A composite hydrogel exhibiting stiff response at low-strain regime by repulsion effect of positive/negative Poisson’s ratio

Shi, Wei; Huang, Jin; Zhou, Tianxu; Xu, Yichao; Yan, Hao; Liu, Mingjie

doi:10.1007/s40843-022-2336-y

Cited by 4 publications

(1 citation statement)

References 34 publications

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“…67 Shi et al introduced hydrogel elastic network into the preprinted elastic framework, combining soft hydrogel matrix with positive Poisson's ratio and hard framework with negative Poisson's ratio (Figure 10). 68 The obtained composite hydrogel exhibits a unique stiff response, which provides a new idea for designing soft−hard synergistic hydrogel materials.…”

Section: Multiphase Network Gels Composed Of Elastic Networkmentioning

confidence: 99%

Bioinspired Multiphase Gels Using Spatial Confinement Strategy

Zhang,

Zhao,

Liu

2024

Acc. Mater. Res.

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Metrics & MoreArticle Recommendations CONSPECTUS: Hydrogels are ideal candidates for various advanced applications, including wearable electronics, soft robots, and biomedical engineering, which benefit from their natural merits of softness, deformability, and biocompatibility. In the early stages since the emergence of hydrogels, tremendous efforts have been made to improve their mechanical performances. Despite the investigation of several mechanical strengthening strategies, including nanocomposites, noncovalent cross-linking, and topological design, single network hydrogels still grapple with the tradeoff between mechanical strength and functionality. As a result, improving network complexity and functional diversification have emerged as a significant trend in gel development. Multiphase gels are developed to incorporate mechanical enhancement components and functional components, obtaining integrated exceptional performances. This Account seeks to review mechanical strength-function integrated gels fabricated by bioinspired multiphase confinement strategy, providing inspiration and guidance for multiphase gel design. The first part starts with a specific elaboration on bioinspired strategy, involving tissue structure analysis, biological mechanism imitation, and bioinspired materials fabrication. By exploring human skeletal muscle and nacre, we elucidate how to connect biological structures and artificial material design concretely. Meanwhile, we highlight the promotion effect of in-depth analysis on the biological micro structure and working mechanism. In the next part, we subsequently evaluate diverse multiphase network structures that were previously developed and showcase their exceptional performances and unique applications. Multiple gels developed by our group�phase separation ionic gels for stiffness changing materials, phase transition organohydrogels for actuation, interpenetrating organohydrogels for lubrication, etc.�are reviewed in this section. The most crucial point for the fabrication of these multiphase gels is stability, which inextricably links to their interface interactions. Therefore, we summarize the techniques employed to establish ultrastable interfaces, such as emulsion interface interaction or heterogeneous interpenetrating networks. We delve into the manifold network structures of multiphase polymers, encompassing plasticity, elasticity, hydrophilicity, and hydrophobicity. Different fabrication strategies were adopted according to their network properties, with the aim of exhibiting their unique mechanical strength and functions. In these confined multiphase structures, the independent motions of orthogonal networks are achieved. Additionally, polymers confined in space in nanometer scale or smaller can exhibit performances deviated from bulk phase, including crystallinity, alignment degree, and glass transition temperature. The discussion also covers the confinement effects on the polymer structure and mobility. Ultimately, we introduce the advanced applications of multiphase ge...

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Section: Multiphase Network Gels Composed Of Elastic Networkmentioning

confidence: 99%