阳极
化学工程
电解质
材料科学
溶剂化
聚合物
共价键
锂(药物)
溶剂
离子
分子
枝晶(数学)
离子键合
离子电导率
扩散
离子运输机
共价有机骨架
高分子化学
锂离子电池
无机化学
图层(电子)
化学物理
化学
扩散阻挡层
阴极
复合数
电池(电)
聚丙烯
动力学
有机电子学
作者
Hao Wu,Xinying Wang,WenGuang Wang,Chunye Liao,Jiayi Wu,Zhuhang Shao,Yiru Zhou,Yunyong Li
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-12-22
卷期号:20 (1): 657-671
被引量:3
标识
DOI:10.1021/acsnano.5c14722
摘要
The high Li + desolvation energy barrier causes sluggish kinetics and uncontrolled dendrite growth, leading to severe solid electrolyte interface (SEI) instability and hindered ion transport across lithium–metal anodes (LMAs), which remains a major barrier to commercialization. Herein, a Lewis-based N/O dual-functional covalent organic polymer (COP-DQCC) with abundant carbonyl components was designed and integrated into a commercial polypropylene (PP) separator. Experimental and theoretical calculations show that the high lithiophilicity of Lewis base N/O atoms enhances lithium salt dissociation, promotes Li + desolvation from the solvation shell, reduces solvent molecule transport, simplifies the solvated structure of Li +, lowers ion diffusion activation energy, and accelerates Li + migration. Additionally, the suitable pore size of the triazine composite carbonyl organic unit regulates the electroplating/stripping behavior of LMA. In situ optical microscopy reveals that the COP-DQCC layer effectively inhibited dendrite growth. Time-of-flight secondary ion mass spectrometry further confirms that the COP-DQCC layer promotes the formation of a stable LiF-rich SEI layer, regulates Li + transport and uniform deposition. Ultimately, the Li/COP-DQCC@PP/Li symmetric cell demonstrated stable cycling for over 2400 h at 1.0 mA cm –2 /1.0 mAh cm –2, maintaining a low overpotential, and continued stable cycling for over 900 h at 4.0 mA cm –2 /4.0 mAh cm –2 . Additionally, the LiFePO 4 /COP-DQCC@PP/Li cell shows remarkable cycling stability, retaining 84.6% of its capacity after 1200 cycles at 1.0 C, and excellent cycling performance at higher loading of LiFePO 4 . This work highlights the development of a durable, dendrite-free anode, offering significant potential for advancing high-energy-density LMAs.
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