Toughening Elastomers Using a Mussel-Inspired Multiphase Design

Xuhui Zhang; Jun Liu; Zhiyu Zhang; Siwu Wu; Zhenghai Tang; Baochun Guo; Liqun Zhang

doi:10.1021/acsami.8b08844

Toughening Elastomers Using a Mussel-Inspired Multiphase Design

Xuhui Zhang
, Jun Liu
, Zhiyu Zhang
, Siwu Wu
, Zhenghai Tang
, Baochun Guo
, Liqun Zhang

科研成果: 期刊稿件 › 文章 › 同行评审

75 引用（Scopus）

摘要

It is a challenge to simultaneously achieve high stretchability, high modulus, and recoverability of polymers. Inspired by the multiphase structure of mussel byssus cuticles, we circumvent this dilemma by introducing a deformable microphase-separated granule with rich coordination into a ductile rubber network. The granule can serve as an additional cross-link to improve the modulus, while the sacrificial, reversible coordination can dissociate and reconstruct continuously during stretching to dissipate energy. The elastomer with such a bioinspired multiphase structure exhibits over a 10-fold increase in toughness compared to the original sample. We envision that this work offers a novel yet facile biomimetic route toward high-performance elastomers.

源语言	英语
页（从-至）	23485-23489
页数	5
期刊	ACS Applied Materials and Interfaces
卷	10
期	28
DOI	https://doi.org/10.1021/acsami.8b08844
出版状态	已出版 - 18 7月 2018
已对外发布	是

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abstract = "It is a challenge to simultaneously achieve high stretchability, high modulus, and recoverability of polymers. Inspired by the multiphase structure of mussel byssus cuticles, we circumvent this dilemma by introducing a deformable microphase-separated granule with rich coordination into a ductile rubber network. The granule can serve as an additional cross-link to improve the modulus, while the sacrificial, reversible coordination can dissociate and reconstruct continuously during stretching to dissipate energy. The elastomer with such a bioinspired multiphase structure exhibits over a 10-fold increase in toughness compared to the original sample. We envision that this work offers a novel yet facile biomimetic route toward high-performance elastomers.",

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author = "Xuhui Zhang and Jun Liu and Zhiyu Zhang and Siwu Wu and Zhenghai Tang and Baochun Guo and Liqun Zhang",

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AU - Zhang, Xuhui

AU - Liu, Jun

AU - Zhang, Zhiyu

AU - Wu, Siwu

AU - Tang, Zhenghai

AU - Guo, Baochun

AU - Zhang, Liqun

PY - 2018/7/18

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N2 - It is a challenge to simultaneously achieve high stretchability, high modulus, and recoverability of polymers. Inspired by the multiphase structure of mussel byssus cuticles, we circumvent this dilemma by introducing a deformable microphase-separated granule with rich coordination into a ductile rubber network. The granule can serve as an additional cross-link to improve the modulus, while the sacrificial, reversible coordination can dissociate and reconstruct continuously during stretching to dissipate energy. The elastomer with such a bioinspired multiphase structure exhibits over a 10-fold increase in toughness compared to the original sample. We envision that this work offers a novel yet facile biomimetic route toward high-performance elastomers.

AB - It is a challenge to simultaneously achieve high stretchability, high modulus, and recoverability of polymers. Inspired by the multiphase structure of mussel byssus cuticles, we circumvent this dilemma by introducing a deformable microphase-separated granule with rich coordination into a ductile rubber network. The granule can serve as an additional cross-link to improve the modulus, while the sacrificial, reversible coordination can dissociate and reconstruct continuously during stretching to dissipate energy. The elastomer with such a bioinspired multiphase structure exhibits over a 10-fold increase in toughness compared to the original sample. We envision that this work offers a novel yet facile biomimetic route toward high-performance elastomers.

KW - biomimetic

KW - coordination

KW - elastomer

KW - multiphase structure

KW - toughening

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JO - ACS Applied Materials and Interfaces

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ER -

Toughening Elastomers Using a Mussel-Inspired Multiphase Design

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