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从亚胺到胺:意外的转折。用于苯乙酮不对称转移氢化的-β铁(II)PNNP'预催化剂。

From imine to amine: an unexpected left turn. -β iron(ii) PNNP' precatalysts for the asymmetric transfer hydrogenation of acetophenone.

作者信息

Demmans Karl Z, Seo Chris S G, Lough Alan J, Morris Robert H

机构信息

Department of Chemistry , University of Toronto , 80 Saint George Street , Toronto , Ontario M5S 3H6 , Canada . Email:

出版信息

Chem Sci. 2017 Sep 1;8(9):6531-6541. doi: 10.1039/c7sc02558k. Epub 2017 Jul 14.

DOI:10.1039/c7sc02558k
PMID:28989679
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5627452/
Abstract

A novel PNN ligand bearing an orthophenylene group and a primary amine was synthesized with the aid of a palladium-catalyzed amination and reacted with phosphonium dimers [-PRCHCH(OH)-][Br] R = Et, iPr, Cy, Ph, xylyl, and -Tol, and [Fe(OH)] to produce a new series of -β iron(ii) PNNP' precatalysts -β-[Fe(Br)(CO)(PNNP')]BPh as a pair of diastereomers. The more stable orthophenylene amido group was chosen to imitate and replace the enamido moiety of a highly active iron precatalyst for the asymmetric transfer hydrogenation (ATH) of ketones in an attempt to prevent its deactivation caused by reduction of the enamido group. This objective was partially achieved using the complex with a PEt group which catalyzed the transfer hydrogenation in isopropanol of 150 000 equivalents of acetophenone to racemic 1-phenylethanol. With a low acetophenone to catalyst ratio of 500 to 1, the catalytic activity was moderate and the enantiomeric excess (ee) of the product 1-phenylethanol ranged surprisingly from 94% () to 95% () depending on the nature of PR and whether the precatalyst contained an imine or amine donor. The amine precatalyst with a PEt-group produced a more stable hydride species when activated, allowing the reaction mixture to be heated to 75 °C to obtain a TON of 8821 for acetophenone while retaining the high ee of 95% (). The activation pathway in basic isopropanol (iPrOH) was studied for three precatalysts to elucidate that the -β precatalysts rearrange to form hydride complexes. The study suggests that the enantioselectivity of these complexes is determined by from which side of the PNNP' plane the hydride transfer occurs.

摘要

借助钯催化胺化反应合成了一种带有邻亚苯基和伯胺的新型PNN配体,并使其与鏻二聚体[-PRCHCH(OH)-][Br](R = 乙基、异丙基、环己基、苯基、二甲苯基和对甲苯基)以及[Fe(OH)]反应,生成了一系列新的β-铁(II)PNNP'预催化剂——β-[Fe(Br)(CO)(PNNP')]BPh,它们是一对非对映异构体。选择更稳定的邻亚苯基酰胺基来模仿和取代高活性铁预催化剂中的烯酰胺部分,用于酮的不对称转移氢化(ATH)反应,试图防止因烯酰胺基团还原导致的失活。使用带有PEt基团的配合物部分实现了这一目标,该配合物在异丙醇中催化150000当量苯乙酮转移氢化为外消旋1-苯乙醇。在苯乙酮与催化剂比例低至500:1时,催化活性适中,产物1-苯乙醇的对映体过量(ee)令人惊讶地在94%()至95%()之间,这取决于PR的性质以及预催化剂是否含有亚胺或胺供体。带有PEt基团的胺预催化剂在活化时产生更稳定的氢化物物种,使得反应混合物能够加热到75°C,得到苯乙酮的TON为8821,同时保持95%()的高ee值。研究了三种预催化剂在碱性异丙醇(iPrOH)中的活化途径,以阐明β-预催化剂重排形成氢化物配合物。该研究表明,这些配合物的对映选择性取决于氢化物转移发生在PNNP'平面的哪一侧。

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