Phase separation dependent active motion of Janus lipid vesicles

Active colloidal systems have emerged as promising contenders for the future of microdevices. While conventional designs have extensively exploited the use of hard colloids, the advancement of cell-inspired architectures represents a pivotal path towards realizing self-regulating and highly functional artificial microswimmers. In this work, we fabricate and actuate Janus lipid vesicles demonstrating reconfigurable motion under an AC electric field. The giant unilamellar vesicles (GUVs) undergo spontaneous phase separation at room temperature leading to Janus-like GUVs with two distinct lipid phases. We report self-propulsion of the Janus GUVs via induced charge electroosmosis, in between parallel electrodes. Remarkably, the fluid nature of the lipid membrane affected by the electric field leads to asymmetry-symmetry transient states resulting in run-and-tumble events supported by structure domain analysis. We characterise an enhanced rotational diffusivity associated with tumble events, decoupled from thermal reorientation. Lastly, we identify cargo-release capabilities and a variety of shape-encoded dynamic modes in these vesicles. This cell-inspired architecture provides an alternative route for creating motile artificial cells and programmable microswimmers.