AI Article Synopsis
- Single atom catalysts show improved electrocatalytic activity for chemical reactions due to better geometric and electronic structures compared to bulk catalysts.
- Researchers developed a method to create single atom copper immobilized MXene that effectively reduces CO to methanol through selective etching of aluminum in hybrid A layers, preserving copper atoms.
- The new single atom Cu catalyst demonstrated a high Faradaic efficiency of 59.1% for producing methanol and exhibited strong electrocatalytic stability, attributed to its unique unsaturated electronic structure which lowers energy barriers for critical reaction steps.
Article Abstract
Single atom catalysts possess attractive electrocatalytic activities for various chemical reactions owing to their favorable geometric and electronic structures compared to the bulk counterparts. Herein, we demonstrate an efficient approach to producing single atom copper immobilized MXene for electrocatalytic CO reduction to methanol selective etching of hybrid A layers (Al and Cu) in quaternary MAX phases (Ti(AlCu)C) due to the different saturated vapor pressures of Al- and Cu-containing products. After selective etching of Al in the hybrid A layers, Cu atoms are well-preserved and simultaneously immobilized onto the resultant MXene with dominant surface functional group (Cl) on the outmost Ti layers (denoted as TiCCl) Cu-O bonds. Consequently, the as-prepared single atom Cu catalyst exhibits a high Faradaic efficiency value of 59.1% to produce CHOH and shows good electrocatalytic stability. On the basis of synchrotron-based X-ray absorption spectroscopy analysis and density functional theory calculations, the single atom Cu with unsaturated electronic structure (Cu, 0 < δ < 2) delivers a low energy barrier for the rate-determining step (conversion of HCOOH* to absorbed CHO* intermediate), which is responsible for the efficient electrocatalytic CO reduction to CHOH.
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