DFT study of reductive functionalization in cis and trans cobalt–methyl–bipyridine complexes

High-oxidation state main-group metal complexes are potential alternatives to transition metals for electrophilic alkane C−H functionalization reactions. However, there is little known about how selection of the p-block, main-group metal and ligand impact alkane C−H activation and functionalization thermodynamics and reactivity. This work reports density functional theory calculations used to determine qualitative and quantitative features of C−H activation and metal-methyl functionalization energy landscapes for reaction between high-oxidation state d 10 s 0 In III , Tl III , Sn IV , and Pb IV carboxylate complexes with methane. While the main-group metal influences the C−H activation barrier height in a periodic manner, the carboxylate ligand has a much larger quantitative impact on C−H activation with stabilized carboxylate anions inducing the lowest barriers. For metal-methyl reductive functionalization reactions, the main-group metal dramatically influences the barrier heights, which are correlated to reaction thermodynamics and bond heterolysis energies as a model for two-electron reduction energies. Overall, this work begins to outline which main-group metals and carboxylate ligands could be useful for alkane functionalization systems that utilize electrophilic C−H activation and metal-alkyl functionalization reactions.

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Electrophilic Impact of High-Oxidation State Main-Group Metal and Ligands on Alkane C–H Activation and Functionalization Reactions

King

Rollins

Holdaway

et al. 2018

Organometallics

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DFT study of reductive functionalization in cis and trans cobalt–methyl–bipyridine complexes

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References 17 publications

Electrophilic Impact of High-Oxidation State Main-Group Metal and Ligands on Alkane C–H Activation and Functionalization Reactions

Electrophilic Impact of High-Oxidation State Main-Group Metal and Ligands on Alkane C–H Activation and Functionalization Reactions

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