相间
金属锂
电解质
阴极
材料科学
枝晶(数学)
溶剂化
锂(药物)
化学工程
多收费
无机化学
金属
聚合物电解质
聚合物
电极
电池(电)
相(物质)
锂电池
半电池
化学
电化学
原位
作者
Chao Fu,Huafeng Cao,Hankun Zhang,Yueping Wang,Zhenhuan Zhang,Jie Yang,Jianxiu Wang,Jinqiang Gao,Kefei Wang,Benhua Wang,Gui-Chao Kuang,Xiangzhi Song,Libao Chen
摘要
ABSTRACT Polyurea (PUR) electrolytes offer molecular tunability, robust mechanics, and strong Li‐salt affinity for lithium metal batteries, but their application is hindered by poor solubility, uncontrolled polymerization, and unstable Li/electrolyte interfaces. Herein, we report two polyurea‐based polymerizable monomers with distinct functionalities, DPN and MPN , and construct flame‐retardant polyurea gel polymer electrolytes ( P‐DPN and P‐MPN ) through an in situ polymerization strategy. This design simultaneously addresses solubility, electrolyte leakage, and interfacial instability. Mechanistic investigations reveal that the carbonyl groups in the urea moieties coordinate with lithium ion (Li + ) to homogenize lithium deposition, while the –NH groups interact with anions to induce weakly solvated Li + structures, thereby accelerating ion transport. Meanwhile, the low HOMO energy level of the polyurea framework promotes the formation of a robust LiF/Li 3 N‐rich inorganic solid electrolyte interphase (SEI), effectively suppressing parasitic reactions and dendrite growth. As a result, the Li|| P‐MPN ||Li symmetric cell exhibits stable cycling for over 2300 h, and full cells paired with diverse cathodes (including NCM811, LCO, and LFP) exhibit outstanding cycling stability under high cathode loading and even at −20°C. This work establishes a molecular design strategy for in situ polyurea electrolytes and deepens the understanding of solvation/interphase regulation in high‐performance and safe lithium metal batteries.
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