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Entropy-Engineered Middle-In Synthesis of Dual Single-Atom Compounds for Nitrate Reduction Reaction

Yao Hu, Haihui Lan, Junjun He, Wenjing Fang, Wenda Zhang, Shuanglong Lu, Fang Duan, Mingliang Du

2024ACS Nano41 citationsDOI

Abstract

Despite the immense potential of Dual Single-Atom Compounds (DSACs), the challenges in their synthesis process, including complexity, stability, purity, and scalability, remain primary concerns in current research. Here, we present a general strategy, termed “Entropy-Engineered Middle-In Synthesis of Dual Single-Atom Compounds” (EEMIS-DSAC), which is meticulously crafted to produce a diverse range of DSACs, effectively addressing the aforementioned issues. Our strategy integrates the advantages of both bottom-up and top-down paradigms, proposing an insight into optimizing the catalyst structure. The as-fabricated DSACs exhibited excellent activity and stability in the nitrate reduction reaction (NO 3 RR). In a significant advancement, our prototypical CuNi DSACs demonstrated outstanding performance under conditions reminiscent of industrial wastewater. Specifically, under a NO 3 – concentration of 2000 ppm, it yielded a Faradaic efficiency (FE) for NH 3 of 96.97%, coupled with a mass productivity of 131.47 mg h –1 mg –1 and an area productivity of 10.06 mg h –1 cm –2 . Impressively, even under a heightened NO 3 – concentration of 0.5 M, the FE for NH 3 peaked at 90.61%, with a mass productivity reaching 1024.50 mg h –1 mg –1 and an area productivity of 78.41 mg h –1 cm –2 . This work underpins the potential of the EEMIS-DSAC approach, signaling a frontier for high-performing DSACs.

Topics & Concepts

Dual (grammatical number)Reduction (mathematics)NitrateAtom (system on chip)Combinatorial chemistryChemistryNanotechnologyMaterials scienceComputational chemistryComputer scienceOrganic chemistryMathematicsGeometryEmbedded systemArtLiteratureAmmonia Synthesis and Nitrogen ReductionCatalytic Processes in Materials ScienceAdvanced Photocatalysis Techniques