To replace the oxygen evolution reaction with thermodynamically more favorable and economically more profitable methane and ethane (the major components of natural gas) electrochemical partial oxidation, we employed constant electrode potential density functional theory calculations to screen 20 one-dimensional metal-organic frameworks containing heteroatom-substituted benzene as electrocatalysts. By computing the Pourbaix diagrams, O-H binding energies, and C-H activation barriers, we determined that although none of these catalysts were able to activate methane, one was able to hydroxylate ethane to ethanol with facile kinetics, making it a promising electrocatalyst for natural gas oxidation.
Keywords: Density functional theory; Electrocatalysis; Ethane oxidation; Natural gas oxidation.
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