Surface tuning of 3DOM LaFe0.6Mg0.4O3 perovskite by acid etching to enhance catalytic performance for soot combustion

[Display omitted] •Surface tuning of LaFe0.6Mg0.4O3 perovskite produced B-site perovskite defects.•Acid etching enhanced oxygen vacancies, formed the Fe4+/Fe3+ redox cycles.•Acid etching generated mesopores structure and increased the specific surface area.•B-site defects of perovskite improved the...

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Bibliographic Details
Published in:Applied surface science 2023-08, Vol.629, p.157435, Article 157435
Main Authors: Ren, Lingling, Huo, Zhuobin, Song, Shangzhi, Yu, Haowei, Tan, Bangjie, Wang, Yujie, Feng, Nengjie, Wan, Hui, Guan, Guofeng
Format: Article
Language:English
Subjects:
B-site acid etching
LaFe0.6Mg0.4O3
Macropores and mesopores
Soot combustion
Structural and surface modification
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Summary:[Display omitted] •Surface tuning of LaFe0.6Mg0.4O3 perovskite produced B-site perovskite defects.•Acid etching enhanced oxygen vacancies, formed the Fe4+/Fe3+ redox cycles.•Acid etching generated mesopores structure and increased the specific surface area.•B-site defects of perovskite improved the catalytic performance of soot combustion. Acid etching is one of the most widely used methods for surface tuning of perovskite. In this paper, 3DOM LaFe0.6Mg0.4O3 was synthesized by a colloidal crystal template method, and was further etched by acetic acid at different times, which made the Mg element at the B-site of perovskite selectively dissolved. Through analysis of multiple characterization results, the introduction of B-site deficiency by acid etching could not only enhance oxygen vacancies, form the Fe4+/Fe3+ redox cycles on the surface of the catalyst, but also generate mesopores structure and increase the specific surface area. After acid treatment, the soot and NO oxidation performances were improved. Among all the as-prepared catalysts, 3DOM LaFe0.6Mg0.4O3 treated by acetic acid for 1 h (LFM-1) exhibited superior reducibility and better activity for soot combustion. The T50 of LFM-1 was 417 °C under 5 % O2/N2 and 500 ppm NO, and the activation energy and TOF were 66 kJ·mol−1 and 2.17 × 10-3 s−1, respectively. Herein, the strategy of introducing B-site deficient by acid treatment is an effective method to improve soot combustion activity, which might be applicable to other catalytic fields.
ISSN:0169-4332
DOI:10.1016/j.apsusc.2023.157435