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First-principles study of XSrBr3 (X = Li, K, Ag) halide perovskites for solar-blind photodetector applications

Muhammad Yar Khan, Muhammad Awais Jehangir, It Ee Lee, Qamar Wali, Tariq Usman, Xiaojie Li, Abdullah Al Souwaileh

2025Chemical Physics Impact7 citationsDOIOpen Access PDF

Abstract

We conducted DFT calculations using FP-LAPW method to explore the electrical, optical, and elastic properties of XSrBr₃ (X = Li, K, Ag) perovskites. For structural optimization, Birch-Murnaghan equation of state is used, which confirmed that these compounds crystallize in a cubic structure. Structural stability was validated through tolerance and octahedral factors, as well as formation energies, while phonon dispersion and Gibbs free energy confirmed their dynamic stability. TB-mBJ-GGA approximation are used to precisely determine the band structures of these compounds and it reveals that all three i.e., (LiSrBr 3 , 6.31 eV), (KSrBr 3 , 6.59 eV), and (AgSrBr 3 , 4.17 eV) are indirect band gaps at the M-Γ high-symmetry points, respectively. IRelast package in WIEN2K are used to assess the elastic responses and it was found all three compounds demonstrated mechanical stability and elastic anisotropy. However, LiSrBr 3 and KSrBr 3 exhibited brittle behavior, while AgSrBr 3 is ductile. In the optical domain, we examined the absorption coefficient, refractive index (n(ω)), reflectivity, and optical conductivity across an energy range of 0 to 12 eV, shedding light on how these materials interacted with different photon energies. Based on the findings, the halide perovskites XSrBr₃ (X = Li, K, Ag) exhibited excellent optical properties, making them strong candidates for solar-blind applications such as UV photodetectors, deep UV-LEDs, and high-frequency systems.

Topics & Concepts

HalidePhotodetectorMaterials scienceOptoelectronicsPerovskite (structure)ChemistryInorganic chemistryCrystallographyPerovskite Materials and ApplicationsThermal Expansion and Ionic ConductivitySolid-state spectroscopy and crystallography