The interplay of sedimentation and crystallization in hard-sphere suspensions

TL;DR

This study investigates how sedimentation and external fields influence crystal nucleation in colloidal hard-sphere suspensions, revealing effects on nucleation rates, growth dynamics, and the potential explanation for experimental-simulation discrepancies.

Contribution

It introduces a simulation framework analyzing sedimentation effects on nucleation, highlighting the roles of external fields and static length scales in the process.

Findings

Sedimentation enhances nucleation rates at greater depths.

Wall proximity suppresses nucleation due to slowed dynamics.

Gravity influences growth rates by creating density gradients.

Abstract

We study crystal nucleation under the influence of sedimentation in a model of colloidal hard spheres via Brownian Dynamics simulations. We introduce two external fields acting on the colloidal fluid: a uniform gravitational field (body force), and a surface field imposed by pinning a layer of equilibrium particles (rough wall). We show that crystal nucleation is suppressed in proximity of the wall due to the slowing down of the dynamics, and that the spatial range of this effect is governed by the static length scale of bond orientational order. For distances from the wall larger than this length scale, the nucleation rate is greatly enhanced by the process of sedimentation, since it leads to a higher volume fraction, or a higher degree of supercooling, near the bottom. The nucleation stage is similar to the homogeneous case, with nuclei being on average spherical and having crystalline planes randomly oriented in space. The growth stage is instead greatly affected by the symmetry breaking introduced by the gravitation field, with a slowing down of the attachment rate due to density gradients, which in turn cause nuclei to grow faster laterally. Our findings suggest that the increase of crystal nucleation in higher density regions might be the cause of the large discrepancy in the crystal nucleation rate of hard spheres between experiments and simulations, on noting that the gravitational effects in previous experiments are not negligible.