Au3Pd1 intermetallic compound as single atom catalyst for formic acid decomposition with highly hydrogen selectivity

Developing efficient catalysts for formic acid decomposition has been studied extensively. Herein, the Au3Pd1 intermetallic compound is designed as a single atom catalyst for the dehydrogenation of formic acid. By using density functional theory calculations, the thermodynamic stability, electronic structure, and reaction mechanism for the Au3Pd1 catalyst are systematically investigated, and the surface charge polarization and atom-ordered arrangement were confirmed to play an important role in the efficient formic acid dehydrogenation. The special positively charged Pd single atom on the Au3Pd1 surface becomes the adsorption site of HCOO- and the reaction site for formic acid decomposition. The nearby Au sites suppress the C-O bond cleavage due to their weak interaction with CO* and OH*. As a result, the HCOO- dehydrogenation pathway is predominant on the Pd single atomic sites and the CO formation is well inhibited. This intermetallic-based catalyst can be extended to other systems and provided general guidance for efficient catalyst design. & COPY; 2023 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

Efficient catalysts for formic acid decomposition have been extensively studied. In this study, the Au3Pd1 intermetallic compound is designed as a single atom catalyst for formic acid dehydrogenation. The thermodynamic stability, electronic structure, and reaction mechanism of the Au3Pd1 catalyst are systematically investigated, and it is found that surface charge polarization and atom-ordered arrangement play an important role in the efficient dehydrogenation process. The results suggest that this intermetallic-based catalyst can be applied to other systems and provide general guidance for designing efficient catalysts.