材料科学
氧化还原
催化作用
分子内力
密度泛函理论
共价键
电子转移
催化循环
共价有机骨架
化学工程
锂(药物)
化学物理
聚合
纳米技术
工作(物理)
储能
硫黄
相(物质)
功能群
能量转换效率
电催化剂
法拉第效率
能量转换
可逆反应
金属有机骨架
组合化学
过程(计算)
反应中间体
光化学
作者
Guo Feng,Jiayi Wang,Shibin Li,Yihang Nie,Chengjiao Zhao,Longjie He,Xuancheng Liu,Yiting Shao,Qingying Li,Kai Zong,Mingliang Jin,Jiawei He,Dan Luo,Xin Wang,Zhongwei Chen
摘要
ABSTRACT The catalytic conversion of lithium polysulfides (LiPSs) is crucial for realizing high‐energy‐density lithium–sulfur batteries. Herein, we propose a molecular cooperate engineering strategy to construct a hierarchical catalytic reaction chain for addressing the complex sulfur phase transitions and sluggish 16‐electron reaction kinetics. A covalent organic framework with a D‐A1‐A2 electronic structure was developed to generate a built‐in electric field (BIEF) via establishing intramolecular charge transfer (ICT) between bipolar functional groups. Theoretical calculations and in situ characterizations confirm that primary and auxiliary functional groups of COF can synergistically enable selective LiPSs capture while the BIEF‐facilitated electron transfer accelerates redox reactions of LiPSs, conferring reduced conversion energy barriers and mitigated shuttle effect. Moreover, the anchoring of the ─NO 2 group and hence the effect of the ─CF 3 group induce directional Li + deposition, ensuring the favored Li plating with epitaxial layered growth and suppressed dendrite formation. As a result, the Li symmetric cell demonstrates an ultra‐long lifespan (>16 000 h at 5 mAh cm −2 ) while Li–S batteries can achieve exceptional cycling stability (0.039% capacity decay per cycle over 1000 cycles). Meanwhile, the pouch cells deliver a high energy density of 395.6 Wh kg −1 with 90.2% capacity retention over cycling. This work presents a generalizable strategy for advancing multi‐electron redox systems.
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