氧化态
配体(生物化学)
材料科学
导电体
镧系元素
拓扑(电路)
多孔性
金属
配位复合体
金属有机骨架
多孔介质
协调数
化学物理
电荷(物理)
化学
纳米技术
光谱学
合理设计
国家(计算机科学)
电子结构
配位几何学
结晶学
作者
Yunlong Fan,Bin Jiang,Zhenghan Zhang,Haoyang Zhang,Luming Yang,Tianyang Chen,He Liu,Yanjun Liu,Jinkun Guo,Tong-Yang Zhao,Ran Du,Cen Tang,Jian Li,Maojun Zheng,Jin‐Hu Dou
标识
DOI:10.1002/anie.202522424
摘要
Abstract Conductive metal–organic frameworks (c‐MOFs), composed of metal nodes and redox‐active ligands, have attracted growing interest due to the coexistence of porosity and charge transport. Notably, their electrical performance is closely related to the packing and ligand oxidation state within the framework, which has rarely been explored. Typical divalent metal nodes favor saturated intralayer square‐planar coordination to ligands in a single oxidation state, thereby predetermining the framework topology. Here, we report a packing and topology control strategy, achieved by tuning the ligand oxidation state and grounded in lanthanides (e.g., Gd) versatile coordination chemistry. Diffuse reflectance spectroscopy and single‐crystal transport measurements reveal that, at low temperature, coordination of Gd 3+ with 2,3,6,7,10,11‐hexahydroxytriphenylene (HHTP) in a lower mixed oxidation state (−4 and −5) yields a more ordered porous packing (Gd 1.5 HHTP) with superior electronic transport performance. In contrast, at elevated temperature, the ligand adopts a higher oxidation state (−3), and coordination with Gd 3+ yields a densely packed structure with local coordination disorder (GdHHTP), resulting in a markedly reduced electrical conductivity. This study demonstrates ligand‐oxidation‐state tuning provides an effective strategy for the precise control of structural order and charge transport in c‐MOFs, laying a theoretical foundation for the rational design of materials with tunable electronic properties.
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