Water-Modulated Biomimetic Hyper-Attribute-Gel Electronic Skin for Robotics and Skin-Attachable Wearables

Duan, Shengshun; Shi, Qiongfeng; Hong, Jianlong; Zhu, Di; Li, Yinghui; Lei, Wei; Lee, Chengkuo; Wu, Jun

doi:10.1021/acsnano.2c09851

Cited by 48 publications

(35 citation statements)

References 63 publications

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“…[31] Duan et al proposed a water-modulated biomimetic hyper-attribute-gel (Hygel) e-skin composed of MXene and silk fibroin (Figure 4b). [57] This hyper-attribute Hygel exhibited high resolution in strain sensing for bending angles, which is eligible for hand motion monitoring and dynamic gesture recognition with long-term wearing comfort, biocompatibility, and safety. This Hygel e-skin was used to achieve 1D-CNN (one-dimensional convolutional neural network) assisted highprecise classification of 15 dynamic gestures.…”

Section: Conductive-network-based Resistive Strain Sensorsmentioning

confidence: 99%

“…[69][70][71] Yet, more research should be devoted to effectively extending the service life of the hydrogel-based strain sensor, such as improving the mechanical properties of the hydrogel and overcoming the disadvantage of losing water. [57,72] Ionic-liquid-based resistive strain sensors where the sensing layer is often composed of ionic liquid and polymer. For example, Li et al proposed an ultra-durable ionic resistive strain sensor with excellent healing ability by impregnating ionic liquids into the robust poly(urea-urethane) (PU) network (Figure 4f), which was attached to a finger to detect the finger-bending.…”

Section: Conductive-network-based Resistive Strain Sensorsmentioning

confidence: 99%

Section: Resistive Sensors For Hand Gesture Recognitionmentioning

confidence: 99%

mentioning

confidence: 99%

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A Pathway into Metaverse: Gesture Recognition Enabled by Wearable Resistive Sensors

Duan

Zhao

Yang

et al. 2023

Advanced Sensor Research

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Hand gesture recognition is of great importance for human–Metaverse interaction. The human hand is relatively smaller, with very complex articulations than the entire human body. Therefore, precise hand gesture recognition, especially in complicated environments, is still a great challenge. Wearable resistive sensors that could directly characterize joint movements are one of the most promising technologies for hand gesture recognition due to their easy integration, low cost, and simple signal acquisition. Here, we summarize common categories of wearable resistive sensors for hand gesture recognition and review the recent advances. Besides, common strategies for improving waterproofness (molecular design, material modification, and interfacial encapsulation) are also outlined. Perspectives on the advantages of combining machine vision and resistive sensors for accurate hand gesture recognition and dynamic hand gesture tracking are then provided. We hope this review could inspire future research in wearable technologies for human–Metaverse systems.

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Section: Conductive-network-based Resistive Strain Sensorsmentioning

confidence: 99%

Section: Conductive-network-based Resistive Strain Sensorsmentioning

confidence: 99%

See 2 more Smart Citations

A Pathway into Metaverse: Gesture Recognition Enabled by Wearable Resistive Sensors

Duan

Zhao

Yang

et al. 2023

Advanced Sensor Research

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“…Gas sensing plays an essential role in environmental monitoring, agricultural production, and medical diagnosis, protecting humans from hazardous gases. With the development of next-generation wearable technologies, flexible electronics are designed in multiple forms to meet the various monitoring scenarios. − Sensors are usually attached to the skin surface or embedded in body-worn accessories accompanied by unstable interface states and strain fields, which are critical to the reception, processing and transmission of sensing signals. , Therefore, ensuring real-time, superior sensitive, and highly reliable gas detection has emerged as a current hotspot in the research of the human–machine interface. − …”

Section: Introductionmentioning

confidence: 99%

2D PtSe₂ Enabled Wireless Wearable Gas Monitoring Circuits with Distinctive Strain-Enhanced Performance

Wang

Duan

et al. 2023

ACS Nano

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The application of 2D materials-based flexible electronics in wearable scenarios is limited due to performance degradation under strain fields. In contrast to its negative role in existing transistors or sensors, herein, we discover a positive effect of strain to the ammonia detection in 2D PtSe 2 . Linear modulation of sensitivity is achieved in flexible 2D PtSe 2 sensors via a customized probe station with an in situ strain loading apparatus. For trace ammonia absorption, a 300% enhancement in room-temperature sensitivity (31.67% ppm −1 ) and an ultralow limit of detection (50 ppb) are observed under 1/4 mm −1 curvature strain. We identify three types of strainsensitive adsorption sites in layered PtSe 2 and pinpoint that basal-plane lattice distortion contributes to better sensing performance resulting from reduced absorption energy and larger charge transfer density. Furthermore, we demonstrate state-of-the-art 2D PtSe 2 -based wireless wearable integrated circuits, which allow real-time gas sensing data acquisition, processing, and transmission through a Bluetooth module to user terminals. The circuits exhibit a wide detection range with a maximum sensitivity value of 0.026 V•ppm −1 and a low energy consumption below 2 mW.

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Initiatorless Solar Photopolymerization of Versatile and Sustainable Eutectogels as Multi‐Response and Self‐Powered Sensors for Human–Computer Interface

Xue,

Shao,

et al. 2023

Adv Funct Materials

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Eutectogels are emerging as an appealing soft conductor for self‐powered sensing and the next generation of flexible human–computer interactive devices owing to their inherent mechanical elasticity and high ionic conductivity. However, it still remains a challenge to simultaneously achieve multi‐functional and multi‐response integrations through a facile and sustainable approach. Herein, a self‐healing, environment tolerant, intrinsically conductive, and recyclable eutectogel with multiple responses is developed via one‐step solar‐initiated polymerization of deep eutectic solvents (DESs) and ionic liquids (ILs). Abundant hydrogen bonds and ion‐dipole interactions impart eutectogels with high mechanical strength (8.8 MPa), ultra‐stretchability (>1100%), strong self‐adhesion (≈12 MPa), recyclability, and autonomously self‐healing ability. Furthermore, the intrinsically conductive eutectogels with appealing versatile sensations on strain, temperature, and humidity can serve as wearable sensors for wireless motion recognition and human–computer interaction control. More importantly, the eutectogel‐assembled single‐electrode triboelectric nanogenerator (TENG) exhibits extreme environment‐tolerant and fast self‐healable properties that contribute to maintaining excellent and stable electrical outputs in a wide work temperature range (approximately −40–60 °C), which appear to be promising in self‐powered flexible electronics with high environmental adaptability.

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Water-Modulated Biomimetic Hyper-Attribute-Gel Electronic Skin for Robotics and Skin-Attachable Wearables

Cited by 48 publications

References 63 publications

A Pathway into Metaverse: Gesture Recognition Enabled by Wearable Resistive Sensors

A Pathway into Metaverse: Gesture Recognition Enabled by Wearable Resistive Sensors

2D PtSe₂ Enabled Wireless Wearable Gas Monitoring Circuits with Distinctive Strain-Enhanced Performance

Initiatorless Solar Photopolymerization of Versatile and Sustainable Eutectogels as Multi‐Response and Self‐Powered Sensors for Human–Computer Interface

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Water-Modulated Biomimetic Hyper-Attribute-Gel Electronic Skin for Robotics and Skin-Attachable Wearables

Cited by 48 publications

References 63 publications

A Pathway into Metaverse: Gesture Recognition Enabled by Wearable Resistive Sensors

A Pathway into Metaverse: Gesture Recognition Enabled by Wearable Resistive Sensors

2D PtSe2 Enabled Wireless Wearable Gas Monitoring Circuits with Distinctive Strain-Enhanced Performance

Initiatorless Solar Photopolymerization of Versatile and Sustainable Eutectogels as Multi‐Response and Self‐Powered Sensors for Human–Computer Interface

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Product

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2D PtSe₂ Enabled Wireless Wearable Gas Monitoring Circuits with Distinctive Strain-Enhanced Performance