化学
密度泛函理论
机制(生物学)
节点(物理)
乙炔
氢键
氢
配体(生物化学)
分子开关
金属有机骨架
胺气处理
控制(管理)
拓扑(电路)
高压
纳米技术
化学物理
更安全的
传输(电信)
合理设计
分子动力学
分子
光电子学
反应机理
作者
Jacopo Perego,Charl X. Bezuidenhout,Silvia Bracco,Bai-Qiao Song,Mohana Shivanna,Soumya Mukherjee,Michael J. Zaworotko,Angiolina Comotti
摘要
Flexible metal−organic frameworks (MOFs) promise access to superior control and enhanced performance for gas separation, storage, and release. For the development of smart materials with “on-demand” responsiveness, the ad hoc design of switching mechanisms is crucial to drive multiple structural transformations. In this study, doubly interpenetrated pillared Zinc(II)-MOFs were customized to fine-tune CO2 and C2H2 sorption/desorption pressures by modulating their dynamic responses. The incorporation of a specifically designed asymmetric bipyridyl-acrylonitrile pillar, together with benzenedicarboxylate and/or amino-benzenedicarboxylate ligands, leverages reversible metal-coordination isomerism to control gas-stimuli responsiveness. The sophisticated mechanism and temporal response involve framework expansion, node rearrangement, and ligand displacement. Furthermore, evolution of the global dynamics of the framework under cyclical CO2 stimuli was revealed, demonstrating a progression from switching behavior to a permanently open structure. The pore-opening threshold pressure for CO2 and acetylene (C2H2)─from discrete pockets to one-dimensional and two-dimensional interconnected channels─was rationally governed by increasing the amine group content, which modulates the density of hydrogen bonds between the two interpenetrated frameworks. This intricate mechanism was elucidated through in situ PXRD under CO2 atmosphere, calorimetry-coupled gas adsorption, and density functional theory calculations. Notably, C2H2-induced gate opening expands the feasibility of C2H2-responsive systems, offering safer and more efficient sorbents.
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