水溶液
MXenes公司
材料科学
电化学
阴极
氧化还原
无定形固体
退火(玻璃)
离子
储能
化学工程
价(化学)
导电体
电导率
扩散阻挡层
扩散
纳米技术
无机化学
动力学
电阻率和电导率
电极
作者
Guangcai Zhao,Shuo Meng,Zhongyuan Zheng,Jian Guo,Lu Chen,Hongli Zheng,Peng Zhang,Jia Yu,Lujie Zuo,Hongbin Zhao,Ting He
标识
DOI:10.1016/j.gce.2025.12.001
摘要
Vanadium-based compounds are promising cathodes for aqueous zinc ion batteries owing to their high capacity derived from multi-electron redox reactions. However, their practical application is often hampered by poor rate capability, caused by low electrical conductivity and sluggish Zn 2+ diffusion kinetics. Herein, we propose a precise amorphization strategy applied to conductive V 2 CT x MXene to overcome these limitations. Starting from exfoliated few-layer V 2 CT x , a controlled annealing process in argon induces a crystalline-to-amorphous transition, which effectively elevates the valence state of surface vanadium, creates abundant active sites for Zn 2+ storage, and expands the interlayer spacing to facilitate ion diffusion. Meanwhile, the intrinsic conductive V-C-V framework remains intact, ensuring rapid electron transport. As a result, the amorphous a-V 2 CT x cathode delivers remarkable electrochemical performance: a high reversible capacity of 543 mAh/g at 1 A/g, exceptional rate capability (494 mAh/g at 30 A/g), and outstanding cycling stability over 3000 cycles with a minimal decay rate of 0.012% per cycle. This work demonstrates the great potential of phase engineering MXenes for developing high-performance energy storage materials. Amorphization engineering of V 2 CT x MXene enables superior aqueous Zn-ion storage by synergistically enhancing ion diffusion kinetics and redox active sites. • Controlled amorphization boosts V valence and Zn²⁺ storage, enabling high capacity. • The conductive V–C–V network ensures fast electron/ion transport and high rate capability. • The a-V₂CTₓ cathode breaks the capacity–rate–stability trade-off in AZIBs.
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