Highly‐Aligned All‐Fiber Actuator with Asymmetric Photothermal‐Humidity Response and Autonomous Perceptivity

Zhang, Yufan; Zhou, Xinran; Liu, Luyun; Wang, Shuang; Zhang, Yue; Wu, Mengjie; Lu, Zeren; Ming, Zechang; Tao, Jin; Xiong, Jiaqing

doi:10.1002/adma.202404696

Advanced Materials

2024

DOI: 10.1002/adma.202404696

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Highly‐Aligned All‐Fiber Actuator with Asymmetric Photothermal‐Humidity Response and Autonomous Perceptivity

Yufan Zhang,

Xinran Zhou,

Luyun Liu

et al.

Abstract: Soft robots adapt to complex environments for autonomous locomotion, manipulation, and perception are attractive for robot‐environment interactions. Strategies to reconcile environment‐triggered actuation and self‐powered sensing responses to different stimuli remain challenging. By tuning the in situ vapor phase solvent exchange effect in continuous electrospinning, an asymmetric highly‐aligned all‐fiber membrane (HAFM) with a hierarchical “grape‐like” nanosphere‐assembled microfiber structure (specific surfa… Show more

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Cited by 5 publications

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Microfiber Actuators With Hot‐Pressing‐Programmable Mechano‐Photothermal Responses for Electromagnetic Perception

Wu,

Zhou,

Zhang

et al. 2024

Advanced Materials

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Electromagnetic radiation (EMR) is a ubiquitous harm and hard to detect dynamically in multiple scenarios. A mechano‐photothermal cooperative microfiber film (MFF) actuator is developed that can synchronously detect EMR with high reliability. The programmable actuation is deployed by a hot‐pressing methodology, achieving the MFF with moderate modulus (378 MPa) and superior toughness (87.26 MJ m−3) that ensure superior response (0.068 cm−1 s−1) and bending curvature (0.63 cm−1). A secondary hot‐pressing can further program the actuation behavior with black phosphorus local photothermal enhancement patterns to achieve 2D–3D transformable geometries. An amphibious robot with a land–water adaptive locomotion mechanism is designed by programming the MFFs. It can crawl on land and locomote on water with a velocity up to ≈1.8 mm s−1, and ≈2.39 cm s−1, respectively. Employing the conductive fabric layer of the actuator with electromagnetic induction effect, the amphibious robot can synchronously perceive environmental EMR with sensitivity up to 99.73% ± 0.15% during locomotion, with superior adaptability to EMR source intensity (0.1 to 3000 W) and distance (≈9 m) compared to a commercial EMR detector. This EMR detective microfiber actuator can inspire a new direction of environment‐interactive smart materials, and soft robots with multi‐scenario adaptivity and autonomous environment perceptivity.

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Microfiber Actuators With Hot‐Pressing‐Programmable Mechano‐Photothermal Responses for Electromagnetic Perception

Wu,

Zhou,

Zhang

et al. 2024

Advanced Materials

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Aloe Leaves‐Inspired Multi‐Stimuli Bidirectional Bending Self‐Sensing Actuator for Smart Solar Panel

Yan,

Tang,

Zong

et al. 2024

Small

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Soft actuators with multi‐stimuli response have shown promising applications in soft intelligent robots. However, most soft actuators are limited by the unidirectional actuation and self‐perception capabilities. Here, a bilayer self‐sensing actuator with bidirectional actuation is proposed, which showed exceptional bidirectional actuation, self‐sensing of temperature and moisture, and smart solar panel. The actuator layer consisted of the powerful hygroscopic sensitivity of poly(vinyl alcohol) (PVA), poly(sodium styrene sulfonate) (PSS), and the conductive carbon black (CB). The structural layer is hydrophobic polyurea (PUU). The bilayer self‐sensing actuator is bent to one side under NIR or temperature stimulation (curvature reaches 3.8 cm−1) and bent to opposite side with moisture stimulation (curvature reaches −4.6 cm−1). Moreover, various bionic robots, weightlifting, and selective grasping robots are demonstrated. Simultaneously, owing to CB gradient, the bilayer sensing actuators can detect movement in different bending directions with a fast response speed (82 ms). In addition, when moisture increased, the smart solar panel bent to downward and cleaned the debris. Upon the sunshine, the smart solar panel faced to sun and maximized power output. More interestingly, the smart solar panel can monitor its bending degree and orientation. The proposed bilayer self‐sensing actuator paved the way for advancements in artificial intelligence robots.

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Tendril-inspired programmable soft actuator based on bilayer thermoplastic film

Hao,

Qiu,

Dai

et al. 2025

Chemical Engineering Journal

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Highly‐Aligned All‐Fiber Actuator with Asymmetric Photothermal‐Humidity Response and Autonomous Perceptivity

Cited by 5 publications

References 59 publications

Microfiber Actuators With Hot‐Pressing‐Programmable Mechano‐Photothermal Responses for Electromagnetic Perception

Microfiber Actuators With Hot‐Pressing‐Programmable Mechano‐Photothermal Responses for Electromagnetic Perception

Aloe Leaves‐Inspired Multi‐Stimuli Bidirectional Bending Self‐Sensing Actuator for Smart Solar Panel

Tendril-inspired programmable soft actuator based on bilayer thermoplastic film

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