Ruijia Liu, Naichao Li, Enyue Zhao, Jinkui Zhao, Lingxu Yang, Wenjun Wang, H. Liu, C. Zeng
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引用次数: 11
摘要
过渡金属氮化物(TMNs),包括氮化钛(TiN),作为耐用高速率锂离子电池(LIBs)的阳极具有显著的应用前景。遗憾的是,缺乏简单的合成方法限制了它们的进一步发展。本文提出了一种简单、低成本的熔盐合成策略,以制备碳锚定的TiN纳米颗粒作为具有高速率性能的锂离子电池的先进阳极材料。所获得的纳米TiN尺寸为~ 5nm,分布均匀,在250次循环后可释放出~ 381.5 mAh g - 1 (0.1 a g - 1)的可逆容量,在1000次循环后可释放出~ 141.5 mAh g - 1 (1.0 a g - 1)的可逆容量。进一步证实了电化学反应过程中发生了TiN和li离子的转化反应,生成了Li3N和Ti。这种独特的微观结构归因于碳锚定的TiN纳米颗粒可以在循环过程中支持结构体积。这项工作强调了通过熔盐合成策略制备TiN作为lib阳极的方法优势,具有令人印象深刻的速率性能。
Facile molten salt synthesis of carbon-anchored TiN nanoparticles for durable high-rate lithium-ion battery anodes
Transition metal nitrides (TMNs), including titanium nitride (TiN), exhibit remarkable application prospects as anodes for durable high-rate lithium-ion batteries (LIBs). Regrettably, the absence of simple synthesis methods restricts their further development. Herein, a facile and low-cost molten salt synthesis strategy was proposed to prepare carbon-anchored TiN nanoparticles as an advanced anode material for LIBs with high rate capabilities. This nanosized TiN obtained is ∼5 nm in size and well-distributed onto carbon plates, which could release a reversible capacity of ∼381.5 mAh g−1 at 0.1 A g−1 after 250 cycles and ∼141.5 mAh g−1 at 1.0 A g−1 after 1000 cycles. Furthermore, it was confirmed that the conversion reaction between TiN and Li-ions happened during the electrochemical reaction process, resulting in the formation of Li3N and Ti. This unique microstructure attributed from TiN nanoparticles anchored by carbon could support the structural volume during cycling. This work highlights the method superiority of TiN prepared via a molten salt synthesis strategy as an anode for LIBs with impressive rate performances.
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