Photo-Driven Ammonia Synthesis via a Proton-Mediated Photoelectrochemical Device.

N reduction reaction (NRR) by light is an energy-saving and sustainable ammonia (NH) synthesis technology. However, it faces significant challenges, including high energy barriers of N activation and unclear catalytic active sites. Herein, we propose a strategy of photo-driven ammonia synthesis via a proton-mediated photoelectrochemical device. We used redox-catalysis covalent organic framework (COF), with a redox site (-C=O) for H reversible storage and a catalytic site (porphyrin Au) for NRR. In the proton-mediated photoelectrochemical device, the COF can successfully store e and H generated by hydrogen oxidation reaction, forming COF-H. Then, these stored e and H can be used for photo-driven NRR (108.97 umol g) under low proton concentration promoted by the H-bond network formed between -OH in COF-H and N on Au, which enabled N hydrogenation and NH production, establishing basis for advancing artificial photosynthesis and enhancing ammonia synthesis technology.