Login / Signup

Unveiling the Structure of Oxygen Vacancies in Bulk Ceria and the Physical Mechanisms behind Their Formation.

Zheng LiNing XuYujing ZhangWen LiuJiaqian WangMeiliang MaXiaolan FuXiaojuan HuWen-Wu XuZhong-Kang Han
Published in: The journal of physical chemistry letters (2024)
Understanding the structures of oxygen vacancies in bulk ceria is crucial as they significantly impact the material's catalytic and electronic properties. The complex interaction between oxygen vacancies and Ce 3+ ions presents challenges in characterizing ceria's defect chemistry. We introduced a machine learning-assisted cluster-expansion model to predict the energetics of defective configurations accurately within bulk ceria. This model effectively samples configurational spaces, detailing oxygen vacancy structures across different temperatures and concentrations. At lower temperatures, vacancies tend to cluster, mediated by Ce 3+ ions and electrostatic repulsion, while at higher temperatures, they distribute uniformly due to configurational entropy. Our analysis also reveals a correlation between thermodynamic stability and the band gap between occupied O 2 p and unoccupied Ce 4 f orbitals, with wider band gaps indicating higher stability. This work enhances our understanding of defect chemistry in oxide materials and lays the groundwork for further research into how these structural properties affect ceria's performance.
Keyphrases
  • machine learning
  • quantum dots
  • mental health
  • high resolution
  • energy transfer
  • physical activity
  • artificial intelligence
  • mass spectrometry
  • density functional theory
  • water soluble
  • big data
  • deep learning