Tough, rapid-recovery composite hydrogels fabricated via synergistic core-shell microgel covalent bonding and Fe 3+ coordination cross-linking

Tough, rapid-recovery composite hydrogels fabricated via synergistic core-shell microgel covalent bonding and Fe 3+ coordination cross-linking

We developed tough, rapid-recovery composite hydrogels that are fabricated via core-shell microgel covalent bonding and Fe dynamic metal coordination cross-linking. First, core-shell microgels are used as cross-linking agents and initiators to prepare homogeneous hydrogel networks with rapid recover...

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Veröffentlicht in:Soft matter 2017-04, Vol.13 (14), p.2654-2662
Hauptverfasser: Liang, Xuechen, Deng, Yukun, Pei, Xiaopeng, Zhai, Kankan, Xu, Kun, Tan, Ying, Gong, Xinyuan, Wang, Pixin
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container_end_page 2662
container_issue 14
container_start_page 2654
container_title Soft matter
container_volume 13
creator Liang, Xuechen
Deng, Yukun
Pei, Xiaopeng
Zhai, Kankan
Xu, Kun
Tan, Ying
Gong, Xinyuan
Wang, Pixin
description We developed tough, rapid-recovery composite hydrogels that are fabricated via core-shell microgel covalent bonding and Fe dynamic metal coordination cross-linking. First, core-shell microgels are used as cross-linking agents and initiators to prepare homogeneous hydrogel networks with rapid recovery in the absence of an organic cross-linking agent. The toughness and recoverability of the composite hydrogels can be improved by adding the dynamic reversibility of ionic cross-linking. Owing to the synergistic effect of microgel covalent bonding, Fe coordination cross-linking, and H-bond cross-linking, the multi-cross-linked composite hydrogels exhibit excellent toughness and a fast recovery rate. These characteristics demonstrate that the dynamic reversibility of the ionic cross-linking can significantly improve the toughness and recoverability of the hydrogels. In addition, the core-shell microgels play a key role in toughening the hydrogels and accelerating their recovery by transferring stress to grafted polymer chains and homogenizing the hydrogel network.
doi_str_mv 10.1039/C7SM00125H
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title Tough, rapid-recovery composite hydrogels fabricated via synergistic core-shell microgel covalent bonding and Fe 3+ coordination cross-linking
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