Effect of Vacancy-Defect on the Electronic and Optical Properties of Cs3Cu2I5 Scintillators: A First-Principles Study

Lead-free copper-based halide perovskite Cs3Cu2I5 crystals have been recognized as a highly promising material in the field of scintillator materials due to their high quantum yield and fast decay characteristics. Their exceptional optical properties and environmental stability render them highly advantageous for gamma and X-ray detection applications, showcasing significant potential for practical use. To conduct a comprehensive analysis of the impact of irradiation defects on the luminescent performance of Cs3Cu2I5 scintillators and their physical mechanisms, this study employs first-principles methods, focusing on the effects of vacancy defects induced by irradiation on the electronic structure and optical properties of Cs3Cu2I5 crystals. The research finds that Cs and Cu vacancy defects introduce shallow energy levels within the material’s bandgap, thereby expanding the luminescent pathways of the crystal and significantly enhancing the radiative recombination rate. In contrast, I vacancy defects create deep energy levels in the bandgap, functioning as nonradiative recombination centers, thereby suppressing luminescent performance. Furthermore, the presence of I vacancy defects exacerbates the self-absorption of visible light in Cs3Cu2I5 scintillators, resulting in a diminished optical signal reaching the photomultiplier tube, and consequently affecting the overall detection efficiency of the scintillator detector. This study reveals the microscopic mechanisms of damage to Cs3Cu2I5 scintillators under high-energy radiation, offering significant theoretical insights for performance optimization and damage protection in practical applications.