共价键
亚胺
动态共价化学
共价有机骨架
化学
网络共价键合
纳米技术
材料科学
氧化还原
普鲁士蓝
组合化学
合理设计
聚合物
有机聚合物
电极
工作(物理)
电池(电)
设计要素和原则
作者
Yumin Chen,Da Zhang,Yang Qin,Chengmin Hu,Ling Miao,Yaokang Lv,Ziyang Song,LiHua GAN,Mingxian Liu
标识
DOI:10.1038/s41467-026-70370-x
摘要
Covalent organic frameworks containing periodic redox-active motifs and conjugation structures are booming as competitive negative electrodes for ammonium-ion batteries. Introducing substantial single-electron active motifs linked by dynamic imine bonds can increase their capacity; however, this design is constrained by suboptimal single-electron redox efficiency and insufficient linkage stability. Here we unlock a multiple two-electron-transfer nitrobenzothiadiazole covalent organic framework via integrating alkynyl benzenes and nitro-functionalized four-electron benzothiadiazoles. The high degree of π-electron sp-conjugation along alkynyl linkages and strong electron-drawing effect of nitrobenzothiadiazole motifs in nitrobenzothiadiazole covalent organic framework promise high NH4+ accessibility of multi-two-electron nitro/thiazole sites (95.2% utilization) with a lower activation energy (25.93 vs. 35.99 kJ mol-1 of benzothiadiazole covalent organic framework).The fast octadeca-H-bonded NH4+ coordination in nitrobenzothiadiazole units liberates a high specific capacity of 317 mAh g-1 for nitrobenzothiadiazole covalent organic framework negative electrode. The alkynyl-bridged π-conjugation network establishes structural anti-dissolution to enable a cycling durability of 70,000 cycles. Paired with high-voltage Prussian blue analogue positive electrode, the ammonium-ion full battery delivers a specific energy of 86.1 Wh kg-1 (based on total active material mass) and a lifespan of 25,000 cycles. This work extends the design landscape of high-performance covalent organic frameworks for advanced ammonium-ion batteries.
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