Chemical C-N coupling from CO and NO, driven by renewable electricity, toward urea synthesis is an appealing alternative for Bosch-Meiser urea production. However, the unmatched kinetics in CO and NO reduction reactions and the complexity of C- and N-species involved in the co-reduction render the challenge of C-N coupling, leading to the low urea yield rate and Faradaic efficiency. Here, we report a single-atom copper-alloyed Pd catalyst (PdCu) that can achieve highly efficient C-N coupling toward urea electrosynthesis. The reduction kinetics of CO and NO is regulated and matched by steering Cu doping level and PdCu/FeNi(OH) interface. Charge-polarized Pd-Cu dual-sites stabilize the key *CO and *NH intermediates to promote C-N coupling. The synthesized PdCu-FeNi(OH) composite catalyst achieves a urea yield rate of 436.9 mmol g h and Faradaic efficiency of 66.4%, as well as a long cycling stability of 1000 h. In-situ spectroscopic results and theoretical calculation reveal that atomically dispersed Cu in Pd lattice promotes the deep reduction of NO to *NH, and the Pd-Cu dual-sites lower the energy barrier of the pivotal C-N coupling between *NH and *CO.
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| http://dx.doi.org/10.1038/s41467-023-42794-2 | DOI Listing |
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