Progressive Learning-Guided Discovery of Single-Atom Metal Oxide Catalysts for Acidic Oxygen Evolution Reaction.

Journal: Angewandte Chemie (International ed. in English)
Published Date: Jul 12, 2025

Abstract

The oxygen evolution reaction (OER) is a key bottleneck in clean energy conversion due to sluggish kinetics and high overpotentials. Transition metal single-atom catalysts offer great promise for OER optimization thanks to their high atomic efficiency and tunable electronic structures. However, intrinsic scaling relationships between adsorbed intermediates limit catalytic performance and complicate discovery through conventional machine learning (ML). To overcome this, we combined density functional theory (DFT) with a progressive learning strategy within an active learning framework. By first predicting adsorption energies as auxiliary features, our ML model achieved improved sensitivity to rare, high-activity candidates. High-throughput screening of 261 transition metal single-atom-doped metal oxides (MSA-MOx) identified nine top-performing catalysts (theoretical overpotential < 0.5 V), including MnSA-RuO2 and FeSA-TiO2 (theoretical overpotential < 0.3 V). Data mining revealed key theoretical descriptors governing OER activity, while electronic structure analysis pinpointed intermediate binding strength as the key performance driver. Further constant-potential DFT calculations and experimental evaluation of MnSA-RuO2 confirmed its low overpotential and excellent durability under acidic conditions. This integrated framework, which connects theoretical modeling, machine learning prediction, and experimental validation, accelerates the discovery of efficient OER catalysts and provides mechanistic insights for the rational design of materials in sustainable energy technologies.

Authors

  • Liangliang Xu
    University of Puerto Rico Rio Piedras: Universidad de Puerto Rico Recinto de Rio Piedras, Department of Chemistry, UNITED STATES OF AMERICA.
  • Linguo Lu
    University of Puerto Rico Rio Piedras: Universidad de Puerto Rico Recinto de Rio Piedras, Department of Physics, UNITED STATES OF AMERICA.
  • Ning Xu
    Department of Clinical Laboratory The First People's Hospital of Yunnan Province, The Affiliated Hospital of Kunming University of Science and Technology Kunming China.
  • Jinpei Huang
    Chung-Ang University - Seoul Campus: Chung-Ang University, Graduate School of Advanced Imaging Science, KOREA, REPUBLIC OF.
  • Guorui Li
    Department of Engineering Mechanics, Zhejiang University, Hangzhou, 310027, China.
  • Jiaqian Wang
    Zhejiang University, School of Materials Science and Engineering, CHINA.
  • Xiaojuan Hu
    Shanghai Innovation Center of TCM Health Service, Shanghai University of Traditional Chinese Medicine, Pudong, China.
  • Alvaro Guerrero
    University of Puerto Rico Rio Piedras: Universidad de Puerto Rico Recinto de Rio Piedras, Department of Chemistry, CHINA.
  • Juan Carlos Vélez Reyes
    University of Puerto Rico Rio Piedras: Universidad de Puerto Rico Recinto de Rio Piedras, Department of Chemistry, CHINA.
  • Xiujuan Xu
    Department of Critical Care Medicine, Tongde Hospital of Zhejiang Province, Hangzhou, China.
  • Zhong-Kang Han
    Zhejiang University, School of Materials Science and Engineering, CHINA.
  • Zhongfang Chen
    UPR: Universidad de Puerto Rico, Department of Chemistry, Institute for Functional Nanomaterials, Rio Piedras, 00931, San Juan, UNITED STATES OF AMERICA.

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