Band-Edge Electronic Structure on Photo(electro)catalytic Performance of ABO<sub>2</sub> (A = Cu, Ag; B = Al, Ga, In): Elucidating the Role of Valence Electron States
Shi-Wei Fu, Jian Yang, Zong‐Yan Zhao, Bao‐Feng Shan, Jiaxin Zhang, Jin Zhang, Qingju Liu, Jianyong Feng, Zhaosheng Li, Zhigang Zou
Abstract
A profound understanding of the band-edge electronic structure is crucial for advancing the development of highly efficient photocatalytic materials and unraveling the underlying mechanisms. This study employs a unified and consistent assessment protocol, offering a systematic exploration of the inherent connections between the band-edge electronic structure and the photo(electro)catalytic performance of a series of delafossite ABO 2 compounds (A = Cu, Ag; B = Al, Ga, In). These compounds exhibit characteristics of indirect bandgap semiconductors, with fundamental and optical bandgaps spanning from 1.45 to 3.57 eV. Notably, the Cu-based ABO 2 compounds display a significantly larger fundamental bandgap and excel as photocathode materials when the B-site element is held constant. Among these, CuInO 2 emerges as the most promising candidate, showcasing superior photo(electro)catalytic performance. Extensive density functional theory calculations unravel intricate insights into the interplay between the band-edge electronic structure and valence orbital hybridization of the A- and B-site elements, providing invaluable perspectives for comprehending and enhancing the photo(electro)catalytic performance of such compounds. The findings in this study not only establish robust theoretical foundations for integrating ABO 2 compounds into the field of photo(electro)catalysis but also lay the groundwork for future material design and optimization.