Highly tough, crack‐resistant and self‐healable piezo‐ionic skin enabled by dynamic hard domains with mechanosensitive ionic channel

Wang, XueBin; Liu, Tong; Sun, FuYao; Zhang, Jingyi; Yao, BoWen; Xu, JianHua; Fu, JiaJun

doi:10.1002/smo.20240008

Smart Molecules

2024

DOI: 10.1002/smo.20240008

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Highly tough, crack‐resistant and self‐healable piezo‐ionic skin enabled by dynamic hard domains with mechanosensitive ionic channel

XueBin Wang,

Tong Liu,

FuYao Sun

et al.

Abstract: Robust and reliable piezo‐ionic materials that are both crack resistant and self‐healable like biological skin hold great promise for applications inflexible electronics and intelligent systems with prolonged service lives. However, such a combination of high toughness, superior crack resistance, autonomous self‐healing and effective control of ion dynamics is rarely seen in artificial iontronic skin because these features are seemingly incompatible in materials design. Here, we resolve this perennial mismatch… Show more

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Cited by 3 publications

References 69 publications

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Smart luminescent nanoclusters with dynamic covalent bond for reversible information encryption

Chen,

Gao,

Liu

et al. 2024

Smart Molecules

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Luminescent nanoclusters (NCs) have attracted much attention because of their superior photophysical properties; however, the design of dynamic NCs with reversible structural change is highly challenging. Herein, we synthesize a kind of dynamic luminescent NCs through Schiff base crosslinking between triethylenetetramine (TETA) and tannic acid at room temperature. The proposed NCs have an excitation‐independent blue emission, and the maximum emission is available at about 458 nm with two excitation centers. Furthermore, the crosslinking degree of the NCs can be effectively adjusted by TETA and their formation is a kinetic‐control process. Most importantly, the proposed NCs show a property of pH‐controlled reversible depolymerization and polymerization, accompanied by a cyclic “on‐off‐on” photoswitching, which is directly attributed to pH‐stimulated reversible C=N bond cleavage and re‐formation. Because of the reversible structure change properties, the dynamic NCs have been well used in reversible information encryption. This new finding provides not only us with a powerful strategy to study the structure–properties relationship of luminescent NCs but also a design idea for constructing smart optical nanomaterials.

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Smart luminescent nanoclusters with dynamic covalent bond for reversible information encryption

Chen,

Gao,

Liu

et al. 2024

Smart Molecules

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An Underwater Self-Healing Polysulfide Elastomer with In-Situ Curing and Adhesion

Lu,

Zhang,

Gao

et al. 2024

Polymer Science & Technology

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As oceanic activities expand, the strategic importance of designing multifunctional materials suitable for underwater applications becomes increasingly apparent. Underwater selfhealing materials offer significant advantages by autonomously repairing damage in-situ during operations, thereby minimizing resource waste and enhancing environmental sustainability. However, most self-healing materials do not have sufficient stability in aquatic environments due to the presence of watersensitive weak cross-linking bonds. Herein, polysulfide elastomers capable of underwater self-healing have been developed through a straightforward, one-step thiol−ene click reaction strategy. This reaction can occur in-situ underwater due to its water insensitivity. The abundance of disulfide bonds in the elastomer enables the formation of coordination bonds with metals, endowing the material with outstanding underwater metal adhesion properties. The optimal elastomer LPTM-55 shows extraordinary toughness of 1.49 MJ/m 3 , underwater self-healing efficiency of 90% within 7 h and adhesion strength up to 1.2 MPa. This innovative material, characterized by its underwater curing, adhesion and self-healing capabilities, demonstrates significant potential for applications in underwater sealing and repair.

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A multi-modal deformation sensing hydrogel with a nerve-inspired highly anisotropic structure

Zhang,

Chen,

et al. 2025

J. Mater. Chem. A

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Highly tough, crack‐resistant and self‐healable piezo‐ionic skin enabled by dynamic hard domains with mechanosensitive ionic channel

Cited by 3 publications

References 69 publications

Smart luminescent nanoclusters with dynamic covalent bond for reversible information encryption

Smart luminescent nanoclusters with dynamic covalent bond for reversible information encryption

An Underwater Self-Healing Polysulfide Elastomer with In-Situ Curing and Adhesion

A multi-modal deformation sensing hydrogel with a nerve-inspired highly anisotropic structure

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