Transient Spectroscopy of Glass-Embedded Perovskite Quantum Dots: Novel Structures in an Old Wrapping
Oleg V. Kozlov (1), Rohan Singh (1), Bing Ai (2), Jihong Zhang (2),, Chao Liu (2), Victor I. Klimov (1) ((1) Chemistry Division, C-PCS, Los Alamos, National Laboratory, Los Alamos, New Mexico, (2) State Key Laboratory of, Silicate Materials for Architectures

TL;DR
This study investigates the optical properties of glass-embedded CsPbBr3 perovskite quantum dots, revealing temperature-dependent emission efficiencies and suggesting structural transformations as a key factor affecting quantum yield.
Contribution
It introduces a new type of all-inorganic glass-embedded perovskite QDs and analyzes their temperature-dependent photoluminescence behavior, highlighting the presence of emissive and nonemissive sub-ensembles.
Findings
Low-temperature PL QY up to ~25%
PL efficiency drops with increasing temperature
Existence of emissive and nonemissive QD sub-ensembles
Abstract
Semiconductor doped glasses had been used by the research and engineering communities as color filters or saturable absorbers well before it was realized that their optical properties were defined by tiny specs of semiconductor matter known presently as quantum dots (QDs). Nowadays, the preferred type of QD samples are colloidal particles; however, there is still a number of applications that would benefit from the availability of high-quality glass-based QD samples. These applications include fiber optics, optically pumped lasers and amplifiers, and luminescent solar concentrators. Here we conduct optical studies of a new type of all-inorganic CsPbBr3 perovskite QDs fabricated directly in glasses by high-temperature precipitation. These samples are scattering free and exhibit excellent waveguiding properties. However, the presently existing problem is their low room-temperature…
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