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Bioinspired Impact‐Resistant and Self‐Monitoring Nanofibrous Composites

Zhen‐Bang Zhang, ZeZhou He, Xiaofeng Pan, Huai‐Ling Gao, Siming Chen, YinBo Zhu, Saisai Cao, Chunyu Zhao, Shuang Wu, Xinglong Gong, HengAn Wu, Shu‐Hong Yu

2022Small11 citationsDOI

Abstract

Abstract Lightweight and impact‐resistant materials with self‐monitoring capability are highly desired for protective applications, but are challenging to be artificially fabricated. Herein, a scalable‐manufactured aramid nanofiber (ANF)‐based composite combining these key properties is presented. Inspired by the strengthening and toughening mechanisms relying on recoverable interfaces commonly existing in biological composites, mechanically weak but dense hydrogen bonds are introduced into the ANF interfaces to achieve simultaneously enhanced tensile strength (300 MPa), toughness (55 MJ m −3 ), and impact resistance of the nanofibrous composite. The achieved mechanical property combination displays attractive advantages compared with that of most of previously reported nanocomposites. Additionally, the nanofibrous composite is designed with a capability for real‐time self‐monitoring of its structural safety during both quasi‐static tensile and dynamic impact processes, based on the strain/damage‐induced resistance variations of a conductive nanowire network inside it. These comprehensive properties enable the present nanofibrous composite with promising potential for protective applications.

Topics & Concepts

Materials scienceComposite materialComposite numberUltimate tensile strengthToughnessAramidNanofiberDelamination (geology)Self-healingNanocompositeTougheningFiberSubductionMedicinePaleontologyBiologyAlternative medicineTectonicsPathologyElectrospun Nanofibers in Biomedical ApplicationsAdvanced Sensor and Energy Harvesting MaterialsBone Tissue Engineering Materials
Bioinspired Impact‐Resistant and Self‐Monitoring Nanofibrous Composites | Litcius