Directional self-locomotion of active droplets enabled by nematic environment

Active matter composed of self-propelled interacting units holds a major promise for the extraction of useful work from its seemingly chaotic dynamics. Streamlining active matter is especially important at the microscale, where the viscous forces prevail over inertia and transport requires a non-reciprocal motion. Here we report that microscopic active droplets representing aqueous dispersions of swimming bacteriaBacillus subtilisbecome unidirectionally motile when placed in an inactive nematic liquid-crystal medium. Random motion of bacteria inside the droplet is rectified into a directional self-locomotion of the droplet by the polar director structure that the droplet creates in the surrounding nematic through anisotropic molecular interactions at its surface. Droplets without active swimmers show no net displacement. The trajectory of the active droplet can be predesigned by patterning the molecular orientation of the nematic. The effect demonstrates that broken spatial symmetry of the medium can be the reason for and the means to control directional microscale transport. Active matter particles self-propel but controlling their direction of motion can be challenging. Here the authors place motile bacteria inside microdroplets and control their propulsion by exploiting the asymmetric director structure of the surrounding liquid crystal.

Automated summary

This study demonstrates that active droplets containing swimming bacteria can achieve unidirectional motion when placed in an inactive nematic liquid-crystal medium, by converting the random motion of the bacteria inside the droplet into directional self-locomotion through interactions with the surrounding nematic. The trajectory of the active droplet can be predesigned by patterning the molecular orientation of the nematic, showing that the broken spatial symmetry of the medium can control directional microscale transport.