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Metal alkyls programmed to generate metal alkylidenes by α-H abstraction: prognosis from NMR chemical shift.通过α-氢抽象作用生成金属亚烷基的金属烷基化合物:基于核磁共振化学位移的预测
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What can NMR spectroscopy of selenoureas and phosphinidenes teach us about the π-accepting abilities of -heterocyclic carbenes?硒脲和磷烯的核磁共振光谱能让我们了解到关于杂环卡宾的π-接受能力的哪些信息?
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NMR 化学位移分析解码 d 族 4 金属配合物的烯烃低聚和聚合活性。

NMR chemical shift analysis decodes olefin oligo- and polymerization activity of d group 4 metal complexes.

机构信息

Department of Chemistry and Applied Biosciences, ETH Zürich, 8093 Zürich, Switzerland.

Department of Chemistry, Graduate School of Engineering Science, Osaka University, Toyonaka, 560-8531 Osaka, Japan.

出版信息

Proc Natl Acad Sci U S A. 2018 Jun 26;115(26):E5867-E5876. doi: 10.1073/pnas.1803382115. Epub 2018 Jun 11.

DOI:10.1073/pnas.1803382115
PMID:29891699
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6042142/
Abstract

d metal-alkyl complexes (M = Ti, Zr, and Hf) show specific activity and selectivity in olefin polymerization and oligomerization depending on their ligand set and charge. Here, we show by a combined experimental and computational study that the C NMR chemical shift tensors of the α-carbon of metal alkyls that undergo olefin insertion signal the presence of partial alkylidene character in the metal-carbon bond, which facilitates this reaction. The alkylidene character is traced back to the π-donating interaction of a filled orbital on the alkyl group with an empty low-lying metal d-orbital of appropriate symmetry. This molecular orbital picture establishes a connection between olefin insertion into a metal-alkyl bond and olefin metathesis and a close link between the Cossee-Arlmann and Green-Rooney polymerization mechanisms. The C NMR chemical shifts, the α-H agostic interaction, and the low activation barrier of ethylene insertion are, therefore, the results of the same orbital interactions, thus establishing chemical shift tensors as a descriptor for olefin insertion.

摘要

d 金属-烷基配合物(M = Ti、Zr 和 Hf)在烯烃聚合和齐聚反应中表现出特定的活性和选择性,这取决于它们的配体和电荷。在这里,我们通过实验和计算的综合研究表明,经历烯烃插入反应的金属烷基的 α-碳的 13C NMR 化学位移张量信号表明金属-碳键中存在部分亚烷基特征,这有利于该反应。这种亚烷基特征可以追溯到烷基上填充轨道与具有适当对称性的低占据金属 d 轨道之间的π供体相互作用。这种分子轨道图将金属-烷基键中的烯烃插入与烯烃复分解反应联系起来,并将 Cossee-Arlmann 和 Green-Rooney 聚合机制紧密联系起来。因此,13C NMR 化学位移、α-H 桥接相互作用和乙烯插入的低活化能垒是相同轨道相互作用的结果,从而确立了化学位移张量作为烯烃插入的描述符。