多硫化物
硫黄
杂原子
氧化还原
材料科学
碳纤维
氮气
溶解
化学工程
储能
动力学
电池(电)
无机化学
化学
电解质
电极
物理化学
有机化学
热力学
复合数
功率(物理)
复合材料
冶金
工程类
物理
量子力学
戒指(化学)
作者
Huifang Xu,Qingbin Jiang,Kang Gao,Kwan San Hui,Shuo Wang,Yan Wang,Cheng‐Zong Yuan,Chenyang Zha,Duc Anh Dinh,Kwun Nam Hui
标识
DOI:10.1002/aenm.202502553
摘要
Abstract Potassium‐sulfur (K‐S) batteries are considered a promising candidate for next‐generation energy storage due to the earth‐abundance of potassium and sulfur and their high theoretical capacities. However, their development is hindered by sluggish redox kinetics, limited mechanistic understanding of solid‐state conversion processes, and the polysulfide shuttle effect. Here, the detailed mechanism of the solid‐solid conversion stage in K‐S batteries is investigated. Conventional carbon‐based sulfur hosts follow a two‐step pathway (K 2 S 3 →K 2 S 2 →K 2 S) with a high intrinsic activation barrier, which fundamentally restricts reaction kinetics. Through first‐principles calculations, it is shown that nitrogen‐doped carbon‐particularly with pyridinic and pyrrolic nitrogen‐enables a direct one‐step conversion from K 2 S 3 to K 2 S, substantially lowering the energy barrier and enhancing K 2 S redox kinetics. Guided by this insight, a nitrogen‐doped carbon/graphene (NCG) matrix is designed with a high nitrogen content (15 wt.%) as a sulfur host. The NCG framework combines high conductivity with strong chemical affinity between nitrogen sites and sulfur species, accelerating redox reactions while suppressing polysulfide dissolution. The S/NCG‐1 cell shows a low‐capacity decay of 0.135% over 500 cycles, highlighting improved sulfur utilization and long‐term stability. This work establishes mechanistic design principles for heteroatom‐doped carbon cathodes and advances the rational development of high‐performance K‐S battery systems.
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