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Ultrastrong MXene film induced by sequential bridging with liquid metal

Wei Li, Tianzhu Zhou, Zejun Zhang, Lei Li, Wangwei Lian, Yanlei Wang, Junfeng Lu, Jia Yan, Huagao Wang, Lei Wei, Qunfeng Cheng

2024Science226 citationsDOI

Abstract

) MXene nanosheets into macroscopic films presents challenges, including voids, low orientation degree, and weak interfacial interactions, which reduce mechanical performance. We demonstrate an ultrastrong macroscopic MXene film using liquid metal (LM) and bacterial cellulose (BC) to sequentially bridge MXene nanosheets (an LBM film), achieving a tensile strength of 908.4 megapascals. A layer-by-layer approach using repeated cycles of blade coating improves the orientation degree to 0.935 in the LBM film, while a LM with good deformability reduces voids into porosity of 5.4%. The interfacial interactions are enhanced by the hydrogen bonding from BC and the coordination bonding with LM, which improves the stress-transfer efficiency. Sequential bridging provides an avenue for assembling other two-dimensional nanosheets into high-performance materials.

Topics & Concepts

Materials scienceBridging (networking)PorosityComposite materialUltimate tensile strengthCoatingLayer (electronics)MetalTitaniumNanotechnologyMetallurgyComputer scienceComputer networkMXene and MAX Phase MaterialsAdvanced Materials and MechanicsAdvanced Sensor and Energy Harvesting Materials