Hydrogen Affinity in Intermetallic Electrides as a Key Indicator of Catalytic Performance in Ammonia Synthesis.

IF 16.9 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Angewandte Chemie International Edition Pub Date : 2025-09-29 DOI:10.1002/anie.202516474

Fangkun Sun,Jiang Li,Yijia Liu,Yutong Gong,Peilan Shi,Masaaki Kitano,Hideo Hosono,Jiazhen Wu

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引用次数: 0

Abstract

Electrides have emerged as promising catalysts or catalyst supports for efficient ammonia synthesis under mild conditions. ATmSi compounds (A = rare earth/alkaline earth, Tm = transition metal) with a tetragonal CeFeSi-type structure represent a class of intermetallic electrides, where lattice atoms serve as active sites, offering significant potential for catalytic applications. However, with over 25 ATmSi compounds, their catalytic performance variations and optimization strategies remain poorly understood. In this study, we systematically investigated the structure-activity relationship of ATmSi compounds, focusing on their anionic electron properties and hydrogen storage capabilities. Analysis of lattice parameters revealed the A-A interlayer distance as a descriptor of anionic electron concentration, with the non-electride CaRuSi exhibiting a notable reduction in this distance due to minimal anionic electrons. The catalytic activities in ARuSi, ACoSi, and AFeSi systems all increase with the expansion of A-A interlayer spacing. Furthermore, hydrogen storage properties, where anionic electrons are replaced by hydride ions, were evaluated. It is critical for N2 hydrogenation. The hydrogen affinity, gauged by the desorption temperature, proved pivotal in determining catalytic efficiency, with optimal performance requiring balanced hydrogen binding strength. These findings provide critical insights for designing advanced catalysts for ammonia synthesis and potentially other hydrogenation reactions.

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金属间电子的亲氢性是氨合成催化性能的关键指标。

电子化合物已成为在温和条件下高效合成氨的有前途的催化剂或催化剂载体。ATmSi化合物（A =稀土/碱土，Tm =过渡金属）具有四边形cefesi型结构，代表了一类金属间电子，其中晶格原子作为活性位点，具有重要的催化应用潜力。然而，对于超过25种ATmSi化合物，它们的催化性能变化和优化策略仍然知之甚少。在这项研究中，我们系统地研究了ATmSi化合物的构效关系，重点研究了它们的阴离子电子性质和储氢能力。对晶格参数的分析表明，a - a层间距离是阴离子电子浓度的描述符，由于阴离子电子的减少，非电化物CaRuSi的层间距离明显减小。ARuSi、ACoSi和AFeSi体系的催化活性均随着A-A层间距的增大而增大。此外，氢存储性能，其中阴离子电子被氢化物离子取代，进行了评估。它是N2加氢的关键。通过解吸温度测量的氢亲和性被证明是决定催化效率的关键，其最佳性能需要平衡的氢结合强度。这些发现为设计先进的氨合成催化剂和潜在的其他氢化反应提供了重要的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Angewandte Chemie International Edition 化学-化学综合

CiteScore

26.60

自引率

6.60%

发文量

3549

审稿时长

1.5 months

期刊介绍： Angewandte Chemie, a journal of the German Chemical Society (GDCh), maintains a leading position among scholarly journals in general chemistry with an impressive Impact Factor of 16.6 (2022 Journal Citation Reports, Clarivate, 2023). Published weekly in a reader-friendly format, it features new articles almost every day. Established in 1887, Angewandte Chemie is a prominent chemistry journal, offering a dynamic blend of Review-type articles, Highlights, Communications, and Research Articles on a weekly basis, making it unique in the field.