Non-Monotonic Size-Dependent Exciton Radiative Lifetime in CsPbBr3 Nanocrystals

Abdullah S. Abbas, Daniel Chabeda, Daniel Weinberg, David T. Limmer, Eran Rabani, A. Paul Alivisatos
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Abstract

Lead-halide perovskite nanocrystals have recently emerged as desirable optical materials for applications such as coherent quantum light emitters and solid-state laser cooling due to their short radiative lifetime and near-unity photoluminescence quantum yield. Here, we investigate the effect of CsPbBr3 nanocrystal size on the radiative lifetime under ambient conditions. High-quality nanocrystals, with monoexponential time-resolved photoluminescence decay behaviors, unveil a non-monotonic trend in radiative lifetime. This non-monotonicity appears to reflect a behavior common among II-VI (CdSe) and perovskites semiconducting nanocrystals. We find that large nanocrystals in the weak quantum confinement regime exhibit long radiative lifetimes due to a thermally accessible population of dim states. Small nanocrystals within the strong quantum confinement regime, surprisingly, also show long radiative lifetimes, due however to a substantial reduction in oscillator strength. Nanocrystals in the intermediate quantum confinement regime displays the shortest radiative lifetime, as their oscillator strength is enhanced relative to particles in the strong confinement regime, but do not have sufficient low-lying dim states like the large particles to counteract this affect. These findings shed light on the impact of nanocrystal size on radiative lifetime and pave the way for tailored optical materials in various optical applications.
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CsPbBr3 纳米晶体中与尺寸无关的非单调激子辐射寿命
铅卤化物过氧化物纳米晶体具有辐射寿命短、光致发光量子产率接近单倍的特点,因此近年来已成为相干量子光发射器和固态激光冷却等应用领域的理想光学材料。在此,我们研究了 CsPbBr3 纳米晶体尺寸对环境条件下辐射寿命的影响。高质量纳米晶体具有单指数时间分辨光致发光衰减行为,其辐射寿命呈现非单调趋势。这种非单调性似乎反映了 II-VI(硒化镉)和perovskites 半导体纳米晶体的共同行为。我们发现,在弱量子约束机制下的大尺寸纳米晶体,由于暗态的热可及性,表现出较长的辐射寿命。处于中等量子约束体系的纳米晶体的辐射寿命最短,因为相对于处于强量子约束体系的粒子,它们的振荡器强度增强了,但却没有像大粒子那样有足够的低洼暗态来抵消这种影响。这些发现揭示了纳米晶体尺寸对辐射寿命的影响,并为各种光学应用中的定制光学材料铺平了道路。
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