Litcius/Paper detail

Dynamic Pore Space Partition in Zinc Metal–Organic Frameworks

Wei Wang, Yichong Chen, Khai X. Phan, Ziyang Jia, Yuchen Xiao, Xianhui Bu, Pingyun Feng

2025Journal of the American Chemical Society10 citationsDOI

Abstract

Increasing the framework connectivity is a useful strategy to tune pore geometry and properties such as gas separation selectivity. Although highly connected frameworks are common for iconic clusters such as M 3 (O/OH) trimers and Zr 6 (O/OH) 8 hexamers, they are rarely seen for Zn 4 O tetramers, one of the most famed MOF building blocks that predates both M 3 and Zr 6 in the MOF field. Here, we demonstrate that pore space partition (PSP) can unlock the potential of Zn 4 O for higher connectivity (>6). We show that on the pore-space-partitioned acs (pacs) platform, zinc-cluster chemistry is diverse and dynamic, yet it can be mapped out semiquantitatively. A large family of Zn x –pacs materials ( x = 2, 3, 4) with 3 different pore-partition mechanisms has been synthesized by applying PSP to the MOF-5-type system. We propose that the difference in the steric effect around 9-connected Zn 3 (OH) and Zn 4 O, exacerbated when the hexagonal c/a ratio is compressed, plays a key role in the discovery of a new pacs family based on 9-connected Zn 4 O. This work significantly broadens the scope of PSP because it no longer requires preoriented open-metal sites. New pacs materials show much better aqueous stability and greatly enhanced C 2 H 2 /C 2 H 4 separation performance than the corresponding nonpartitioned MOF-5-type materials.

Topics & Concepts

ChemistryZincMetal-organic frameworkPartition (number theory)Space (punctuation)MetalOrganic chemistryAdsorptionLinguisticsCombinatoricsMathematicsPhilosophyMetal-Organic Frameworks: Synthesis and ApplicationsMachine Learning and ELMEnhanced Oil Recovery Techniques