Mechanistic Insights into Ru‐catalyzed Alkene Epoxidation with Nitrous Oxide as a Terminal Oxidant

Nitrous oxide (N2O) is a greenhouse gas produced in the manufacture of 6,6‐nylon and nitric acid. While an attractive oxidant that releases only N2 as a by‐product, the kinetic stability of N2O typically requires high temperatures and pressures for activation. This work describes initial kinetics of...

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Bibliographic Details
Published in:European journal of inorganic chemistry 2024-05, Vol.27 (14), p.n/a
Main Authors: Timokhin, Vitaliy I., David Grigg, R., Schomaker, Jennifer M.
Format: Article
Language:English
Subjects:
Alkenes
Catalysts
Disproportionation
Epoxidation
Greenhouse gases
High temperature
kinetics
Low concentrations
N2O
Nitric acid
Nitrous oxide
oxidation
Oxidizing agents
Oxygen transfer
Substrates
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Summary:Nitrous oxide (N2O) is a greenhouse gas produced in the manufacture of 6,6‐nylon and nitric acid. While an attractive oxidant that releases only N2 as a by‐product, the kinetic stability of N2O typically requires high temperatures and pressures for activation. This work describes initial kinetics of oxygen transfer in the epoxidation of cholesteryl acetate with N2O catalysed by D4‐Ru(VI)(por)(O)2 complexes in efforts to provide a better mechanistic understanding of this chemistry. Insights include a need for low concentrations of the alkene to avoid competitive binding to the metal, possible saturation behavior at high N2O pressures, transfer of only one oxygen of RuVI(O)2 to substrate and a possible catalyst turnover involving disproportionation of RuIV(O) and RuIV(O)(N2O) to active RuVI(O)2, RuIV(O) and N2. These insights will be used in future designs of improved catalysts and reaction protocols that may operate efficiently at low pressures of N2O and ambident temperature. Simple kinetic studies provided insights to inform future catalyst designs able to employ N2O as an oxidant under mild conditions. Results suggest the use of low alkene concentrations, possible saturation behavior at high N2O pressures and a potential catalyst turnover involving disproportionation of RuIV(O) and RuIV(O)(N2O).
ISSN:1434-1948
1099-0682
DOI:10.1002/ejic.202300782