Citation: Wenruo NI, Hongpeng LI, Yun ZHANG, Yiran TIAN, Jiehui RUI, Yingcheng TONG, Xiaolin PI, Zhenyan TANG. Research progress of ruthenium alloy catalysts in hydrogen evolution reaction[J]. Chinese Journal of Inorganic Chemistry, ;2026, 42(1): 23-44. doi: 10.11862/CJIC.20250188 shu

Research progress of ruthenium alloy catalysts in hydrogen evolution reaction

1.
Kunming Institute of Precious Metals, Kunming 650106, China
2.
Yunnan Precious Metal Laboratory Co., Ltd., State Key Laboratory of Precious Metal Functional Materials, Kunming 650106, China

Corresponding author: Xiaolin PI, linlinp0602@163.com Zhenyan TANG, tzy@ipm.com.cn
Received Date: 6 June 2025
Revised Date: 24 November 2025

Figures(13)

Ruthenium alloy catalysts are a class of important catalytic materials, garnering significant attention in various fields such as heterogeneous catalysis, electrocatalysis, and photocatalysis, owing to their unique electronic structure and surface properties. By efficiently combining with other metal elements, the catalytic performance of ruthenium-based catalysts can be significantly improved, expanding their application range. Especially in the hydrogen evolution reaction (HER), ruthenium alloy catalysts have become a research focus for driving efficient conversion of green hydrogen energy due to their outstanding advantages such as high catalytic activity, low cost-effectiveness, good stability and durability. Their excellent performance has brought new possibilities for breakthroughs in sustainable energy technology. This article focuses on HER ruthenium alloy catalysts, with a focus on four core dimensions: preparation methods, component design, modification methods, and performance research. It deeply explores the latest developments in HER ruthenium alloy catalysts in recent years. At the same time, a forward-looking outlook is made on future research directions based on industry development trends, aiming to provide theoretical support and reference for the innovative design and engineering development of high-performance HER ruthenium alloy catalysts, and help promote rapid technological progress in this field.
- ruthenium alloy,
- catalyst,
- hydrogen evolution reaction,
- alloying
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