Shape-dependent direction reversal in anisotropic catalytic microswimmers

TL;DR

This study demonstrates that the propulsion direction of anisotropic catalytic microswimmers can reverse with increasing fuel concentration, influenced by shape-induced confinement effects and reaction changes.

Contribution

It reveals shape-dependent direction reversal in microswimmers and links it to confinement and catalytic reaction changes, expanding understanding of active particle behavior.

Findings

Direction reversal occurs only in anisotropic shapes like discs, tori, and bent rods.

Reversal is independent of material composition and size.

Confinement and reaction changes influence propulsion direction.

Abstract

The propulsion direction of active particles is a key feature in self-propelled systems and depends on the propulsion mechanism and environmental conditions. Here, using 3D micro-printed catalytically active particles, we experimentally show that the propulsion direction can change with increasing fuel concentration when the active particle possesses an anisotropic shape. We find that discs, tori, and bent rods reverse their direction of motion with increasing hydrogen peroxide concentration--moving with their inert side forward at low concentrations and with their catalytic side forward at high concentrations. In contrast, spheres and straight rods do not exhibit this reversal. We observe that direction reversal is independent of the base material composition of the swimmer and its size, and only occurs for anisotropic particles where, due to their elongated shape, the location of the solute concentration maximum is unstable and can be shifted by substrate-induced confinements. Our measurements suggest that in addition a change in the platinum-catalyzed reaction of hydrogen peroxide occurs, to which particles with elongated shapes that induce sufficient confinement are more sensitive.