材料科学
三聚体
金属有机骨架
配体(生物化学)
分拆(数论)
苯
化学物理
多孔性
限制
合理设计
纳米技术
复合材料
有机化学
二聚体
机械工程
吸附
受体
工程类
化学
组合数学
生物化学
数学
作者
Yingying Zhang,Zhi Fang,Yuqing Qi,Lei Gan,Hongliang Huang,Huajun Yang
标识
DOI:10.1002/adma.202511669
摘要
The pore-space-partition (PSP) strategy, which subdivides large pores into smaller segments, has proven highly effective in flexible acs-type frameworks. However, extending this approach to rigid structures has remained a formidable challenge due to the strict size and symmetry constraints required for partitioning ligands. In this study, we successfully overcome these limitations and, for the first time, apply the PSP strategy to rigid acs frameworks. This breakthrough relies on the precise geometric and size compatibility between the parent framework and specially designed partitioning ligands. A series of metal-organic frameworks (MOFs) based on four ligand pairs and four metal combinations are synthesized. Notably, MOFs incorporating partitioning ligands with a hexaazaphenalene core exhibited exceptional benzene adsorption properties. Among these, the neutral NNM-750-Fe, featuring ideal charge balance between the metal trimer (+1) and the partitioning ligand (-1), demonstrated significantly enhanced benzene uptake at low pressure compared to non-partitioned and charged-partitioned analogues. This work not only expands the boundaries of the PSP strategy to rigid frameworks but also opens new avenues for the rational design of high-performance porous materials for advanced separation and adsorption applications.
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