Realisation of the Brazil-nut effect in charged colloids without external driving

TL;DR

This study demonstrates that the Brazil-nut effect can occur in charged colloids driven solely by Brownian motion and electrostatics, without external shaking, revealing new insights into sedimentation in strongly interacting systems.

Contribution

It shows experimentally and theoretically that the Brazil-nut effect can arise in charged colloids without external driving, highlighting the role of charge regulation and metastable states.

Findings

Brazil-nut effect observed in charged colloids driven by electrostatics.

Theoretical model agrees with experimental sedimentation profiles.

Charge regulation significantly alters sedimentation behavior.

Abstract

Sedimentation is a ubiquitous phenomenon across many fields of science, such as geology, astrophysics, and soft matter. Sometimes, sedimentation leads to unusual phenomena, such as the Brazil-nut effect, where heavier (granular) particles reside on top of lighter particles after shaking. We show experimentally that a Brazil-nut effect can be realised in a binary colloidal system of long-range repulsive charged particles driven purely by Brownian motion and electrostatics without the need for activity. Using theory, we argue that not only the mass-per-charge for the heavier particles needs to be smaller than the mass-per-charge for the lighter particles, but that at high overall density, the system can be trapped in a long-lived metastable state, which prevents the occurrence of the equilibrium Brazil-nut effect. Therefore, we envision that our work provides valuable insights into the physics of strongly interacting systems, such as partially glassy and crystalline structures. Finally, our theory, which quantitatively agrees with the experimental data, predicts that the shapes of sedimentation density profiles of multicomponent charged colloids are greatly altered when the particles are charge regulating with more than two ion species involved. Hence, we hypothesise that sedimentation experiments can aid in revealing the type of ion-adsorption processes that determine the particle charge and possibly the value of the corresponding equilibrium constants.