多硫化物
化学工程
电催化剂
硫黄
化学
硫化
阴极
纳米颗粒
材料科学
硫化物
阳极
硫化锌
储能
纳米技术
无机化学
电化学
电极
有机化学
锌
物理化学
功率(物理)
物理
量子力学
工程类
电解质
作者
Jun Li,Jinlong Liu,Fangxi Xie,Ran Bi,Lei Zhang
标识
DOI:10.1002/anie.202406126
摘要
Aqueous zinc batteries based on the conversion‐type sulfur cathodes are promising in energy storage system due to the high theoretical energy density, low cost, and good safety. However, the multi‐electron solid‐state intermediate conversion reaction of sulfur cathodes generally possess sluggish kinetics, which leads to lower discharge voltage and inefficient sulfur utilization, thus suppressing the practical energy density. Herein, sulfur nanoparticles derived from metal−organic frameworks confined in‐situ within electrospun fibers derived sulfur and nitrogen co‐doped carbon nanofibers (S@S,N‐CNF) composite, which possesses yolk−shell S@C nanostructure, is fabricated through successive sulfidation, pyrolysis, and sulfide oxidation processes, and served as a high‐performance cathode material for Zn−S battery. The S and N dopants on carbon can collectively catalyse sulfur reduction reaction (SRR) by lowering energy barrier and accelerating kinetics to increase discharge voltage and specific capacity. Meanwhile, the yolk−shell S@C structure with spatially confined S nanoparticle yolks is beneficial to improve charge transfer and lower activation energy, thus further expediting SRR kinetics. Furthermore, extensive density functional theory (DFT) calculations reveal that S and N dual‐doping can thermodynamically and dynamically reduce the energy barrier of rate‐determining step (i.e., the transformation of *ZnS4 into *ZnS2) for the overall SRR, thereby significantly accelerating SRR kinetics.
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