尖晶石
阴极
溶解
材料科学
电解质
四方晶系
化学工程
降级(电信)
氧化还原
阳极
锰
相(物质)
冶金
电极
化学
物理化学
电气工程
工程类
有机化学
作者
Dawei Xia,Junyi Yao,Chenguang Shi,Qianxi Wang,Changgyu Seok,Afolabi Uthmon Olayiwola,Weibo Huang,Dennis Nordlund,Si Athena Chen,Cheng‐Jun Sun,Luxi Li,Dewen Hou,Lina Quan,Yuzi Liu,Hui Xiong,Feng Lin
标识
DOI:10.1002/adma.202501352
摘要
Mn-rich cathodes balance performance and sustainability but suffer from limited cyclability due to Mn dissolution and cathode-to-anode crosstalk. The Jahn-Teller (J-T) effect of Mn3+ is often linked to the above phenomena, such as in spinel LiMn2O4. However, in typical voltage ranges, significant Mn3+ only appears near the end of discharge, highlighting the need to reassess its role in driving Mn dissolution, structural degradation, and battery performance. Here, the spinel cathode's degree of disorder is tailored to expand the Mn redox range, enabling segmentation into J-T active and less active voltage ranges. Cycling at segmented voltage windows reveals surface degradation mechanisms with and without the major J-T effect. Despite a stronger J-T effect below 3.6 V vs. Li/Li+, Mn dissolution is less significant than above 3.6 V. Expanding the cycling window to 2.0-4.3 V causes severe degradation as the J-T active range induces a tetragonal phase and Mn2+-rich surface, driving Mn dissolution and consuming Li-ion inventory in full cells. Reducing electrolyte acidity minimizes Mn3+ disproportionation, enabling a stable dopant-free Mn-only cathode with a 250 mAh g-1 specific capacity. These findings demonstrate that full cells using Mn-rich cathodes have the potential to avoid the notorious crosstalk problem through electrolyte engineering.
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