Exploiting anisotropic particle shape to electrostatically assemble colloidal molecules with high yield and purity

TL;DR

This study demonstrates how exploiting the shape and size of colloidal particles, especially cubic particles, enables efficient and high-purity assembly of colloidal molecules with specific valence, using electrostatic self-assembly and magnetic separation.

Contribution

The paper introduces a novel method leveraging particle shape and electrostatic interactions to achieve high-yield, pure colloidal molecule assembly across various size ratios, expanding the design space.

Findings

Cubic particle shape is key to high-yield assembly.

Electrostatic repulsion guides spheres to facets, not edges.

Magnetic properties enable separation of assembled molecules.

Abstract

Hypothesis: Colloidal molecules with anisotropic shapes and interactions are powerful model systems for deciphering the behavior of real molecules and building units for creating materials with designed properties. While many strategies for their assembly have been developed, they typically yield a broad distribution or are limited to a specific type. We hypothesize that the shape and relative sizes of colloidal particles can be exploited to efficiently direct their assembly into colloidal molecules of desired valence. Experiments: We exploit electrostatic self-assembly of negatively charged spheres made from either polystyrene or silica onto positively charged hematite cubes. We thoroughly analyze the role of the shape and size ratio of particles on the cluster size and yield of colloidal molecules. Findings: Using a combination of experiments and simulations, we demonstrate that cubic particle shape is crucial to generate high yields of distinct colloidal molecules over a wide variety of size ratios. We find that electrostatic repulsion between the satellite spheres is important to leverage the templating effect of the cubes, leading the spheres to preferentially assemble on the facets rather than the edges and corners of the cube. Furthermore, we reveal that our protocol is not affected by the specific choice of the material of the colloidal particles. Finally, we show that the permanent magnetic dipole moment of the hematite cubes can be utilized to separate colloidal molecules from non-assembled satellite particles. Our simple and effective strategy might be extended to other templating particle shapes, thereby greatly expanding the library of colloidal molecules that can be achieved with high yield and purity.