Novel Biomimetic “Spider Web” Robust, Super‐Contractile Liquid Crystal Elastomer Active Yarn Soft Actuator

Wu, Dingsheng; Li, Xin; Zhang, Yuxin; Cheng, Xinyue; Long, Zhiwen; Ren, Lingyun; Xia, Xin; Wang, Qingqing; Li, Jie; Lv, Pengfei; Feng, Quan; Wei, Qufu

doi:10.1002/advs.202400557

Cited by 6 publications

(1 citation statement)

References 53 publications

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“…220 Wu et al have developed an AuNRs@LCE active yarn that exhibits significant contraction and stable actuation characteristics. 217 A liquid crystal oligomer solution was electrospun to form micro/nanofibers, which were then twisted, cross-linked using UV, and subjected to a drafting. The active yarn demonstrated long-term stability in light absorption and actuation capabilities.…”

Section: Applications Of Photothermal Actuatorsmentioning

confidence: 99%

Design and mechanism of photothermal soft actuators and their applications

Sutar,

Latthe,

et al. 2024

J. Mater. Chem. A

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Section: Applications Of Photothermal Actuatorsmentioning

confidence: 99%

Design and mechanism of photothermal soft actuators and their applications

Sutar,

Latthe,

et al. 2024

J. Mater. Chem. A

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Stretchable and High‐Performance Fibrous Sensors Based on Ionic Capacitive Sensing for Wearable Healthcare Monitoring

Liu,

Yang,

Chen

et al. 2024

Advanced Science

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Electronic textiles with remarkable breathability, lightweight, and comfort hold great potential in wearable technologies and smart human‐machine interfaces. Ionic capacitive sensors, leveraging the advantages of the electric double layer, offer higher sensitivity compared to traditional capacitive sensors. Current research on wearable ion‐capacitive sensors has focused mainly on two‐dimensional (2D) or three‐dimensional (3D) device architectures, which show substantial challenges for direct integration with textiles and compromise their wearing experience on conformability and permeability. One‐dimensional (1D) stretchable fiber materials serve as vital components in constructing electronic textiles, allowing for rich structural design, patterning, and device integration through mature textile techniques. Here, a stretchable functional fiber with robust mechanical and electrical performances is fabricated based on semi‐solid metal and ionic polymer, which provided a high stretchability and good electrical conductivity, enabling seamless integration with textiles. Consequently, high‐performance stretchable fiber sensors are developed through different device architecture designs, including pressure sensors with high sensitivity (7.21 kPa−1), fast response (60 ms/30 ms), and excellent stability, as well as strain sensors with high sensitivity (GF = 1.05), wide detection range (0–300% strain), and excellent sensing stability under dynamic deformations.

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