Exceptional metal-semiconductor-metal transition of lead apatites via oxygen defect tuning
PHYSICAL CHEMISTRY CHEMICAL PHYSICS(2024)
摘要
Lead apatites, distinguished and compelling bulk materials with the stoichiometric arrangement as Pb-10(POx)(6)O-y, are renowned for their structural complexity. Recently, the discovery of possible room-temperature superconductivity under ambient pressure in copper-substituted lead apatites has engendered considerable interest within both the physics community and beyond. Nevertheless, exploration of pristine Pb-10(POx)(6)O-y parent structures has hitherto remained elusive. In this study, we employ density functional theory (DFT) calculations to investigate the effects of oxygen defects on the electronic structures of Pb-10(POx)(6)O-y and Pb9Cu(POx)(6)O-y. We scrutinize two distinct categories of defects: oxygen atoms enmeshed within POx groups (O-x) and solitary oxygen atoms (O-y). Our investigation uncovers a profound influence of these defects on the band structure. Specifically, the introduction of O-y defects prompts a remarkable transition in Pb-10(PO4)(6)O-y from a metal to semiconductor to metal state, accompanied by pivotal shifts in the principal electronic contributors from p orbitals of O-y to those of Pb atoms. Furthermore, the introduction of O-x defects in Pb-10(POx)(6)O-1 engenders metamorphosis in the band structure, transmuting it from a semiconductor to a metallic state. Significantly, our findings pinpoint the suitable range of x in the Pb-10(POx)(6)O-1 configuration as lying between 2 and 4. Additionally, our study also demonstrates that the oxygen defects (O-x/O-y) do not affect the metallic properties of copper-substituted lead apatites. This study elucidates the significant role of oxygen defects in modulating the electronic properties of apatite materials, offering insights into potential interdisciplinary applications. This establishes a crucial link between material composition and electronic behavior, revealing key mechanisms for engineering functionality in lead apatites and other advanced materials.
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