Litcius/Paper detail

Mussel byssus cuticle-inspired ultrastiff and stretchable triple-crosslinked hydrogels

Chenglong Dong, Hailong Fan, Feng Tang, Xiaobin Gao, Kai Feng, Jiahui Wang, Zhaoxia Jin

2020Journal of Materials Chemistry B26 citationsDOI

Abstract

Applications in the harsh environment require hydrogels with ultra-stiffness, toughness, and stretchability. However, it remains a challenge to increase the elastic modulus without sacrificing the maximum elongation of hydrogels, because of the trade-off between stiffness and extensibility. Inspired by the crosslinking hierarchy of mussel byssus cuticle, here, we report a strategy to fabricate an ultra-stiff, tough and stretchable triple-crosslinked (TC) hydrogel. The polymer is crosslinked by chemical crosslinker at first, subsequently by introducing a polyphenolic compound, tannic acid (TA), and metal ions. The hydrogen-bond-based network between the polymer and TA works as an extensible and energy-dissipative network, mimicking the matrix of the cuticle, while the higher crosslinked domains formed by the coordinate bonds between TA and metal ions contribute to the stiffness. The triple-crosslinked hydrogel exhibits two orders of magnitude increase in stiffness (E = 58 MPa), but without sacrificing the maximum elongation (ε = 850%), compared with those of metal-free hydrogels (E = 0.18 MPa, and ε = 860%). The combination of ultra-stiffness, toughness, and stretchability in hydrogels is successfully achieved through leveraging the hierarchically cross-linked network based on hydrogen bonding and coordination bonding. Moreover, utilizing the wide distribution of bonding strength of coordination interaction, the mechanical properties of triple-crosslinked hydrogels can be manipulated by using different kinds of catechol-metal coordination.

Topics & Concepts

Self-healing hydrogelsMaterials scienceToughnessComposite materialPolymerStiffnessHydrogen bondChemical engineeringPolymer chemistryMoleculeChemistryOrganic chemistryEngineeringHydrogels: synthesis, properties, applicationsAdvanced Sensor and Energy Harvesting MaterialsPolymer Surface Interaction Studies