Unraveling Lewis acid-base sites in defected MOFs for catalyzing dicyclopentadiene hydrogenation via a DFT study and descriptor exploration

IF 6.5 1区 化学 Q2 CHEMISTRY, PHYSICAL Journal of Catalysis Pub Date : 2024-09-11 DOI:10.1016/j.jcat.2024.115747
Linmeng Wang , Zhiyuan Liu , Hongyi Gao , Juan Chen , Jingjing Wang , Ping Yang , Wei Wang , Ge Wang
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Abstract

The 12-connected UiO-66 MOFs with great defect regulation ability have attracted significant attention due to the easily tunable electronic structure and surface electrostatic potential distribution of metal nodes. In this density functional theory (DFT) study, we systematically explored the effect of bi-active site types as the frustrated Lewis pair (FLP) and classical Lewis pair (LP) as well as metal elements of secondary building units (SBUs) on the catalytic hydrogenation of dicyclopentadiene (DCPD) to tetrahydrodicyclopentadiene (THDCPD). These design strategies effectively modulate the frontier molecular orbital energy level that determines the binding strength between MOFs and adsorbed species *Hδ+-Hδ- and charges transfer before and after H2 chemisorption. We also found that the heterolytic H2 adsorption energy and charges transfer linearly correlate with the energy barrier. In order to unravel the clear-cut designing strategies and further simplify computational complexity, we firstly proposed the ADCH charges difference between the Lewis acid and the Lewis base centers (ΔQM-O) as an intrinsic descriptor for catalytic activity of DCPD into THDCPD, which can effectively describe the reactivity and electrostatic effects of oppositely charged bi-active sites in the system. Furthermore, the defective UiO-66(Ce) MOF with moderate ΔQM-O effectively balance the contradiction between the barriers of two primitive reaction: the heterolytically H2 dissociation to *Hδ+-*Hδ- and the desorption of the active hydrogen species to hydrogenate 8,9-dihydrodicyclopentadiene (8,9-DHDCPD), resulting in the optimal catalytic performance. This work provides a deep understanding of the catalytic mechanism of MOFs with multiple active sites and might open up avenues for the rational design of novel hydrogenation catalysts.

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通过 DFT 研究和描述符探索揭示有缺陷 MOFs 中催化双环戊二烯氢化的路易斯酸碱位点
12 连接的 UiO-66 MOFs 具有很强的缺陷调节能力,由于其电子结构和金属节点的表面静电势分布易于调节,因此备受关注。在这项密度泛函理论(DFT)研究中,我们系统地探讨了受挫路易斯对(FLP)和经典路易斯对(LP)等双活性位点类型以及二级构建单元(SBU)的金属元素对双环戊二烯(DCPD)催化氢化成四氢双环戊二烯(THDCPD)的影响。这些设计策略有效地调节了前沿分子轨道能级,该能级决定了 MOFs 与吸附物种 *Hδ+-Hδ- 之间的结合强度以及 H2 化学吸附前后的电荷转移。我们还发现,H2 的异溶吸附能和电荷转移与能垒呈线性相关。为了揭示清晰的设计策略并进一步简化计算复杂性,我们首先提出了路易斯酸中心和路易斯碱中心之间的 ADCH 电荷差(ΔQM-O)作为 DCPD 转化为 THDCPD 催化活性的内在描述因子,它可以有效地描述体系中带电的双活性位点的反应性和静电效应。此外,缺陷 UiO-66(Ce)MOF具有适度的ΔQM-O,能有效平衡两个原始反应障碍之间的矛盾:H2异解为*Hδ+-*Hδ-和活性氢种解吸加氢8,9-二氢双环戊二烯(8,9-DHDCPD),从而获得最佳催化性能。这项研究深入了解了具有多个活性位点的 MOFs 的催化机理,为合理设计新型加氢催化剂开辟了道路。
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来源期刊
Journal of Catalysis
Journal of Catalysis 工程技术-工程:化工
CiteScore
12.30
自引率
5.50%
发文量
447
审稿时长
31 days
期刊介绍: The Journal of Catalysis publishes scholarly articles on both heterogeneous and homogeneous catalysis, covering a wide range of chemical transformations. These include various types of catalysis, such as those mediated by photons, plasmons, and electrons. The focus of the studies is to understand the relationship between catalytic function and the underlying chemical properties of surfaces and metal complexes. The articles in the journal offer innovative concepts and explore the synthesis and kinetics of inorganic solids and homogeneous complexes. Furthermore, they discuss spectroscopic techniques for characterizing catalysts, investigate the interaction of probes and reacting species with catalysts, and employ theoretical methods. The research presented in the journal should have direct relevance to the field of catalytic processes, addressing either fundamental aspects or applications of catalysis.
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