电负性
阳离子聚合
氧化还原
掺杂剂
无机化学
化学
离子
电化学
兴奋剂
材料科学
物理化学
有机化学
电极
光电子学
作者
Pengrui Liang,Kaiwen Qi,Shiyuan Chen,Xuan Ding,Xiaojun Wu,Changzheng Wu,Yongchun Zhu
标识
DOI:10.1002/ange.202318186
摘要
Abstract LiNi 0.8 Co 0.1 Mn 0.1 O 2 (NCM‐811) exhibits the highest capacity in commercial lithium‐ion batteries (LIBs), and the high Ni content (80 %) provides the only route for high energy density. However, the cationic structure instability arisen from the increase of Ni content (>80 %) limits the further increase of the capacity, and inevitable O 2 release related to anionic structure instability hinders the utilization of anion redox activity. Here, by comparing various combinations of high‐entropy dopants substituted Co element, we propose a low‐electronegativity cationic high‐entropy doping strategy to fabricate the high‐Ni Co‐free layered cathode (LiNi 0.8 Mn 0.12 Al 0.02 Ti 0.02 Cr 0.02 Fe 0.02 O 2 ) that exhibits much higher capacity and cycling stability. Configurational disorder originated from cationic high‐entropy doping in transition metal (TM) layer, anchors the oxidized lattice oxygen ((O 2 ) n− ) to preserve high (O 2 ) n− content, triggering the anion redox activity. Electron transfer induced by applying TM dopants with lower electronegativity than that of Co element, increases the electron density of O in TM‐O octahedron (TM‐O 6 ) configuration to reach higher (O 2 ) n− content, resulting in the higher anion redox activity. With exploring the stabilization effect on both cations and anions of high‐entropy doping and low‐electronegativity cationic modified anion redox activity, we propose an innovative and variable pathway for rationally tuning the properties of commercial cathodes.
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