it is well known that colloidal particles suspended in a near-critical binary solvent exhibit interesting aggregation phenomena, often associated with colloidal phase transitions and assumed to be driven by long-ranged solvent-mediated (SM) interactions (critical Casimir forces), set by the (diverging) correlation length of the solvent. We present the first simulation and theoretical study of an explicit model of a ternary mixture that mimics this situation. Both the effective SM pair interactions and the full ternary phase diagram are determined for Brownian disks suspended in an explicit two-dimensional supercritical binary liquid mixture. Gas-liquid and fluid-solid transitions are observed in a region that extends well away from criticality of the solvent reservoir. We discuss to what extent an effective pair-potential description can account for the phase behavior we observe. Our study provides a fresh perspective on how proximity to the critical point of the solvent reservoir might influence colloidal self-assembly.
Keywords
SOLVATION FORCE, CRITICAL-POINT, FLUIDS, ADSORPTION, PARTICLES, BEHAVIOR, MIXTURE, SPHERES, Taverne
Citation
Edison, J R, Tasios, N, Belli, S, Evans, R, van Roij, R & Dijkstra, M 2015, 'Critical Casimir Forces and Colloidal Phase Transitions in a Near-Critical Solvent : A Simple Model Reveals a Rich Phase Diagram', Physical Review Letters, vol. 114, no. 3, 038301. https://doi.org/10.1103/PhysRevLett.114.038301