Multi‐Functional Actuators Made with Biomass‐Based Graphene‐Polymer Films for Intelligent Gesture Recognition and Multi‐Mode Self‐Powered Sensing

Weng, Mingcen; Zhou, Jiahao; Zhou, Peidi; Shang, Ruzhi; You, Minghua; Shen, Guozhen; Chen, Huamin

doi:10.1002/advs.202309846

Advanced Science

2024

DOI: 10.1002/advs.202309846

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Multi‐Functional Actuators Made with Biomass‐Based Graphene‐Polymer Films for Intelligent Gesture Recognition and Multi‐Mode Self‐Powered Sensing

Mingcen Weng,

Jiahao Zhou,

Peidi Zhou

et al.

Abstract: Multi‐functional actuation systems involve the mechanical integration of multiple actuation and sensor devices with external energy sources. The intricate combination makes it difficult to meet the requirements of lightweight. Hence, polypyrrole@graphene‐bacterial cellulose (PPy@G‐BC) films are proposed to construct multi‐responsive and bilayer actuators integrated with multi‐mode self‐powered sensing function. The PPy@G‐BC film not only exhibits good photo‐thermoelectric (PTE) properties but also possesses go… Show more

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Cited by 13 publications

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Moisture‐Driven Actuators

Tang,

Zhao,

Liu

et al. 2024

Adv Funct Materials

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Water constitutes a huge circulation network in solid, liquid and gaseous forms that contains inestimable recyclable energy. Obtaining energy from gaseous moisture is challenging but of great significance to promote the energy upgrading. The emergence of moisture‐driven actuator (MDA) provides an effective way in converting moisture energy to mechanical energy. The MDA can combine with water molecules through hygroscopicity and swell to produce macroscopic deformation. Due to the wide distribution of humidity and the wireless driving mode, MDA shows great application potential in the fields of environmental monitoring, remote control and energy harvesting. This paper comprehensively reviews the research progress of MDA from aspects of hydrophilic materials, structures, preparing methods, multi‐response integration and applications, aiming at providing guidance for the design, preparation and application of MDA. Besides, the challenges faced by MDA are analyzed and corresponding solutions are proposed, which points out the next stage developing direction of MDA.

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Moisture‐Driven Actuators

Tang,

Zhao,

Liu

et al. 2024

Adv Funct Materials

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

Zhang,

Zhou,

Liu

et al. 2024

Advanced Materials

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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 surface area of 13.6 m2 g−1) and excellent mechanical toughness (tensile stress of 5.5 MPa, and fracture toughness of 798 KJ m−3) is developed, which shows efficient asymmetric actuation to both photothermal and humidity stimuli. The HAFM consists of a metal‐organic framework (MOF)‐enhanced moisture‐responsive layer and an MXene‐improved photothermal‐responsive layer, which achieves substantial actuation with a bending curvature up to ≈7.23 cm−1 and a fast response of 0.60 cm−1 s−1. By tailoring the fiber alignment and bi‐layer thickness ratio, different types of micromanipulators, automatic walking robots, and plant robots with programmable structures are demonstrated, which are realized for self‐powered information perception of material type, object moisture, and temperature by integrating the autonomous triboelectric effect induced by photothermal‐moisture actuation. This work presents fiber materials with programable hierarchical asymmetries and inspires a common strategy for self‐powered organism‐interface robots to interact with complex environments.

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Deep‐Learning‐Assisted Triboelectric Whisker Sensor Array for Real‐Time Motion Sensing of Unmanned Underwater Vehicle

Liu,

Dong,

Jin

et al. 2024

Adv Materials Technologies

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Aquatic animals can perceive their surrounding flow fields through highly evolved sensory systems. For instance, a seal whisker array understands the hydrodynamic field that allows seals to forage and navigate in dark environments. In this work, a deep learning‐assisted underwater triboelectric whisker sensor array (TWSA) is designed for the 3D motion estimation and near‐field perception of unmanned underwater vehicles. Each sensor comprises a high aspect ratio elliptical whisker shaft, four sensing units at the root of the elliptical whisker shaft, and a flexible corrugated joint simulating the skin on the cheek surface of aquatic animals. The TWSA effectively identifies flow velocity and direction in the 3D underwater environments and exhibits a rapid response time of 19 ms, a high sensitivity of 0.2V/ms−1, and a signal‐to‐noise ratio of 58 dB. The device also locks onto the frequency of the upstream wake vortex, achieving a minimal detection accuracy of 81.2%. Moreover, when integrated with an unmanned underwater vehicle, the TWSA can estimate 3D trajectories assisted by a trained deep learning model, with a root mean square error of ≈0.02. Thus, the TWSA‐based assisted perception holds immense potential for enhancing unmanned underwater vehicle near‐field perception and navigation capabilities across a wide range of applications.

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Multi‐Functional Actuators Made with Biomass‐Based Graphene‐Polymer Films for Intelligent Gesture Recognition and Multi‐Mode Self‐Powered Sensing

Cited by 13 publications

References 50 publications

Moisture‐Driven Actuators

Moisture‐Driven Actuators

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

Deep‐Learning‐Assisted Triboelectric Whisker Sensor Array for Real‐Time Motion Sensing of Unmanned Underwater Vehicle

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