Abstract
Metal-mediated C–H activation reactions generate metal–alkyl intermediates that can be converted into carbon–oxygen bonds through functionalization reactions. While the mechanisms and reactivity of C–H activation reactions have been well studied for transition-metal complexes, much less is known about functionalization reactions, especially for main-group-metal–alkyl complexes. Here we report density functional theory calculations on the reaction thermodynamics and kinetic pathways for main-group, p-block-metal TlIII–methyl functionalization reactions in water using a combination of continuum and explicit/continuum solvent models. Specifically, we examined the oxygen functionalization of (OAc)TlIII(CH3)2 and (OAc)2TlIII(CH3) in water where in both cases functionalization gives methyl acetate and methanol. Our calculations suggest that (OAc)TlIII(CH3)2 is thermodynamically and kinetically stable against bond homolysis, heterolysis, protonolysis, and all reductive functionalization pathways. Functionalizati...
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