Haocheng Xiong, Peiping Yu, Kedang Chen, Shike Lu, Qikun Hu, Tao Cheng, Bingjun Xu, Qi Lu
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引用次数: 0
摘要
通过电化学方法将一氧化碳转化为含有 C-N 键的化学物质,可以有效地将二氧化碳转化为一氧化碳,从而为储存可再生能源电力和减少二氧化碳排放提供了一条极具吸引力的途径。以往的电催化研究主要集中在阴极反应上,而阴极反应受到氢进化反应的竞争和电子效率的限制。在此,我们提出了一种在商用铂催化剂上通过电催化 CO 和 NH3 氧化偶联合成尿素的方法。我们证明了尿素的最佳选择性约为 70%,并且在整个宽电位窗口内保持在 50% 以上,电催化 C-N 键形成率高达 100 mmol h-1 gcatalyst-1。在机理研究中,我们提出 CO 和 NH3 在铂上的氧化偶联导致氰酸酯的形成,然后发生沃勒反应生成尿素。这种方法通过铂催化 CO 和 NH3 之间的反应,为具有高电子效率的尿素生产提供了一条实用途径。
Urea synthesis via electrocatalytic oxidative coupling of CO with NH3 on Pt
Electrochemical conversion of CO to chemicals containing C–N bonds offers an appealing route to store renewable electricity and mitigate CO2 emission, as CO2 can be efficiently transformed to CO. Previous electrocatalysis research has primarily focused on cathodic reactions, which are impeded by the competing hydrogen evolution reaction and limited electron efficiency. Here we present a urea synthesis approach via electrocatalytic oxidative coupling between CO and NH3 on commercial Pt catalysts. We demonstrate an optimal selectivity of approximately 70% for urea and remain above 50% throughout a wide potential window with an electrocatalytic C–N bond formation rate of up to 100 mmol h−1 gcatalyst−1. In mechanistic investigations, we propose that the oxidative coupling of CO and NH3 on Pt leads to cyanate formation, followed by the Wöhler reaction to form urea. This approach offers a practical route for urea production with high electron efficiency by enabling Pt-catalysed reactions between CO and NH3. Electrocatalytic urea formation most commonly involves the co-reduction of NOx species with CO2. This limits overall energy efficiency as commodity-scale NOx is produced from N2 via NH3. The swings in nitrogen oxidation state can be minimized through direct oxidative electrocatalytic reaction of CO and NH3 to urea, as shown in this study.
期刊介绍:
Nature Catalysis serves as a platform for researchers across chemistry and related fields, focusing on homogeneous catalysis, heterogeneous catalysis, and biocatalysts, encompassing both fundamental and applied studies. With a particular emphasis on advancing sustainable industries and processes, the journal provides comprehensive coverage of catalysis research, appealing to scientists, engineers, and researchers in academia and industry.
Maintaining the high standards of the Nature brand, Nature Catalysis boasts a dedicated team of professional editors, rigorous peer-review processes, and swift publication times, ensuring editorial independence and quality. The journal publishes work spanning heterogeneous catalysis, homogeneous catalysis, and biocatalysis, covering areas such as catalytic synthesis, mechanisms, characterization, computational studies, nanoparticle catalysis, electrocatalysis, photocatalysis, environmental catalysis, asymmetric catalysis, and various forms of organocatalysis.
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