Exclusive C–C Oxidative Addition in a Rhodium Thiophosphoryl Pincer Complex and Computational Evidence for an η3-C–C–H Agostic Intermediate

The room-temperature reaction between the Rh(I) precursor [Rh(COE)2(acetone)2]BF4 (COE = cyclooctene) and a new thiophosphoryl-based SCS pincer ligand leads to oxidative addition of an sp2–sp3 C–C bond as the only observed outcome, despite the presence of accessible sp3 C–H bonds. A DFT study reveal...

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Bibliographic Details
Published in:Organometallics 2012-01, Vol.31 (1), p.505-512
Main Authors: Montag, Michael, Efremenko, Irena, Diskin-Posner, Yael, Ben-David, Yehoshoa, Martin, Jan M. L, Milstein, David
Format: Article
Language:eng ; jpn
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Summary:The room-temperature reaction between the Rh(I) precursor [Rh(COE)2(acetone)2]BF4 (COE = cyclooctene) and a new thiophosphoryl-based SCS pincer ligand leads to oxidative addition of an sp2–sp3 C–C bond as the only observed outcome, despite the presence of accessible sp3 C–H bonds. A DFT study reveals that the chemistry of the SCS system is controlled by π repulsion between occupied rhodium d orbitals and the lone-pair electrons on the two sulfur atoms. This repulsion gives rise to the thermodynamic selectivity for C–C over C–H cleavage, as it is attributed to the higher electronegativity of a methyl versus hydride ligand, thereby allowing more effective release of excessive π electron density. It is also demonstrated that the observed C–C and unobserved C–H cleavage pathways originate from a common intermediate that features a novel η3-C–C–H agostic interaction. The COE ligand is shown to play an important role by greatly stabilizing this intermediate, making it the only available entry point to both reaction pathways.
ISSN:0276-7333
1520-6041
DOI:10.1021/om201205y