An Ab Initio Perspective on the Key Vacancy Defects of KMgF₃

Abstract: Perovskite-type KMgF3, which represents a distinct class of multifunctional materials, has drawn immense interest in the advanced technological fields due to its various attractive properties. However, these properties are strongly influenced by the presence of various vacancy point defects in the host crystal structure. This drives us to gain a detailed knowledge of the defect chemistry in KMgF3 by investigating geometry, electronic structure, defect formation energies, and charge transition levels. To achiev… Show more

“…For example, unlike in perovskite oxides, such as LaGaO3, in which oxide-ion vacancy 5 can be easily introduced, 18,19 in perovskite fluorides, it is indicated by DFT calculation 6 that fluoride-ion vacancy is difficult to be introduced because of its high formation 7 energy. 20 This indication was experimentally confirmed in some typical perovskites an 8 perovskite-related fluorides by our preliminary investigations (detailed in SI). To 9 overcome the difficulty of defect control in simple fluorides, the use of mixed-anion 10 compounds as a host material is a promising approach for controlling defect species and 11 concentration.…”

Revealing Impacts of Anion Defect Species on Fluoride-Ion Conduction of Ruddlesden-Popper Oxyfluoride Ba₂ScO₃F

“…For example, unlike in perovskite oxides, such as LaGaO3, in which oxide-ion vacancy 5 can be easily introduced, 18,19 in perovskite fluorides, it is indicated by DFT calculation 6 that fluoride-ion vacancy is difficult to be introduced because of its high formation 7 energy. 20 This indication was experimentally confirmed in some typical perovskites an 8 perovskite-related fluorides by our preliminary investigations (detailed in SI). To 9 overcome the difficulty of defect control in simple fluorides, the use of mixed-anion 10 compounds as a host material is a promising approach for controlling defect species and 11 concentration.…”

Revealing Impacts of Anion Defect Species on Fluoride-Ion Conduction of Ruddlesden-Popper Oxyfluoride Ba₂ScO₃F

“…The formation energy of a point defect system is an important quantity to analyse the thermodynamic stability of all defect systems under various synthetic conditions. The defect formation energy (Δ H f ) of defect D X can be expressed as 66,67 where and stand for the energy of KMgF 3 in the presence of defects (D X ) and in the absence of defects with an identical supercell size (3 × 3 × 3) using the HSE hybrid density functional. μ x is the chemical potential of element X and n X is the number of atoms of element X removed ( n x > 0) or added ( n x < 0) during the formation of the defect system, E F is the Fermi level, ε VBM is the energy of the VBM, and q indicates the defect charge state.…”

Probing site-selective doping and charge compensating defects in KMgF₃: insights from a hybrid DFT study

“…Brillouin zone sampling has been performed by a Γ-centered k -point mesh value of 6 × 6 × 6 for the supercell using the Monkhorst and Pack scheme . To overcome the limitation of standard DFT during band gap calculations, we employed the hybrid functional of Heyd, Scuseria, and Ernzerhof (HSE), which is shown to reproduce the experimental band gap for a wide range of materials. − According to this functional, the ion-core interaction is separated into two parts: short range (SR) and long range (LR). The interaction in the SR is described by both exact Hartree–Fock (HF) exchange and PBE exchange, while the LR is solely described by PBE.…”

Enhancement of Photoactivity of TiO₂ for Potential Applications in CO₂ Conversion and Water Splitting: A Hybrid Density Functional Theory Study