Machine Learning‑Assisted Low‑Dimensional Electrocatalysts Design for Hydrogen Evolution Reaction

Authors

Jin Li, Luoyang Normal University
Naiteng Wu, Luoyang Normal University
Jian Zhang, Nanjing University of Posts and Telecommunications
Hong‑Hui Wu, University of Science and Technology Beijing, University of Nebraska-Lincoln
Kunming Pan, Henan University of Science and Technology
Yingxue Wang, National Engineering Laboratory for Risk Perception and Prevention
Guilong Liu, Luoyang Normal University
Xianming Liu, Luoyang Normal University
Zhenpeng Yao, Shanghai Jiao Tong University
Qiaobao Zhang, Xiamen University

Date of this Version

10-13-2023

Citation

Nano-Micro Lett. (2023) 15:227. https://doi.org/10.1007/s40820-023-01192-5

Comments

Open access.

Abstract

Efficient electrocatalysts are crucial for hydrogen generation from electrolyzing water. Nevertheless, the conventional "trial and error" method for producing advanced electrocatalysts is not only cost-ineffective but also time-consuming and labor-intensive. Fortunately, the advancement of machine learning brings new opportunities for electrocatalysts discovery and design. By analyzing experimental and theoretical data, machine learning can effectively predict their hydrogen evolution reaction (HER) performance. This review summarizes recent developments in machine learning for low-dimensional electrocatalysts, including zero-dimension nanoparticles and nanoclusters, one-dimensional nanotubes and nanowires, two-dimensional nanosheets, as well as other electrocatalysts. In particular, the effects of descriptors and algorithms on screening low-dimensional electrocatalysts and investigating their HER performance are highlighted. Finally, the future directions and perspectives for machine learning in electrocatalysis are discussed, emphasizing the potential for machine learning to accelerate electrocatalyst discovery, optimize their performance, and provide new insights into electrocatalytic mechanisms. Overall, this work offers an in-depth understanding of the current state of machine learning in electrocatalysis and its potential for future research.