Litcius/Paper detail

Pretension-Free and Self-Recoverable Coiled Artificial Muscle Fibers with Powerful Cyclic Work Capability

Bo Cui, Ming Ren, Lizhong Dong, Yulian Wang, Jianfeng He, Xulin Wei, Yueran Zhao, Panpan Xu, Xiaona Wang, Jiangtao Di, Qingwen Li

2023ACS Nano85 citationsDOI

Abstract

Similar to natural muscle fibers, coiled artificial muscle fibers provide a straightforward contraction. However, unlike natural muscle fibers, their recovery from the contracted state to the initial state requires high stress, resulting in almost zero work during a full actuation cycle. Herein, a self-recoverable coiled artificial muscle fiber was prepared by conformally coating an elastic carbon nanotube (CNT) fiber with a very thin liquid crystal elastomer (LCE) sheath. The as-obtained muscle fiber demonstrated excellent actuation properties comprising 56.9% contractile stroke, 1522%/s contraction rate, 7.03 kW kg –1 power density, and 32,000 stable cycles. The LCE chains were helically aligned in a nematic phase, and the phase change of the LCE caused by Joule heating drove the actuation process. Moreover, the LCE/CNT fiber had a well-separated, torsionally stable, and elastic coiled structure, which permitted large contractile strokes and acted as an elastic template for external-stress-free recovery. Thus, the use of self-recoverable muscle fibers to mimic the natural muscles for object dragging, multidirectional bending, and quick striking was demonstrated.

Topics & Concepts

Materials scienceArtificial muscleFiberComposite materialLiquid crystalBendingActuatorOptoelectronicsComputer scienceArtificial intelligenceAdvanced Materials and MechanicsAdvanced Sensor and Energy Harvesting MaterialsDielectric materials and actuators