Nature Communications (Jun 2024)

Subsurface A-site vacancy activates lattice oxygen in perovskite ferrites for methane anaerobic oxidation to syngas

  • Jiahui He,
  • Tengjiao Wang,
  • Xueqian Bi,
  • Yubo Tian,
  • Chuande Huang,
  • Weibin Xu,
  • Yue Hu,
  • Zhen Wang,
  • Bo Jiang,
  • Yuming Gao,
  • Yanyan Zhu,
  • Xiaodong Wang

DOI
https://doi.org/10.1038/s41467-024-49776-y
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Tuning the oxygen activity in perovskite oxides (ABO3) is promising to surmount the trade-off between activity and selectivity in redox reactions. However, this remains challenging due to the limited understanding in its activation mechanism. Herein, we propose the discovery that generating subsurface A-site cation (Lasub.) vacancy beneath surface Fe-O layer greatly improved the oxygen activity in LaFeO3, rendering enhanced methane conversion that is 2.9-fold higher than stoichiometric LaFeO3 while maintaining high syngas selectivity of 98% in anaerobic oxidation. Experimental and theoretical studies reveal that absence of Lasub.-O interaction lowered the electron density over oxygen and improved the oxygen mobility, which reduced the barrier for C-H bond cleavage and promoted the oxidation of C-atom, substantially boosting methane-to-syngas conversion. This discovery highlights the importance of A-site cations in modulating electronic state of oxygen, which is fundamentally different from the traditional scheme that mainly credits the redox activity to B-site cations and can pave a new avenue for designing prospective redox catalysts.