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Ligand-Induced High-Deficient 2D {Zn<sub>2</sub>}-Organic Material: High Catalytic Activity on CO<sub>2</sub>-Epoxide Cycloaddition and DFT Calculation

Yang Fei, Liming Fan, Tuoping Hu, Xiutang Zhang

2025ACS Sustainable Chemistry & Engineering24 citationsDOI

Abstract

Due to diffusion barriers, the catalytic applications of porous metal–organic materials in organic synthesis are currently limited to relatively small substrates. Therefore, a synthesis strategy consisting of dimensionality reduction, active site addition, and defect engineering was adopted to develop two-dimensional (2D) metal–organic materials by using the designed organic linker 4,4′-(4-(4-(trifluoromethoxy)phenyl)pyridine-2,6-diyl)diisophthalic acid (H 4 TPPD), based on which a highly robust 2D [Zn 2 (COO) 6 (DMF) 4 ]-based framework of {[(CH 3 ) 2 NH 2 ][Zn(HTPPD)(DMF) 2 ]·2H 2 O} n ( NUC-141 ) was self-assembled. The thermally activated NUC-141a has the following distinctive merits: (i) higher-order in-plane nanoscale pores of ca. 15.1 × 10.2 × 8.9 Å 3; (ii) functionalized by four kinds of acid–base active sites, including highly defected Zn 2+ sites, trifluoromethoxy, free carboxyl, and pyridyl. Due to its multiple high-density catalytic sites, NUC-141a exhibits a higher catalytic performance in the coupling reactions of CO 2 and various epoxides than most reported 2D and three-dimensional (3D) metal–organic framework (MOF)-based materials. Meanwhile, NUC-141a exhibits high turnover number (TON) values, selectivity, and chemical stability in coupling reactions. Density functional theory (DFT) calculations using double-defected ZnO 6 as a catalytic unit confirmed that the energy barriers for overcoming ring-opening, CO 2 insertion, and ring-closing steps were 5.4, 15.3, and 29.2 kcal/mol, respectively, all of which were significantly lower than those of monodefected ZnO 7, saturated ZnO 8, and most reported MOF catalysts. In addition, NUC-141a exhibits high separation performance for CO 2 /CH 4 mixtures at 273 K and 100 kPa, with separation selectivity of 49 (1:99, v/v), 38 (10:90, v/v), and 23 (50:50, v/v). Therefore, this work not only demonstrated through a series of DFT calculations that more highly defected metal sites in MOFs have higher catalytic performance but also provided an effective synthesis strategy for preparing 2D functional MOFs.

Topics & Concepts

EpoxideCycloadditionCatalysisLigand (biochemistry)ChemistryMaterials scienceChemical engineeringOrganic chemistryCombinatorial chemistryEngineeringReceptorBiochemistryMetal-Organic Frameworks: Synthesis and ApplicationsCarbon dioxide utilization in catalysisCovalent Organic Framework Applications