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Adaptive nanotube networks enabling omnidirectionally deformable electro-driven liquid crystal elastomers towards artificial muscles

Jiao Wang, Hao Zhou, Yangyang Fan, Wenhao Hou, Tonghui Zhao, Zhiming Hu, Enzheng Shi, Jiu‐an Lv

2024Materials Horizons20 citationsDOI

Abstract

< 1.15 at 4000 times its weight loaded). In addition, our artificial muscles exhibit real-muscle-like morphing intelligence that enables preventing mechanical damage in response to excessively heavyweight loading. These high-performance artificial muscles uniquely combining omnidirectional stretchability, robust electrothermal actuation, low driving voltage, and powerful mechanical output would exert significant technological impacts on engineering applications such as soft robotics and wearable flexible electronics.

Topics & Concepts

ElastomerMaterials scienceArtificial muscleNanotubeLiquid crystalNanotechnologyCrystal (programming language)Composite materialCarbon nanotubeOptoelectronicsComputer scienceArtificial intelligenceProgramming languageActuatorAdvanced Materials and MechanicsAdvanced Sensor and Energy Harvesting MaterialsDielectric materials and actuators