路易斯酸
化学
溶剂化
锂(药物)
基础(拓扑)
密度泛函理论
吸附
隐溶剂化
组合化学
催化作用
计算化学
分子
物理化学
有机化学
数学分析
内分泌学
医学
数学
作者
Chuan Zhao,Zhongfu Yan,Bo Zhou,Yu Pan,Anjun Hu,Miao He,Jing Liu,Jianping Long
标识
DOI:10.1002/anie.202302746
摘要
Abstract Lewis‐base sites have been widely applied to regulate the properties of Lewis‐acid sites in electrocatalysts for achieving a drastic technological leap of lithium‐oxygen batteries (LOBs). Whereas, the direct role and underlying mechanism of Lewis‐base in the chemistry for LOBs are still rarely elucidated. Herein, we comprehensively shed light on the pivotal mechanism of Lewis‐base sites in promoting the electrocatalytic reaction processes of LOBs by constructing the metal–organic framework containing Lewis‐base sites (named as UIO‐66‐NH 2 ). The density functional theory (DFT) calculations demonstrate the Lewis‐base sites can act as electron donors that boost the activation of O 2 /Li 2 O 2 during the discharged‐charged process, resulting in the accelerated reaction kinetics of LOBs. More importantly, the in situ Fourier transform infrared spectra and DFT calculations firstly demonstrate the Lewis‐base sites can convert Li 2 O 2 growth mechanism from surface‐adsorption growth to solvation‐mediated growth due to the capture of Li + by Lewis‐base sites upon discharged process, which weakens the adsorption energy of UIO‐66‐NH 2 towards LiO 2 . As a proof of concept, LOB based on UIO‐66‐NH 2 can achieve a high discharge specific capacity (12 661 mAh g −1 ), low discharged‐charged overpotential (0.87 V) and long cycling life (169 cycles). This work reveals the direct role of Lewis‐base sites, which can guide the design of electrocatalysts featuring Lewis‐acid/base dual centers for LOBs.
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