通过与液态金属顺序桥接诱导的超强MXene薄膜。

Ultrastrong MXene film induced by sequential bridging with liquid metal.

作者信息

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

机构信息

School of Chemistry, Key Laboratory of Bio-inspired Smart Interfacial Science and Technology of Ministry of Education, Beihang University, Beijing 100191, China.

School of Chemistry and Materials Science, University of Science and Technology of China, Hefei 230026, China.

出版信息

Science. 2024 Jul 5;385(6704):62-68. doi: 10.1126/science.ado4257. Epub 2024 Jul 4.

DOI:10.1126/science.ado4257

PMID:38963844

Abstract

Assembling titanium carbide (TiCT) 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.

摘要

将碳化钛（TiCT）MXene纳米片组装成宏观薄膜存在诸多挑战，包括孔隙、低取向度和弱界面相互作用，这些都会降低机械性能。我们展示了一种使用液态金属（LM）和细菌纤维素（BC）依次桥接MXene纳米片的超强宏观MXene薄膜（LBM薄膜），其拉伸强度达到908.4兆帕斯卡。采用刮刀涂布重复循环的逐层方法将LBM薄膜的取向度提高到0.935，而具有良好可变形性的LM将孔隙减少至5.4%的孔隙率。BC的氢键和与LM的配位键增强了界面相互作用，提高了应力传递效率。顺序桥接为将其他二维纳米片组装成高性能材料提供了一条途径。

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通过与液态金属顺序桥接诱导的超强MXene薄膜。

Ultrastrong MXene film induced by sequential bridging with liquid metal.

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