Oxygen Transfer in Electrophilic Epoxidation Probed by O NMR: Differentiating Between Oxidants and Role of Spectator Metal Oxo

Overview

Journal Chem Sci

Publisher Royal Society of Chemistry

Specialty Chemistry

Date 2019 Mar 8

PMID 30842846

Citations 2

Authors

Christian Ehinger

Christopher P Gordon

Christophe Coperet

Affiliations

Soon will be listed here.

Abstract

Peroxide compounds are used both in laboratory and industrial processes for the electrophilic epoxidation of olefins. Using NMR-spectroscopy, we investigate why certain peroxides engage in this type of reaction while others require activation by metal catalysts, methyltrioxorhenium (MTO). More precisely, an analysis of O NMR chemical shift and quadrupolar coupling parameters provides insights into the relative energy of specific frontier molecular orbitals relevant for reactivity. For organic peroxides or HO a large deshielding is indicative of an energetically high-lying lone-pair on oxygen in combination with a low-lying σ*(O-O) orbital. This feature is particularly pronounced in species that engage in electrophilic epoxidation, such as peracids or dimethyldioxirane (DMDO), and much less pronounced in unreactive peroxides such as HO and ROOH, which can however be activated by transition-metal catalysts. In fact, for the proposed active peroxo species in MTO-catalyzed electrophilic epoxidation with HO an analysis of the O NMR chemical shift highlights specific π- and δ-type orbital interactions between the so-called metal spectator oxo and the peroxo moieties that raise the energy of the high-lying lone-pair on oxygen, thus increasing the reactivity of the peroxo species.

Citing Articles

Efficient epoxidation over dinuclear sites in titanium silicalite-1.

Gordon C, Engler H, Tragl A, Plodinec M, Lunkenbein T, Berkessel A Nature. 2020; 586(7831):708-713.

PMID: 33116285 DOI: 10.1038/s41586-020-2826-3.

Electronegativity and location of anionic ligands drive yttrium NMR for molecular, surface and solid-state structures.

Latsch L, Lam E, Coperet C Chem Sci. 2020; 11(26):6724-6735.

PMID: 33033594 PMC: 7504898. DOI: 10.1039/d0sc02321c.

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