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具有空间和电子适应性的吡啶基二亚胺氮二配位体钯配合物:顺/反式半配位的协同和在脱氢催化中的应用。

Sterically and Electronically Flexible Pyridylidene Amine Dinitrogen Ligands at Palladium: Hemilabile cis/trans Coordination and Application in Dehydrogenation Catalysis.

机构信息

Department of Chemistry, Biochemistry and Pharmaceutical Sciences, University of Bern, Freiestrasse 3, CH-3012, Bern, Switzerland.

出版信息

Chemistry. 2022 Dec 6;28(68):e202202672. doi: 10.1002/chem.202202672. Epub 2022 Oct 11.

DOI:10.1002/chem.202202672
PMID:36066486
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10092520/
Abstract

Ligand design is crucial for the development of new catalysts and materials with new properties. Herein, the synthesis and unique hemilabile coordination properties of new bis-pyridylidene amine (bis-PYE) ligands to palladium, and preliminary catalytic activity of these complexes in formic acid dehydrogenation are described. The synthetic pathway to form cationic complexes [Pd(bis-PYE)Cl(L)]X with a cis-coordinated N,N-bidentate bis-PYE ligand is flexible and provides access to a diversity of Pd complexes with different ancillary ligands (L=pyridine, DMAP, PPh , Cl, P(OMe) ). The H NMR chemical shift of the trans-positioned PYE N-CH unit is identified as a convenient and diagnostic handle to probe the donor properties of these ancillary ligands and demonstrates the electronic flexibility of the PYE ligand sites. In the presence of a base, the originally cis-coordinated bis-PYE ligand adopts a N,N,N-tridentate coordination mode with the two PYE units in mutual trans position. This cis-trans isomerization is reverted in presence of an acid, demonstrating a unique structural and steric flexibility of the bis-PYE ligand at palladium in addition to its electronic adaptability. The palladium complexes are active in formic acid dehydrogenation to H and CO . The catalytic performance is directly dependent on the ligand bonding mode, the nature of the ancillary ligand, the counteranion, and additives. The most active system features a bidentate bis-PYE ligand, PPh as ancillary ligand and accomplishes turnover frequencies up to 525 h in the first hour and turnover numbers of nearly 1000, which is the highest activity reported for palladium-based catalysts to date.

摘要

配体设计对于开发具有新性质的新型催化剂和材料至关重要。在此,描述了新型双吡啶亚胺(bis-PYE)配体与钯的合成及其独特的半配位特性,以及这些配合物在甲酸脱氢反应中的初步催化活性。形成顺式配位 N,N-双齿 bis-PYE 配体的阳离子配合物[Pd(bis-PYE)Cl(L)]X 的合成途径具有灵活性,可获得具有不同辅助配体(L=吡啶、DMAP、PPh 3 、Cl、P(OMe) 3 )的多种 Pd 配合物。反位 PYE N-CH 单元的 H NMR 化学位移被确定为一种方便且具有诊断性的方法,可以探测这些辅助配体的供电子性能,并证明了 PYE 配体位点的电子灵活性。在碱的存在下,原本顺式配位的 bis-PYE 配体采用 N,N,N-三齿配位模式,两个 PYE 单元处于相互反位。在酸的存在下,这种顺反异构化被反转,除了其电子适应性外,还证明了钯中 bis-PYE 配体的独特结构和空间灵活性。钯配合物在甲酸脱氢反应中具有活性,可生成 H 和 CO。催化性能直接取决于配体键合模式、辅助配体的性质、抗衡阴离子和添加剂。最活跃的体系具有双齿 bis-PYE 配体和 PPh 3 作为辅助配体,在第一个小时内达到高达 525 h-1 的周转频率和近 1000 的周转数,这是迄今为止报道的钯基催化剂中最高的活性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d6aa/10092520/b1bcec92dee6/CHEM-28-0-g001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d6aa/10092520/2ffc8e1cfeac/CHEM-28-0-g007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d6aa/10092520/aed06c9f501e/CHEM-28-0-g012.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d6aa/10092520/9954fe0d12ba/CHEM-28-0-g002.jpg
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