电催化剂
异质结
材料科学
光化学
化学吸附
氨生产
无机化学
过渡金属
化学
原子轨道
动力学
催化作用
光催化
氨
化学动力学
反应机理
双金属
电子结构
吡嗪
费米能级
化学工程
分解水
作者
Yu Ge,Lizhi Sun,Xinbing Xu,Chenchen Fu,Zhonglong Yin,Qing Zhou,Peng Shi,Weiben Yang,Ben Liu
标识
DOI:10.1002/anie.202519571
摘要
Abstract Electrocatalytic nitrate reduction reaction offers an effective route for ammonia synthesis and actual wastewater treatment. Despite some important achievements, the progress is still low than expected, especially in low‐concentration nitrate, mostly because of slow hydrogenation kinetics and interfering substances. In this work, we presented that, by engineering spin orbital orientation, a carbon‐encapsulated FeP/Fe 3 O 4 heterojunctions (FeP/Fe 3 O 4 @C) enabled ultrafast and stable NH 3 electrosynthesis from low‐concentration nitrate. In‐situ characterization and theoretical calculation confirmed that FeP/Fe 3 O 4 heterojunctions induced spin orbit splitting of Fe, resulting in electron transition from low spin to high spin. The resulted non‐degenerate orbitals caused the energy levels shift up and guided the electron migration from FeP to Fe 3 O 4 , which thus activated additional 3d orbital electron states. This spin orbital orientation further optimized the chemisorption properties of nitrogen‐oxygen intermediates and H* spillover, thus accelerating hydrogenation kinetics for ultrafast NH 3 electrosynthesis. Meanwhile, FeP/Fe 3 O 4 @C electrocatalyst alleviated the phosphate poisoning of active metal sites during industrial wastewater treatment, demonstrating excellent anti‐interference capability and environmental sustainability for real application. This work by modulating the “charge‐spin‐orbit” structure of active sites provided a new strategy for rational design of high‐performance electrocatalysts for various electrocatalytic reactions.
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