Proton-Regulated C–N Coupling for Efficient Amino Acid Electrosynthesis
Yong Wang, Xiang‐Da Zhang, Pengsong Li, Congyang Wang, Yuqing Hou, Ran Duan, Jun Ma, Ganwen Zhang, Xihua Wang, Huizhen Liu, Yichao Zhang, Lihong Jing, Qingli Qian, Xiaofu Sun, Xinchen Kang, Qinggong Zhu, Buxing Han
Abstract
Electrosynthesis of amino acids from abundant nitrogen sources and α-keto acids represents a sustainable route. Enhancing the reaction efficiency and exploring the mechanisms influencing the reaction are of great significance. Herein, we studied the effect of protons in the electrolyte on amino acid synthesis, which has been overlooked to date. Using the coreduction of oxalic acid and nitrate (NO 3 – ) to glycine (Gly) on dendritic Bi as a model system, we found that optimal proton concentrations specifically enhance two key steps of the four-step reactions, governing Gly selectivity and production rate. One is that protons directly coordinate with key intermediates in NO 3 – reduction. Suitable proton concentration induces the desorption of *NH 2 OH (where * denotes an adsorption site) as protonated NH 3 OH + from the catalyst surface. This desorption effectively prevents *NH 2 OH from further reduction to NH 3, securing the essential intermediate (NH 3 OH + ) for Gly synthesis. The other is that suitable proton concentration favors the proton-coupled electron transfer hydrogenation of glyoxylic acid oxime to Gly, which finally enhances the Gly selectivity and production rate. Guided by this mechanistic insight, we optimized the reaction conditions to precisely control each critical step, achieving excellent Gly electrosynthesis performance with an FE Gly of 78.9% and a partial current density of 108.2 mA cm –2 . The versatility of this approach was further demonstrated through efficient synthesis of diverse amino acids, including alanine, aspartic acid, and phenylglycine, delivering very high FEs and yield rates.