Electron Shuttle in -Heteroaromatic Ni Catalysts for Alkene Isomerization

Overview

Journal JACS Au

Publisher American Chemical Society

Specialty Chemistry

Date 2022 Aug 29

PMID 36032537

Authors

Maxime Tricoire

Ding Wang

Thayalan Rajeshkumar

Laurent Maron

Gregory Danoun

Gregory Nocton

Affiliations

Soon will be listed here.

Abstract

Simple -heteroaromatic Ni(II) precatalysts, (L)NiMe (L = bipy, bipym), were used for alkene isomerization. With an original reduction method using a simple borane (HB(Cat)), a low-valent Ni center was formed readily and showed good conversion when a reducing divalent lanthanide fragment, Cp*Yb, was coordinated to the (bipym)NiMe complex, a performance not achieved by the monometallic (bipy)NiMe analogue. Experimental mechanistic investigations and computational studies revealed that the redox non-innocence of the L ligand triggered an electron shuttle process, allowing the elusive formation of Ni(I) species that were central to the isomerization process. Additionally, the reaction occurred with a preference for mono-isomerization rather than chain-walking isomerization. The presence of the low-valent ytterbium fragment, which contributed to the formation of the electron shuttle, strongly stabilized the catalysts, allowing catalytic loading as low as 0.5%. A series of alkenes with various architectures have been tested. The possibility to easily tune the various components of the heterobimetallic catalyst reported here, the ligand L and the divalent lanthanide fragment, opens perspectives for further applications in catalysis induced by Ni(I) species.

Citing Articles

Alkene Isomerization Catalyzed by a Mn(I) Bisphosphine Borohydride Complex.

Blaha I, Weber S, Dulger R, Veiros L, Kirchner K ACS Catal. 2024; 14(17):13174-13180.

PMID: 39263541 PMC: 11385370. DOI: 10.1021/acscatal.4c03364.

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