微尺度化学
材料科学
同质性(统计学)
纳米尺度
阴极
纳米技术
能量密度
密度泛函理论
电化学
杂质
电流密度
化学工程
科技与社会
光电子学
材料设计
材料加工
作者
Sang‐Wook Park,Hojoon Kim,Sangwook Han,Kyoung Sun Kim,You‐Yeob Song,Haeshin Lee,Won-Ick Jang,Dae‐Hyung Lee,S. J. Bae,Dong-Woo Kim,Jungwoo Park,Inchul Park,Sang Cheol Nam,Hyungsub Kim,Jinhyuk Lee,Kisuk Kang,Dong‐Hwa Seo
标识
DOI:10.1002/aenm.202503496
摘要
Abstract Manganese‐based disordered rock‐salt (Mn‐DRX) cathodes provide high energy density and exceptional compositional tunability, which enables the rational design and discovery of advanced DRX chemistries. However, exploration across the vast Mn‐DRX design space remains hindered by the slow and energy‐intensive nature of traditional synthesis methods. Here, the Joule‐heating (JH) method is demonstrated to enable rapid and energy‐efficient synthesis of high‐performance Mn‐DRX cathodes. Through a case study of Li 1.2 Mn 0.4 Ti 0.4 O 2 (LMTO), we show that optimizing DRX materials under rapid synthesis requires controlling both nanoscale short‐range ordering (SRO) and microscale features such as bulk homogeneity and impurity phases, highlighting that microscale features are as critical as SRO. Based on this understanding, we show that a JH‐synthesized LMTO (annealed at 1050 °C just for 10 min) achieves a near‐phase‐pure DRX structure with uniform elemental distribution and reduced SRO compared to furnace‐synthesized LMTO (annealed at 950 °C for 12 h), leading to improved rate capability (161 vs 137 mAh g −1 at 1 A/g). Additionally, using the JH system, various DRX compositions are synthesized with electrochemical performance comparable to that of furnace‐synthesized counterparts, demonstrating its versatility. These findings demonstrate that rapid JH synthesis offers a robust approach to producing high‐performance Mn‐DRX cathodes, paving the way for high‐throughput discovery across the vast DRX design space.
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