Rapid Defect Engineering in FeCoNi/FeAl2O4 Hybrid for Enhanced Oxygen Evolution Catalysis: A Pathway to High‐Performance Electrocatalysts

Author:

Chen Yuhao1,Xu Jiang1,Chen Yujie2,Wang Luqi1,Jiang Shuyun3,Xie Zong‐Han2,Zhang Tianran4,Munroe Paul5,Peng Shengjie1ORCID

Affiliation:

1. College of Materials Science and Technology Nanjing University of Aeronautics and Astronautics Nanjing 210016 China

2. School of Mechanical Engineering University of Adelaide Adelaide SA-5005 Australia

3. Department of Mechanical Engineering Southeast University 2 Si Pai Lou Nanjing 210096 PR China

4. College of Material Science and Opto-Electronic Technology University of Chinese Academy of Science Beijing PR China

5. School of Materials Science and Engineering University of New South Wales NSW 2052 Australia

Abstract

AbstractRational modulation of surface reconstruction in the oxygen evolution reaction (OER) utilizing defect engineering to form efficient catalytic activity centers is a topical interest in the field of catalysis. The introduction of point defects has been demonstrated to be an effective strategy to regulate the electronic configuration of electrocatalysts, but the influence of more complex planar defects (e.g., twins and stacking faults), on their intrinsic activity is still not fully understood. This study harnesses ultrasonic cavitation for rapid and controlled introduction of different types of defects in the FeCoNi/FeAl2O4 hybrid coating, optimizing OER catalytic activity. Theoretical calculations and experiments demonstrate that the different defects optimize the coordination environment and facilitate the activation of surface reconstruction into true catalytic activity centers at lower potentials. Moreover, it demonstrates exceptional durability, maintaining stable oxygen production at a high current density of 300 mA cm−2 for over 120 hours. This work not only presents a novel pathway for designing advanced electrocatalysts but also deepens our understanding of defect‐engineered catalytic mechanisms, showcasing the potential for rapid and efficient enhancement of electrocatalytic performance.

Funder

National Natural Science Foundation of China

Publisher

Wiley

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