Shanghai Key Laboratory of Materials Protection and Advanced Materials in Electric Power, College of Environmental and Chemical Engineering , Shanghai University of Electric Power , Shanghai 200090 , China.
Department of Chemistry and Shanghai Key Laboratory of Molecular Catalysis and Innovative Materials, Institute of New Energy , Fudan University , Shanghai 200433 , China.
ACS Appl Mater Interfaces. 2018 Oct 31;10(43):37163-37171. doi: 10.1021/acsami.8b14971. Epub 2018 Oct 19.
Sodium-ion batteries have increasingly been considered as an attractive alternative to lithium-ion batteries for large-scale applications. High specific capacity and suitable working potential anode materials are one of the keys to search for future developments. Here, a novel and stable sodium titanate/carbon-black phosphorus (NTO/C-BP) hybrids are first fabricated as a promising anode material for advanced sodium-ion batteries. Under the protection of argon (Ar) atmosphere, the direct high-energy mechanical milling of the BP nanoparticle and NTO/C results in the formation of NTO/C-BP hybrids. In other words, the BP nanoparticle can be interconnected with bare NTO by P-O-Ti bonds and/or form stable P-C bonds with the carbon coating layer on the surface of NTO. The NTO/C-BP hybrids are not only beneficial for enhancing specific capacity but also have a great protective effect on the exposure of BP to air by the synergistic effect between BP and NTO/C. The results show that the NTO/C-BP hybrids can deliver very high specific capacity (∼225 mA h g after 55 cycles at 20 mA g, ∼183 mA h g after 100 cycles at 100 mA g). It is expected from these scientific findings that forming stable P-C bonds and P-O-Ti bonds in this work can serve as a guidance to other Ti-based and P-based electrode materials for practical large-scale application of sodium-ion batteries.
钠离子电池作为锂离子电池的替代品,在大规模应用中越来越受到关注。高比容量和合适的工作电位的阳极材料是寻找未来发展方向的关键之一。本文首次制备了一种新型稳定的钛酸钠/碳黑磷(NTO/C-BP)杂化物,作为先进钠离子电池的一种有前途的阳极材料。在氩气(Ar)气氛的保护下,BP 纳米粒子和 NTO/C 的直接高能机械研磨导致 NTO/C-BP 杂化物的形成。换句话说,BP 纳米粒子可以通过 P-O-Ti 键与裸露的 NTO 相互连接,或者与 NTO 表面的碳涂层形成稳定的 P-C 键。NTO/C-BP 杂化物不仅有利于提高比容量,而且通过 BP 和 NTO/C 之间的协同作用,对 BP 暴露在空气中具有很好的保护作用。结果表明,NTO/C-BP 杂化物在 20 mA g 下 55 次循环后可提供非常高的比容量(约 225 mA h g),在 100 mA g 下 100 次循环后可提供约 183 mA h g 的比容量。从这些科学发现可以预期,在这项工作中形成稳定的 P-C 键和 P-O-Ti 键可以为其他基于 Ti 和 P 的电极材料在钠离子电池的实际大规模应用中提供指导。
