Abstract
Electrocatalyst design and optimization strategies continue to be an active area of research interest for the applied use of renewable energy resources and the development of associated technologies. The electrocatalytic conversion of CO2 is an attractive approach in this context, because of the added potential benefit of addressing its rising atmospheric concentrations. In previous experimental and computational studies we have described the mechanism of the first molecular Cr complex capable of electrocatalytically reducing CO2 to CO in the presence of an added proton donor, which contained a redox-active 2,2'-bipyridine (bpy) fragment, CrN2O2. The high selectivity for CO in the bpy-based system was dependent on a delocalized Cr(II)(bpy•–) active state. Subsequently, we became interested in exploring how expanding the polypyridyl ligand core would impact selectivity and activity during electrocatalytic CO2 reduction. Here, we report a new CrN3O catalyst, Cr(tpytbupho)Cl2 1, where 2-([2,2':6',2''-terpyridin]-6-yl)-4,6-di-tert-butylphenolate = [tpytbupho]–, which reduces CO2 to CO with quantitative selectivity via a different mechanism than our previously reported Cr(tbudhbpy)Cl(H2O) catalyst. Computational analyses indicate that changes in the overall reaction are the combined result of a decrease in intrinsic ligand charge (L3X vs L2X2) and an increase in ligand redox activity, which result in increased electronic coupling between the doubly reduced tpy fragment of the ligand and a Cr(II) center. The strong electronic coupling enhances the rate of protonation and subsequent C–OH bond cleavage, resulting in CO2 binding becoming the rate-determining step, which is an uncommon mechanism during protic CO2 reduction.
Supplementary materials
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Supporting Information
Description
Experimental details, computational details, additional CV plots, additional computational plots
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