共价键
材料科学
质子
表面改性
无水的
电导率
亚胺
共价有机骨架
化学物理
动态共价化学
质子输运
纳米笼
熔点
多孔性
化学工程
高分子
网络共价键合
热导率
多孔介质
结晶学
纳米技术
氢键
热传导
溶剂
工作(物理)
胺气处理
从头算
晶体结构
作者
Aiping Yao,Changyan Zhu,Jun Liu,Hongliang Xu,Kuizhan Shao,Chunyi Sun,Chao Qin,Xinlong Wang,Hongying Zang,Zhongmin Su,Donglin Jiang
标识
DOI:10.1038/s41467-025-67873-4
摘要
Proton conduction pathways and mechanisms in covalent organic frameworks (COFs) have long been obscured by polycrystalline disorder. Here we report a solvent-free melt-phase post-synthetic modification (PSM) strategy that enables precise functionalization of three-dimensional single-crystalline COFs while preserving crystallinity. This methodology overcomes the limitations of solvent-mediated PSM by operating above the melting point of azole reagents, ensuring homogeneous pore accessibility without solvent occlusion. Applied to archetypal imine-linked COF-300, the method achieves crystallographically resolved conversion of fragile imine bonds (C = N, 1.245 Å) into robust amine linkages (C-N, 1.415 Å), concurrently covalently anchoring of proton-conductive azoles (C-N, 1.487 Å) on the COFs skeleton. The resulting azole-functionalized COFs (COF-300-1,2,3-triazole, COF-300-1,2,4-triazole, COF-300-pyrazole) exhibit intrinsic anhydrous superprotonic conductivity reaching 4.35 × 10-3 S cm-1 at 170 °C, with low activation energies (0.153-0.186 eV). Atomic-resolution crystallography and DFT calculations reveal that rigid hydrogen-bond networks eliminate thermal barriers for proton hopping, establishing a definitive structure-property correlation for proton transport in single-crystal COFs. This work pioneers a versatile platform for functionalizing 3D crystalline porous materials under solvent-free conditions.
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