Abstract
Michael addition is one of the most important carbon–carbon bond formation reactions. In this study, an (R, R)-1,2-diphenylethylenediamine (DPEN)-based thiourea organocatalyst was applied to the asymmetric Michael addition of nitroalkenes and cycloketones to produce a chiral product. The primary amine moiety in DPEN reacts with the ketone to form an enamine and is activated through the hydrogen bond formation between the nitro group in the α, β-unsaturated nitroalkene and thiourea. Here, the aim was to obtain an asymmetric Michael product through the 1,4-addition of the enamine to an alkene to form a new carbon–carbon bond. As a result, the primary amine of the chiral diamine was converted into an enamine. The reaction proceeded with a relatively high level of enantioselectivity achieved using double activation through the hydrogen bonding of the nitro group and thiourea. Michael products with high levels of enantioselectivity (76–99% syn ee) and diastereoselectivity (syn/anti = 9/1) were obtained with yields in the range of 88–99% depending on the ketone.
Highlights
Various cycloketones, acetone and nitrostyrene derivatives were reacted in the conditions, various cycloketones, acetone and nitrostyrene derivatives were reacted in the presence of the catalyst, solvent, and a phenol group derivative
Density functional theory (DFT) calculations were performed to show the mechanisms of substrates and catalysts
The asymmetric 1,4-addition reaction of various ketones with nitroalkenes was catalyzed using a DPEN-based thiourea catalyst to form enamines that act as nucleophiles
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Reactions using metal complexes as catalysts have exhibited higher catalytic activity than that of conventional Pt complex catalysts. Metal catalysts are expensive, and the residual metals can cause environmental problems due to disposal after use and contamination of the products [1]. The replacement of metal catalysts with organic catalysts in some reactions may solve a significant portion of the aforementioned problems. The Michael reaction is one of the most important carbon–
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