定向电还原亚硝酸盐至氨的脉冲激光引发的双催化界面

Talshyn Begildayeva, Jayaraman Theerthagiri, Vy Thuy Nguyen, Ahreum Min, Hyeyoung Shin, Myong Yong Choi
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摘要

在中性电解质中通过有毒亚硝酸盐(NO2-RR)的电化学还原反应绿色、高选择性地合成氨(NH3)是解决能源和环境问题的可行方案。结合金属和金属衍生材料的双性质电催化剂对于提高该反应的选择性参数和功效至关重要。在此,我们通过液态单锅脉冲激光烧蚀法获得了具有强大金属-支撑相互作用的 Pd-、Pt-、Ru-和 Ir-装饰 Co3(PO4)2 (CoPi) 复合材料。在所设计的复合材料中,Ir-CoPi 的法拉第效率、质量平衡和在足够低的电位下对 NH3 产物的选择性均≈100%。此外,与 Ag/AgCl 相比,Ir-CoPi 的 NH3 产率最高,达到 19.13 mg h-1 cm-2,有毒 NO2- 的去除率为 78.1%,速率常数 kapp = 0.31 mm min-1(-1.6 V)。现场实验和理论研究揭示了 Ir-CoPi 杰出性能的内在机理,这可归功于 Ir 成分上特定活性位点的产生。通过电化学技术、密度泛函理论计算和改进相应的工业流程,从不断变化的中间反应物中获得的启示为大规模生产 NH3 提供了新的机遇。
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Pulsed Laser-Initiated Dual-Catalytic Interfaces for Directed Electroreduction of Nitrite to Ammonia
Green and highly selective synthesis of ammonia (NH3) via electrochemical reduction reaction of toxic nitrite (NO2RR) in a neutral electrolyte is a feasible solution for energy and environmental issues. Dual-nature electrocatalysts combining metal and metal-derived materials are crucial for enhancing the selectivity parameter and efficacy of this reaction. Here, Pd-, Pt-, Ru-, and Ir-decorated Co3(PO4)2 (CoPi) composites with a robust metal–support interaction are obtained via the one-pot pulsed laser ablation in liquid method. Among the designed composites, Ir–CoPi affords ≈100% Faradaic efficiency, mass balance, and selectivity toward NH3 product at sufficiently low potentials. Further, it affords the highest NH3 yield rate of 19.13 mg h−1 cm−2 with 78.1% removal of toxic NO2 with a rate constant kapp = 0.31 mm min−1 under −1.6 V versus Ag/AgCl. In situ experiments and theoretical investigations reveal the underlying mechanisms responsible for this outstanding performance of Ir–CoPi, which can be accredited to the generation of specific active sites on the Ir component. Insights derived from the evolving intermediate reactive species provide new opportunities for large-scale NH3 production through electrochemical techniques, density functional theory calculations, and the improvement of the corresponding industrial processes.
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