尖晶石
阴极
化学
兴奋剂
相(物质)
工作(物理)
理论(学习稳定性)
超短脉冲
转化(遗传学)
化学稳定性
光电子学
化学物理
化学工程
纳米晶
纳米技术
热力学
块(置换群论)
分析化学(期刊)
极化子
热稳定性
作者
H B Wu,C ZHANG,Siqi Guan,Pei Tang,Xulin Mu,Yutao Niu,Chunyang Wang,Feng Li
摘要
Next-generation lithium-ion batteries demand high-voltage cathodes that combine exceptional stability with ultrafast charging capability. Cobalt-free spinel-type oxides, owing to their high operating voltage, energy density, and cost effectiveness, are leading candidates, yet their cycle life is still constrained by intrinsic chemo-electro-mechanical instabilities. Here, by leveraging compositionally complex doping, we reconfigure the reaction thermodynamics of a high-voltage spinel cathode by extending its solid-solution regime to higher states of charge, enabling ultrafast charging while maintaining robust chemo-electro-mechanical stability. Multimodal characterization reveals that the reshaped reaction pathway effectively suppresses high-temperature intragranular cracking, interfacial rock salt phase transformation, and parasitic byproduct accumulation, thereby preserving efficient three-dimensional Li + diffusion. The cathode delivers unprecedented ultrafast-charging durability, achieving 81.8% after 4000 cycles at 10 C (25 °C) and 82.0% after 1000 cycles at 3 C (60 °C). Our work demonstrates that compositionally complex doping can effectively modulate the thermodynamics of phase transformation and enhance the chemo-electro-mechanical stability of high-voltage spinel cathodes, providing new insights into the design of durable fast-charging cathode materials.
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