NUS chemists have developed a new “catalyst control” blueprint to overcome a longstanding challenge in the site-selective dicarbofunctionalization of unactivated alkenes, by enabling the reaction to proceed in the absence of directing or activating groups to access valuable sp3-hybridized carbon frameworks.
Multicomponent catalytic processes that can form multiple carbon-carbon bonds in a single step under mild conditions are highly sought after for generating molecular complexity in chemical synthesis. One such class of reactions involves the transition-metal-catalyzed incorporation of carbogenic units across readily available alkene feedstocks. A key challenge is the ability to control the regioselectivity of olefin addition, especially in situations when the two newly introduced motifs possess similar electronic and/or steric attributes. This problem is further exacerbated in reactions involving the less reactive (unactivated) aliphatic alkenes, which suffer from poor regiochemical control. Conventionally, “substrate control” and “auxiliary control” strategies were employed to implement efficient and site-selective dicarbofunctionalizations across aliphatic olefins. Unfortunately, both approaches require contrived substrate modifications which are costlier, generate excessive waste and limit practicality.
A research team led by Prof. Koh Ming Joo, from the Department of Chemistry, National University of Singapore, has developed a catalytic regime that completely eliminates the need for pre-installed functionalities or directing auxiliaries. This was achieved by leveraging a dimeric nickel(I) catalyst bearing a sterically encumbered N-heterocyclic carbene (NHC) ligand, which would first react with an aryl triflate and undergo branched-selective carbonickelation via transition state TS A across the alkene, so as to minimize steric repulsions that exist between the sizable ligand and the alkene substituent(s) in the disfavored transition state TS A’. Subsequent transmetallation with a Grignard or zinc reagent and reductive elimination furnishes the desired adduct in high efficiency and site selectivity. The regiochemical outcome of these transformations is further supported by density functional theory (DFT) calculations performed by Prof. Osvaldo Gutierrez, a long-time collaborator from the University of Maryland and currently at Texas A&M University.
Prof. Koh said, “With the new Ni-catalyzed method, it is not necessary to pre-introduce an activating or directing unit on the alkene substrate to enhance reaction efficiency or control the regioselectivity of dicarbofunctionalization. This provides significant merits in terms of cost savings, step economy and waste reduction.”
“Our catalytic system can potentially accelerate the assembly of drug-like building blocks for compound library screening in drug discovery programs. We expect the ‘catalyst control’ concept that we conceived in our study to pave the way for the future development of general alkene addition processes that no longer rely on activating units within the substrate for high efficiency and selectivity,” he added.
The research team is currently expanding the scope of this work towards the synthesis of enantioenriched compounds.
H. Wang et al, Directing-group-free catalytic dicarbofunctionalization of unactivated alkenes, Nature Chemistry DOI: 10.1038/s41557-021-00836-6 Published: 2021.
National University of Singapore
Directing group-free alkene dicarbofunctionalization through catalyst control (2021, December 27)
retrieved 27 December 2021
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