Synthesis of MXene and its application for zinc-ion storage

Since 2020, some new breakthroughs in the field of MXene synthesis scheme such as water-free etching, HCl-based hydrothermal etching, halogen etching, and other novel synthesis methods have been proposed. Not only that, the application of MXene in zinc-ion storage devices has also made great progress in the past 2 years. The understanding of zinc-ion storage mechanism of MXene has undergone profound changes, and its applications have also become diversified, demonstrating the great potential of MXene for high performance zinc-ion storage devices. In this review, we have summarized the preparation and synthesis of MXene materials and systematically investigated the progress of MXene in aqueous zinc-ion storage devices. In particular, for the synthesis of MXene, we added recent reports of conventional synthesis schemes that have been widely reported to help understand their development and combined with recent novel synthesis schemes to provide a distinct partition framework. In addition, for the application of MXene, we discussed the cognitive change of zinc-ion storage mechanism of MXene and conducted an in-depth discussion about the design philosophy of MXene and their characteristics. Finally, a comprehensive perspective on the future development of MXene in the synthetic strategy and aqueous zinc-ion storage applications have been outlined.

Automated summary

Recent breakthroughs have been made in the synthesis of MXene, a two-dimensional material, and its application in zinc-ion storage devices. This review provides a comprehensive summary of the progress in the preparation and synthesis of MXene materials and explores its potential in aqueous zinc-ion storage applications. The future development of MXene in synthetic strategies and zinc-ion storage devices is also discussed.