Confined self-propulsion of an isotropic active colloid

TL;DR

This study investigates how spatial confinement within a capillary tube influences the self-propulsion of isotropic active colloids, revealing that confinement can enhance propulsion by altering chemical transport mechanisms.

Contribution

The paper introduces a numerical framework to analyze confined active colloids, demonstrating how confinement modifies propulsion thresholds and velocities.

Findings

Confinement promotes spontaneous motion by reducing the Pe threshold.

Propulsion velocities are maximized at an optimal confinement ratio.

Chemical transport shifts from diffusion-dominated to convection-enhanced due to confinement.

Abstract

To spontaneously break their intrinsic symmetry and self-propel at the micron scale, isotropic active colloidal particles and droplets exploit the non-linear convective transport of chemical solutes emitted/consumed at their surface by the surface-driven fluid flows generated by these solutes. Significant progress was recently made to understand the onset of self-propulsion and non-linear dynamics. Yet, most models ignore a fundamental experimental feature, namely the spatial confinement of the colloid, and its effect on propulsion. In this work, the self-propulsion of an isotropic colloid inside a capillary tube is investigated numerically. A flexible computational framework is proposed based on a finite-volume approach on adaptative octree-grids and embedded boundary methods. This method is able to account for complex geometric confinement, the nonlinear coupling of chemical transport and flow fields, and the precise resolution of the surface boundary conditions, that drive the system's dynamics. Somewhat counter-intuitively, spatial confinement promotes the colloid's spontaneous motion by reducing the minimum advection-to-diffusion ratio or P\'clet number, Pe, required to self-propel; furthermore, self-propulsion velocities are significantly modified as the colloid-to-capillary size ratio $\kappa$ is increased, reaching a maximum at fixed Pe for an optimal confinement $0<\kappa<1$. These properties stem from a fundamental change in the dominant chemical transport mechanism with respect to the unbounded problem : with diffusion now restricted in most directions by the confining walls, the excess solute is predominantly convected away downstream from the colloid, enhancing front-back concentration contrasts. These results are confirmed quantitatively using conservation arguments and lubrication analysis of the tightly-confined limit, $\kappa\rightarrow 1$.