Agile manoeuvring of dandelion-inspired micro-flyers with vortex-enabled stability

Abstract: Manoeuvring untethered, centimetre-scale airborne structures has been a long-standing challenge. Active flight systems, relying on high-power-density actuators alongside mechanical and electronic components, are constrained by critical limitations in energy delivery and miniaturisation. In contrast, passive systems transported and distributed by the wind typically lack the capability for mid-air controlled manoeuvrability. Here we report an ultra-light (1.2 mg) hexagonal polymeric assembly capable of passive flight with optical control of its trajectory. This dandelion-inspired micro-flyer incorporates six radially arranged filamentous structures, of which morphology is dynamically controlled through photomechanical deformation by six independent soft actuators made of liquid crystalline elastomer thin films. Compared to the diaspore of the dandelion (Taraxacum officinale), micro-flyer demonstrate a similar terminal velocity (~0.5 m s-1), 45% better positional stability and nearly zero rotational rate (1.68 s-1; natural seeds: 50.8 s-1). Particle image velocimetry reveals that a stable asymmetric separated vortex ring underlies its flight stability, enabling mid-air steerability. When free-falling in a low-turbulent airstream, the light-driven hexapodal fliers demonstrate precise altitude control, reversible body flipping, pattern formation, interactive swarm, and controlled trajectories across three-dimensional space. The results show that responsive materials with light-induced asymmetry can bring about manoeuvrability in air, paving the way for agile, untethered controlled micro-fliers.