Influence of Solvent Quality on Depletion Potentials in Colloid-Polymer Mixtures

TL;DR

This study uses Monte Carlo simulations to show that solvent quality significantly affects depletion potentials in colloid-polymer mixtures, with good solvents inducing stronger attractions due to more aspherical polymer conformations.

Contribution

The paper extends previous models by incorporating solvent quality effects on polymer shape fluctuations, revealing their impact on depletion interactions in colloid-polymer systems.

Findings

Depletion attractions are stronger in good solvents than in theta solvents.

Polymer asphericity significantly influences depletion potentials.

Simulation confirms solvent quality alters colloid-colloid interaction strength.

Abstract

As first explained by the classic Asakura-Oosawa (AO) model, effective attractive forces between colloidal particles induced by depletion of nonadsorbing polymers can drive demixing of colloid-polymer mixtures into colloid-rich and colloid-poor phases, with practical relevance for purification of water, stability of foods and pharmaceuticals, and macromolecular crowding in biological cells. By idealizing polymer coils as effective penetrable spheres, the AO model qualitatively captures the influence of polymer depletion on thermodynamic phase behavior of colloidal suspensions. In previous work, we extended the AO model to incorporate aspherical polymer conformations and showed that fluctuating shapes of random-walk coils can significantly modify depletion potentials [W. K. Lim and A. R. Denton, Soft Matter 12, 2247 (2016); J. Chem. Phys. 144, 024904 (2016)]. We further demonstrated that the shapes of polymers in crowded environments depend sensitively on solvent quality [W. J. Davis and A. R. Denton, J. Chem. Phys. 149, 124901 (2018)]. Here we apply Monte Carlo simulation to analyze the influence of solvent quality on depletion potentials in mixtures of hard sphere colloids and nonadsorbing polymer coils, modeled as ellipsoids whose principal radii fluctuate according to random-walk statistics. We consider both self-avoiding and non-self-avoiding random walks, corresponding to polymers in good and theta solvents, respectively. Our simulation results demonstrate that depletion of polymers of equal molecular weight induces much stronger attraction between colloids in good solvents than in theta solvents and confirm that depletion interactions are significantly influenced by aspherical polymer conformations.