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Iron-Catalyzed Tunable and Site-Selective Olefin Transposition

Xiaolong Yu, Haonan Zhao, Ping Li, Ming Joo Koh

2020Journal of the American Chemical Society88 citationsDOI

Abstract

The catalytic isomerization of C-C double bonds is an indispensable chemical transformation used to deliver higher-value analogues and has important utility in the chemical industry. Notwithstanding the advances reported in this field, there is compelling demand for a general catalytic solution that enables precise control of the C═C bond migration position, in both cyclic and acyclic systems, to furnish disubstituted and trisubstituted alkenes. Here, we show that catalytic amounts of an appropriate earth-abundant iron-based complex, a base and a boryl compound, promote efficient and controllable alkene transposition. Mechanistic investigations reveal that these processes likely involve in situ formation of an iron-hydride species which promotes olefin isomerization through sequential olefin insertion/β-hydride elimination. Through this strategy, regiodivergent access to different products from one substrate can be facilitated, isomeric olefin mixtures commonly found in petroleum-derived feedstock can be transformed to a single alkene product, and unsaturated moieties embedded within linear and heterocyclic biologically active entities can be obtained.

Topics & Concepts

ChemistryTransposition (logic)Olefin fiberCatalysisCombinatorial chemistryOrganic chemistryPhilosophyLinguisticsSynthetic Organic Chemistry MethodsAsymmetric Hydrogenation and CatalysisChemical Synthesis and Analysis
Iron-Catalyzed Tunable and Site-Selective Olefin Transposition | Litcius