| Literature DB >> 30152590 |
Jian Qiao1,2, Jiangtao Di2, Susheng Zhou2, Kaiyun Jin2, Sha Zeng2, Na Li3, Shaoli Fang3, Yanhui Song1,2, Min Li1, Ray H Baughman3, Qingwen Li2.
Abstract
Artificial muscles are reported in which reduced graphene oxide (rGO) is trapped in the helical corridors of a carbon nanotube (CNT) yarn. When electrochemically driven in aqueous electrolytes, these coiled CNT/rGO yarn muscles can contract by 8.1%, which is over six times that of the previous results for CNT yarn muscles driven in an inorganic electrolyte (1.3%). They can contract to provide a final stress of over 14 MPa, which is about 40 times that of natural muscles. The hybrid yarn muscle shows a unique catch state, in which 95% of the contraction is retained for 1000 s following charging and subsequent disconnection from the power supply. Hence, they are unlike thermal muscles and natural muscles, which need to consume energy to maintain contraction. Additionally, these muscles can be reversibly cycled while lifting heavy loads.Entities:
Keywords: artificial muscle; carbon nanotube; electrochemical muscle; graphene; yarn muscle
Year: 2018 PMID: 30152590 DOI: 10.1002/smll.201801883
Source DB: PubMed Journal: Small ISSN: 1613-6810 Impact factor: 13.281