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Achieving Record-Breaking Urea Synthesis on Crystalline–Amorphous Hybrid via Electrochemical-Chemical Looping

Cheng Zhong, Xiaodeng Wang, Dafeng Yan, Xupeng Qin, Dawei Chen, Chu Zhang, Yujie Wang, Yansong Zhou, Chade Lv, Peilian Hou, Kefan Zhang, Peng Jin, Yangyang Zhou, Qinghua Liu, Kaizhi Gu, Xiaoxiao Wei, Chen Chen, Shuangyin Wang

2025Journal of the American Chemical Society12 citationsDOI

Abstract

Electrocatalytic C–N coupling of nitrate and CO 2 represents a paradigm shift in sustainable urea synthesis. We demonstrate that amorphous CuO x -coated crystalline Cu nanowires achieve a record-breaking urea yield rate of 0.89 mol h –1 g –1 via novel electrochemical-chemical looping. Mechanistic investigations reveal a three-step catalytic cycle: (i) electro-reductive generation of Cu 0 and oxygen vacancies (O v ); (ii) O v -mediated nitrate activation via oxygen atom insertion, spontaneously yielding nitrogen-bonded nitrite (*NO 2 ) while oxidizing Cu 0 to catalytically active Cu +; and (iii) Cu + -catalyzing C–N coupling between *NO 2 and CO 2 to form urea. This pathway circumvents conventional rate-limiting nitrate reduction step, reducing the electron transfer requirement from 16e – to 12e – for urea synthesis. Notably, direct nitrite utilization fails to generate Cu + or nitrogen-bonded intermediates, instead forming oxygen-bonded species with markedly reduced C–N coupling activity–a finding that overturns conventional understanding. Our work establishes new fundamental principles for efficient urea synthesis and provides insights into catalyst design and green chemistry.

Topics & Concepts

ChemistryUreaCatalysisElectron transferOxidizing agentNitriteNitrateYield (engineering)Inorganic chemistryOxygenCoupling (piping)Amorphous solidRedoxCombinatorial chemistryElectrochemistryWork (physics)Green chemistryChemical engineeringAmmonia Synthesis and Nitrogen ReductionAdvanced Photocatalysis TechniquesCovalent Organic Framework Applications
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