Abstract
We have quantum chemically studied activation of HnA-AHn bonds (AHn = CH3, NH2, OH, F) by PdLn catalysts with Ln = no ligand, PH3, (PH3)2, using relativistic density functional theory at ZORA-BLYP/TZ2P. The activation energy associated with the oxidative addition step decreases from H3C-CH3 to H2N-NH2 to HO-OH to F-F, where the activation of the F-F bond is barrierless. Activation strain and Kohn-Sham molecular orbital analyses reveal that the enhanced reactivity along this series of substrates originates from a combination of (i) reduced activation strain due to a weaker HnA-AHn bond; (ii) decreased Pauli repulsion as a result of a difference in steric shielding of the HnA-AHn bond; and (iii) enhanced backbonding interaction between the occupied 4d atomic orbitals of the palladium catalyst and σ∗ acceptor orbital of the substrate.
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Moloto, B. P., Vermeeren, P., Tiezza, M. D., Bouwens, T., Esterhuysen, C., Hamlin, T. A., & Bickelhaupt, F. M. (2023). Palladium-catalyzed activation of HnA-AHnbonds (AHn= CH3, NH2, OH, F). Pure and Applied Chemistry, 95(3), 181–191. https://doi.org/10.1515/pac-2022-1004
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