Visualization of oxygen vacancies and self-doped ligand holes in La3Ni2O7-δ
成果类型:
Article
署名作者:
Dong, Zehao; Huo, Mengwu; Li, Jie; Li, Jingyuan; Li, Pengcheng; Sun, Hualei; Gu, Lin; Lu, Yi; Wang, Meng; Wang, Yayu; Chen, Zhen
署名单位:
Tsinghua University; Sun Yat Sen University; Sun Yat Sen University; Nanjing University; Nanjing University; Tsinghua University; Sun Yat Sen University; Collaborative Innovation Center of Advanced Microstructures (CICAM); Nanjing University; Hefei National Laboratory; Chinese Academy of Sciences; Institute of Physics, CAS; Chinese Academy of Sciences; University of Chinese Academy of Sciences, CAS
刊物名称:
Nature
ISSN/ISSBN:
0028-4157
DOI:
10.1038/s41586-024-07482-1
发表日期:
2024-06-27
页码:
847-+
关键词:
electronic-structure
ptychography
temperature
phase
摘要:
The recent discovery of superconductivity in La3Ni2O7-delta under high pressure with a transition temperature around 80 K (ref. 1) has sparked extensive experimental(2-6) and theoretical efforts(7-12). Several key questions regarding the pairing mechanism remain to be answered, such as the most relevant atomic orbitals and the role of atomic deficiencies. Here we develop a new, energy-filtered, multislice electron ptychography technique, assisted by electron energy-loss spectroscopy, to address these critical issues. Oxygen vacancies are directly visualized and are found to primarily occupy the inner apical sites, which have been proposed to be crucial to superconductivity(13,14). We precisely determine the nanoscale stoichiometry and its correlation to the oxygen K-edge spectra, which reveals a significant inhomogeneity in the oxygen content and electronic structure within the sample. The spectroscopic results also reveal that stoichiometric La3Ni2O7 has strong charge-transfer characteristics, with holes that are self-doped from Ni sites into O sites. The ligand holes mainly reside on the inner apical O and the planar O, whereas the density on the outer apical O is negligible. As the concentration of O vacancies increases, ligand holes on both sites are simultaneously annihilated. These observations will assist in further development and understanding of superconducting nickelate materials. Our imaging technique for quantifying atomic deficiencies can also be widely applied in materials science and condensed-matter physics.
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