化学
磁滞
阴极
阳离子聚合
离子半径
氧化还原
无机化学
氧化物
电化学
半径
电压
离子键合
离子
化学物理
联轴节(管道)
钠
工作(物理)
化学工程
氧气
硫酸盐
析氧
离子电导率
作者
Jiahao Jiao,Ze Hua,Feiran Shen,Ren H,Yi Zhou,Yilong Niu,Tianwei Cui,Yuan Wang,H X Bi,Yuxuan Zuo,Cheng‐Wei Kao,Ting-Shan Chan,Zhenhua Chen,Liang Zhang,Qing Wang,He Lp,Fanghua Ning,Ruiwen Shao,Biao Li
摘要
Voltage hysteresis in layered oxide cathodes of Li/Na-ion batteries, a significant barrier to energy efficiency, is commonly attributed to reversible cation migration. This is particularly prevalent in materials utilizing anionic redox for high capacity, yet the strong coupling between cation migration and complex anionic processes (such as O–O dimerization, oxygen loss, and charge transfer) has obscured a definitive causal link. To decouple these phenomena, we designed a series of P2-type Na 2/3 Ni 0.1 M 0.1 Mn 0.8 O 2 compounds, where M is an electrochemically inactive trivalent cation (Al 3+, Ga 3+, Sc 3+ ) of increasing ionic radius (0.535 Å, 0.62 Å, 0.745 Å). Interestingly, these systems exhibit negligible anionic redox activity but display increasing voltage hysteresis that scales with the size of the M 3+ cations. Through a combination of experimental and theoretical analyses, we correlate this hysteresis with an enhanced tendency for reversible interlayer cation migration of M 3+, which is facilitated by a larger cationic size that is more adaptive to the large Na interlayer spacing. By successfully isolating cation migration from anionic redox, this work establishes its direct role in driving voltage hysteresis, providing fundamental insights into the design of cathode materials having less cation migration and reduced voltage hysteresis for Na-ion batteries.
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