Unveiling the Structural Effects in Hybrid Copper Phosphonate Frameworks for Selective Electrocatalytic CO Reduction Reaction.

Electrochemical CO reduction holds tremendous promise for transforming carbon dioxide into several value-added energy feedstocks and utilizing renewable energy sources. Herein, we have developed two novel copper-based organophosphonates for selective electrocatalytic conversion of CO to CHOH conversion. The two-dimensional layer structure of Cu[(Hhedp)(CHN)].2HO () and the three-dimensional Cu[(Hhedp)(CHN)(SO)].2HO () have been isolated as single crystals via a hydrothermal strategy. Compound consists of Cu oxidation states exclusively, while compound has Cu oxidation states in a network wherein a Cu-phosphonate template is embedded inside the framework. Depending on mixed valent oxidation states, compound exhibits high selectivity compared to compound for the electrocatalytic reduction of CO to CHOH (C1) as the primary product and CHCOOH (C2) as the secondary product. Notably, product selectivity is enhanced as the Faradaic efficiency (FE) of the competing hydrogen evolution reaction (HER) is significantly reduced in compound relative to that of , particularly at higher applied reduction potentials. The optimal ratio of Cu active sites in compound plays a pivotal role in enhancing methanol selectivity, stabilizing critical intermediates, and maintaining ideal reduction potentials as a noble-metal free electrocatalyst. Moreover, the optical band gap and the Mott-Schottky measurements further suggest the title Cu-phosphonate materials could be promising and effective photocatalysts.