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Literature DB >> 31296765

Sheath-run artificial muscles.

Jiuke Mu¹, Mônica Jung de Andrade¹, Shaoli Fang¹, Xuemin Wang^2,3, Enlai Gao^1,4, Na Li^1,5, Shi Hyeong Kim¹, Hongzhi Wang⁶, Chengyi Hou⁶, Qinghong Zhang⁶, Meifang Zhu⁶, Dong Qian², Hongbing Lu², Dharshika Kongahage⁷, Sepehr Talebian⁷, Javad Foroughi⁷, Geoffrey Spinks⁷, Hyun Kim⁸, Taylor H Ware⁸, Hyeon Jun Sim⁹, Dong Yeop Lee⁹, Yongwoo Jang⁹, Seon Jeong Kim⁹, Ray H Baughman¹⁰.

Abstract

Although guest-filled carbon nanotube yarns provide record performance as torsional and tensile artificial muscles, they are expensive, and only part of the muscle effectively contributes to actuation. We describe a muscle type that provides higher performance, in which the guest that drives actuation is a sheath on a twisted or coiled core that can be an inexpensive yarn. This change from guest-filled to sheath-run artificial muscles increases the maximum work capacity by factors of 1.70 to 2.15 for tensile muscles driven electrothermally or by vapor absorption. A sheath-run electrochemical muscle generates 1.98 watts per gram of average contractile power-40 times that for human muscle and 9.0 times that of the highest power alternative electrochemical muscle. Theory predicts the observed performance advantages of sheath-run muscles.

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Year: 2019 PMID： 31296765 DOI： 10.1126/science.aaw2403

Source DB: PubMed Journal: Science ISSN： 0036-8075 Impact factor: 47.728

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Cited

11 in total

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Journal: Adv Sci (Weinh) Date: 2022-01-24 Impact factor: 16.806

Sheath-run artificial muscles.

1. Soft actuators for real-world applications.

2. Shape-programmable, deformation-locking, and self-sensing artificial muscle based on liquid crystal elastomer and low-melting point alloy.

3. Towards bio-inspired artificial muscle: a mechanism based on electro-osmotic flow simulated using dissipative particle dynamics.

4. Microfluidic manipulation by spiral hollow-fibre actuators.

Review 5. A Shift from Efficiency to Adaptability: Recent Progress in Biomimetic Interactive Soft Robotics in Wet Environments.

6. High Energy and Power Density Peptidoglycan Muscles through Super-Viscous Nanoconfined Water.

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8. Designer patterned functional fibers via direct imprinting in thermal drawing.

9. Ultrastrong and Highly Sensitive Fiber Microactuators Constructed by Force-Reeled Silks.

10. Miniature coiled artificial muscle for wireless soft medical devices.