Nature Communications (Mar 2025)

Co-expression of multi-genes for polynary perovskite electrocatalysts for reversible solid oxide cells

  • Xiaoxin Zhang,
  • Hongyuan He,
  • Yu Chen,
  • Guangming Yang,
  • Xiao Xiao,
  • Haiping Lv,
  • Yongkang Xiang,
  • Shuxiong Wang,
  • Chang Jiang,
  • Jianhui Li,
  • Zhou Chen,
  • Subiao Liu,
  • Ning Yan,
  • Xue Yong,
  • Abdullah N. Alodhayb,
  • Yuanming Pan,
  • Ning Chen,
  • Jinru Lin,
  • Xin Tu,
  • Zongping Shao,
  • Yifei Sun

DOI
https://doi.org/10.1038/s41467-025-58178-7
Journal volume & issue
Vol. 16, no. 1
pp. 1 – 14

Abstract

Read online

Abstract High-entropy LnBaCo2O5+δ perovskites are explored as rSOC air electrodes, though high configuration entropy (S config) alone poorly correlates with performance due to multifactorial interactions. We systematically engineer LnBaCo2O5+δ perovskites (Ln = lanthanides) with tunable S config and 20 consistent parameters, employing Bayesian-optimized symbolic regression to decode activity descriptors. The model identifies synergistic contributions from S config, ionic radius, and electronegativity, enabling screening of 177,100 compositions. Three validated oxides exhibit superior activity/durability, particularly (Pr0.05La0.4Nd0.2Sm0.1Y0.25)BaCo2O5+δ , showing enhanced oxygen vacancy concentration and disordered transport pathways. First-principles studies reveal optimized charge transfer kinetics via cobalt-oxygen bond modulation. Further, the interplay between first ionization energy, atomic mass, and ionic Lewis acidity dictates stability. This data-driven approach establishes a quantitative framework bridging entropy engineering and catalytic functionality in complex oxides.