The reduction of carbon dioxide to oxalate has been studied by experimental Collisionally Induced Dissociation (CID) and vibrational characterization of the alkali metal oxalates, supplemented by theoretical electronic structure calculations. The critical step in the reductive process is the coordination of the heterocumulene CO2 to an alkali metal anion, forming a metal carbonite MCO2 ablt to subsequently add a second CO2 molecule. While the energetic demand for these reactions is generally low, we find that the degree of activation of CO2 in terms of charge transfer and transition state energies is the highest for lithium and systematically decreases down the group (M - Li - Cs).
Revised: November 18, 2020 |
Published: October 16, 2020
Citation
Jestila J.S., J. Denton, E. Perez, T. Khuu, E. Apra, E. Apra, and S.S. Xantheas, et al. 2020.Characterization of the Alkali Metal Oxalates (MC2O4-) and their formation by CO2 reduction via the Alkali Metal Carbonites (MCO2-).Physical Chemistry Chemical Physics 22, no. 14:7460-7473.PNNL-SA-156525.doi:10.1039/D0CP00547A