Plant‐Like Tropisms in Artificial Muscles

Abstract

Helical plants have the ability of tropisms to respond to natural stimuli, and biomimicry of such helical shapes into artificial muscles has been vastly popular. However, the shape‐mimicked actuators only respond to artificially provided stimulus, they are not adaptive to variable natural conditions, thus being unsuitable for real‐life applications where on‐demand, autonomous operations are required. Novel artificial muscles made of hierarchically patterned helically wound yarns that are self‐adaptive to environmental humidity and temperature changes are demonstrated here. Unlike shape‐mimicked artificial muscles, a unique microstructural biomimicking approach is adopted, where the muscle yarns can effectively replicate the hydrotropism and thermotropism of helical plants to their microfibril level using plant‐like microstructural memories. Large strokes, with rapid movement, are obtained when the individual microfilament of yarn is inlaid with hydrogel and further twisted into a coil‐shaped hierarchical structure. The developed artificial muscle provides an average actuation speed of ≈5.2% s−1 at expansion and ≈3.1% s−1 at contraction cycles, being the fastest amongst previously demonstrated actuators of similar type. It is demonstrated that these muscle yarns can autonomously close a window in wet climates. The building block yarns are washable without any material degradation, making them suitable for smart, reusable textile and soft robotic devices.