Revisiting group 4–7 transition metals for heterogeneous ammonia synthesis

EES catalysis Pub Date : 2024-02-02 DOI:10.1039/D3EY00301A
Wenbo Gao, Yawei Wang, Qianru Wang, Zhaolong Sun, Jianping Guo and Ping Chen
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Abstract

Ammonia is a key small molecule for manufacturing nitrogen-based fertilizers and organic chemicals and equally important for renewable energy storage and conversion. The available Haber–Bosch ammonia synthesis process using fused iron catalysts operated under harsh conditions is, however, unsustainable. The development of alternative and more efficient approaches to sustainable ammonia production has garnered much attention recently. Most of the prior work has been devoted to the investigation of Fe, Ru or Co-based metal catalysts for ammonia synthesis. In comparison, there are very limited studies on group 4–7 transition metals, because they are prone to form metal nitrides, which are difficult to hydrogenate to ammonia. This mini-review summarizes recent advances in activating these metals for heterogeneous ammonia synthesis. We show that the potential properties of group 4–7 transition metals for ammonia synthesis should be revisited, which may lead to the development of more efficient materials or chemical processes for ammonia production under mild conditions.

Abstract Image

重新审视用于异相氨合成的 4-7 族过渡金属
氨是制造氮基化肥和有机化学品的关键小分子,对于可再生能源的储存和转换也同样重要。然而,现有的哈伯-博什氨合成工艺使用熔融铁催化剂,在苛刻的条件下运行,是不可持续的。最近,开发可持续氨生产的替代方法和更高效的方法引起了广泛关注。之前的大部分工作都致力于研究用于合成氨的铁基、钌基或钴基金属催化剂。相比之下,对 4-7 族过渡金属的研究非常有限,因为它们容易形成金属氮化物,而氮化物很难氢化为氨。本微型综述总结了活化这些金属用于异相氨合成的最新进展。我们表明,应重新审视 4-7 族过渡金属在氨合成中的潜在特性,这可能会带来更高效的材料或化学工艺,从而在温和条件下生产氨。
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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