Litcius/Paper detail

Strain-induced tunable optoelectronic properties of inorganic halide perovskites APbCl<sub>3</sub> (A = K, Rb, and Cs)

Md. Rasidul Islam, Abdullah Al Mamun Mazumder, Md. Rayid Hasan Mojumder, A. S. M. Zadid Shifat, M. Khalid Hossain

2023Japanese Journal of Applied Physics52 citationsDOIOpen Access PDF

Abstract

Abstract Halide perovskites are promising photovoltaic, solar cell, and semiconductor materials. Density-functional theory (DFT) models address compressive and tensile biaxial strain effects on APbCl 3 , where A = (K, Rb, and Cs). This research shows how A-cation impacts bandgap energy and band structure. The direct bandgap for KPbCl 3 , RbPbCl 3 , and CsPbCl 3 is found 1.612, 1.756, and 2.046 eV, respectively; increases from A = K to Cs. When spin–orbital coupling (SOC) is introduced, bandgaps in KPbCl 3 , RbPbCl 3 , and CsPbCl 3 perovskites are reduced to 0.356, 0.512, and 0.773 eV, respectively. More tensile strain widens the bandgap; compressive strain narrows it. Without SOC, the bandgaps of KPbCl 3 , RbPbCl 3 , and CsPbCl 3 were tuned from 0.486 to 2.213 eV, 0.778 to 2.289 eV, and 1.168 to 2.432 eV, respectively. When the compressive strain is increased, the dielectric constant of APbCl 3 decreases (redshift) and increases (blueshift) as the tensile strain is increased. Strain improves APbCl 3 perovskite’s optical performance.

Topics & Concepts

Band gapPerovskite (structure)Materials scienceHalideBlueshiftStrain (injury)SemiconductorUltimate tensile strengthDensity functional theoryDielectricDirect and indirect band gapsTensile strainOptoelectronicsPhotoluminescenceChemistryCrystallographyComposite materialInorganic chemistryComputational chemistryMedicineInternal medicinePerovskite Materials and ApplicationsSolid-state spectroscopy and crystallographyLuminescence Properties of Advanced Materials