Enhanced Optical Properties and Stability of CsPbBr3 Nanocrystals Through Nickel Doping

To improve the quantum efficiency and stability of perovskite quantum dots, the structural and optical properties are optimized by varying the concentration of Ni doping in CsPbBr3 perovskite nanocrystals (PNCs). As Ni doping is gradually added, a blue shift is observed at the photoluminescence (PL) spectra. Ni‐doped PNCs exhibit stronger light emission, higher quantum efficiency, and longer lifetimes than undoped PNCs. The doped divalent element acts as a defect in the perovskite structure, reducing the recombination rate of electrons and holes. A stability test is used to assess the susceptibility of the perovskite to light and moisture. For ultra‐violet light irradiation, the PL intensity of undoped PNCs decreases by 70%, whereas that of Ni‐doped PNCs decreases by 18%. In the water addition experiment, the PL intensity of Ni‐doped PNCs is three times that of undoped PNCs. For CsPbBr3 and Ni:CsPbBr3 PNCs, a light emitting diode is fabricated by spin‐coating. The efficiency of Ni:CsPbBr3 exceeds that of CsPbBr3 PNCs, and the results significantly differ based on the ratio. A maximum luminance of 833 cd m–2 is obtained at optimum efficiency (0.3 cd A–1). Therefore, Ni‐doped PNCs are expected to contribute to future performance improvements in display devices. The addition of transition metal nickel to cesium lead halide perovskite improves stability against moisture and UV light, increases the quantum yield by 26.2%, and significantly reduces the non‐radiative recombination. This modification approach can overcome the limitations of commercialization as the nickel doped perovskite demonstrates high luminescence efficiency when applied to LED devices.