Markus Leutzsch, Larry M Wolf, Puneet Gupta, Michael Fuchs, Walter Thiel, Christophe Farès, Alois Fürstner
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引用次数: 0
摘要
通过对位氢(p-H2)诱导极化(PHIP)转移核磁共振光谱,我们深入了解了{Cp*Ru}配合物催化内部炔烃不寻常的反式氢化机制。研究发现,高产的反式还原与一种途径竞争,在这种途径中,H2 的两个 H 原子都被输送到底物的单个炔烃 C 原子上,而第二个炔烃 C 原子则被转化为金属碳烯。这种 "宝石氢化 "模式似乎是史无前例的;通过分离和结构表征由配体间二级相互作用稳定的碳化钌配合物,我们独立地证实了这一点。详细的 DFT 研究表明,反式烯和碳络合物源自一个共同的金属环丙烯中间体。此外,计算分析和 PHIP NMR 数据一致表明,金属碳烯是烯烃异构化和过度还原的主要通道,而烯烃异构化和过度还原经常干扰常规的炔烃反式加氢反应。
Formation of Ruthenium Carbenes by gem-Hydrogen Transfer to Internal Alkynes: Implications for Alkyne trans-Hydrogenation.
Insights into the mechanism of the unusual trans-hydrogenation of internal alkynes catalyzed by {Cp*Ru} complexes were gained by para-hydrogen (p-H2) induced polarization (PHIP) transfer NMR spectroscopy. It was found that the productive trans-reduction competes with a pathway in which both H atoms of H2 are delivered to a single alkyne C atom of the substrate while the second alkyne C atom is converted into a metal carbene. This "geminal hydrogenation" mode seems unprecedented; it was independently confirmed by the isolation and structural characterization of a ruthenium carbene complex stabilized by secondary inter-ligand interactions. A detailed DFT study shows that the trans alkene and the carbene complex originate from a common metallacyclopropene intermediate. Furthermore, the computational analysis and the PHIP NMR data concur in that the metal carbene is the major gateway to olefin isomerization and over-reduction, which frequently interfere with regular alkyne trans-hydrogenation.
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