Activation of CO and CH on MgO surfaces: mechanistic insights from first-principles theory.

One of the most challenging topics in heterogeneous catalysis is conversion of CH to higher hydrocarbons. Direct conversion of CH to ethylene can be achieved the oxidative coupling of methane (OCM) reaction. Despite studies which have shown MgO to activate CH and initiate the OCM reaction, its large-scale applications face a significant impediment due to formation of a byproduct, CO, and poisoning of the catalyst due to carbonate formation. In the present work, we address two aspects of the OCM reaction on MgO surfaces: carbonate formation on the surface of the catalyst, and (dissociative) adsorption of CH. We use first-principles density functional theoretical calculations to determine the energetics and underlying mechanisms of interaction of CO and CH with various surfaces of MgO: (100), (110), and (111) (both Mg- and O-terminations), and the seldom studied, hydroxylated (111) MgO surface with O-termination. We find that the strength of the interaction of CO with MgO surfaces depends on several factors: their surface energies, coordination number of surface O atoms, and ability to donate electrons. However, the O-terminated (111) surface of MgO bucks all aforementioned factors, with only oxygen richness affecting its reactivity towards CO. The interaction of CH with MgO surfaces depends primarily on the coordination number of the surface O atoms and the orientation of the CH molecule with respect to the surface. Finally, we provide insights into (a) formation of surface carbonates, which is relevant to CO capture and conversion, and (b) C-H bond activation on MgO surfaces, which is crucial for direct conversion of CH to value-added chemicals.