分子内力
配体(生物化学)
吸附
化学
灵活性(工程)
刚度(电磁)
延伸率
设计要素和原则
多孔性
结晶学
材料科学
缩放比例
立体化学
化学物理
六方晶系
化学工程
计算化学
标度律
组合化学
结构刚度
材料设计
纳米技术
合理设计
聚合物
位阻效应
分解
模块化(生物学)
作者
Wei Wang,Khai X. Phan,Ziyang Jia,Xianhui Bu,Pingyun Feng
标识
DOI:10.1002/anie.202521262
摘要
Aliphatic ligands are often sidelined in the design of framework materials because their conformational flexibility can contribute to problems such as difficult crystallization, low porosity, and stability. Attempts to boost porosity by ligand elongation usually worsen these problems. Here we propose an expanded bioisosteric replacement (eBIS) concept capable of both scaling up and rigidifying aliphatic ligands. We demonstrate one example realized via linking two cyclohexyl rings in series, which restricts ligand flexibility through intramolecular non-covalent interactions providing an alternative to the π-conjugation-based rigidity. The resulting ligand displays consistent rigidity across multiple MOF platforms. On the pacs platform, it can realize extreme pore geometry with the highest hexagonal c/a ratio and new metal-cluster chemistry such as the first synthesis of nickel-titanium oxocluster. It can boost the BET surface area to as high as 2810 m2 g-1, likely the highest among aliphatic-dicarboxylate MOFs. Furthermore, it leads to possibly largest C2H6/C2H4 uptake differences (88 cm3 g-1, uptake ratio of 1.83, 273 K) among rigid MOFs, a desired property for C2H6-selective separation, which is confirmed by breakthrough experiments. The remarkably low adsorption enthalpies for C2H6 (14.7 kJ mol-1) and C2H4 (15.1 kJ mol-1) enables low-energy adsorbent regeneration benefitting practical separation.
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