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Computational analysis of apatite‐type compounds for band gap engineering: DFT calculations and structure prediction using tetrahedral substitution

Hai‐Kun Liu, Libing Liao, Yuanyuan Zhang, Sergey M. Aksenov, Ning Liu, Qingfeng Guo, Dina V. Deyneko, Tianyi Wang, Lefu Mei, Chenghua Sun

2021Rare Metals20 citationsDOI

Abstract

Abstract Mineral apatite compounds have attracted significant interest due to their chemical stability and adjustable hexagonal structure, which makes them suitable as new photovoltaic functional materials. The band gap of natural apatite is ~ 5.45 eV, and such a large value limits their applications in the field of catalysis and energy devices. In this research, we designed a method to narrow the band gap via the tetrahedral substitution effect in apatite‐based compounds. The density functional theory (DFT) and experimental investigation of the electronic and optical properties revealed that the continuous incorporation of [MO 4 ] 4– tetrahedrons (M = Si, Ge, Sn, and Mn) into the crystal lattice can significantly reduce the band gap. In particular, this phenomenon was observed when the [MnO 4 ] 4– tetrahedron replaces the [PO 4 ] 4– tetrahedron because of the formation of a Mn 3d‐derived conduction band minimum (CBM) and interacts with other elements, leading to band broadening and obvious reduction of the band gap. This approach allowed us to propose a novel scheme in the band gap engineering of apatite‐based compounds toward an entire spectral range modification.

Topics & Concepts

Materials scienceBand gapApatiteDensity functional theoryTetrahedronElectronic band structureComputational chemistryChemical physicsNanotechnologyCrystallographyOptoelectronicsCondensed matter physicsMineralogyChemistryPhysicsLuminescence Properties of Advanced MaterialsPerovskite Materials and ApplicationsCrystal Structures and Properties
Computational analysis of apatite‐type compounds for band gap engineering: DFT calculations and structure prediction using tetrahedral substitution | Litcius