Issue 28, 2017

Modelling critical Casimir force induced self-assembly experiments on patchy colloidal dumbbells

Abstract

Colloidal particles suspended in a binary liquid mixture can interact via solvent mediated interactions, known as critical Casimir forces. For anisotropic colloids this interaction becomes directional, which leads to rich phase behavior. While experimental imaging and particle tracking techniques allow determination of isotropic effective potentials via Boltzmann inversion, the modeling of effective interaction in anisotropic systems is non-trivial precisely because of this directionality. Here we extract effective interaction potentials for non-spherical dumbbell particles from observed radial and angular distributions, by employing reference interaction site model (RISM) theory and direct Monte Carlo simulations. For colloidal dumbbell particles dispersed in a binary liquid mixture and interacting via induced critical Casimir forces, we determine the effective site–site potentials for a range of experimental temperatures. Using these potentials to simulate the system for strong Casimir forces, we reproduce the experimentally observed collapse, and provide a qualitative explanation for this behavior.

Graphical abstract: Modelling critical Casimir force induced self-assembly experiments on patchy colloidal dumbbells

Supplementary files

Article information

Article type
Paper
Submitted
03 Apr 2017
Accepted
07 Jun 2017
First published
09 Jun 2017

Soft Matter, 2017,13, 4903-4915

Modelling critical Casimir force induced self-assembly experiments on patchy colloidal dumbbells

A. C. Newton, T. A. Nguyen, S. J. Veen, D. J. Kraft, P. Schall and P. G. Bolhuis, Soft Matter, 2017, 13, 4903 DOI: 10.1039/C7SM00668C

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