Absence of Anomalous Electron-Phonon Coupling in the Temperature Renormalization of the Gap of CsPbBr$_3$ Nanocrystals

arXiv - PHYS - Materials Science Pub Date : 2024-09-10 DOI:arxiv-2409.06374

Shima Fasahat, Benedikt Schäfer, Kai Xu, Nadesh Fiuza-Maneiro, Sergio Gómez-Graña, M. Isabel Alonso, Lakshminarayana Polavarapu, Alejandro R. Goñi

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Abstract

Metal halide perovskites exhibit a fairly linear increase of the bandgap with increasing temperature, when crystallized in a tetragonal or cubic phase. In general, both thermal expansion and electron-phonon interaction effects contribute equally to this variation of the gap with temperature. Herein, we have disentangled both contributions in the case of colloidal CsPbBr$_3$ nanocrystals (NCs) by means of photoluminescence (PL) measurements as a function of temperature (from 80 K to ambient) and hydrostatic pressure (from atmospheric to ca. 1 GPa). At around room temperature, CsPbBr$_3$ NCs also show a linear increase of the bandgap with temperature with a slope similar to that of the archetypal methylammonium lead iodide (MAPbI$_3$) perovskite. This is somehow unexpected in view of the recent observations in mixed-cation Cs$_x$MA$_{1-x}$PbI$_3$ single crystals with low Cs content, for which Cs incorporation caused a reduction by a factor of two in the temperature slope of the gap. This effect was ascribed to an anomalous electron-phonon interaction induced by the coupling with vibrational modes admixed with the Cs translational dynamics inside the cage voids. Thus, no trace of anomalous coupling is found in CsPbBr$_3$ NCs. In fact, we show that the linear temperature renormalization exhibited by the gap of CsPbBr$_3$ NCs is shared with most metal halide perovskites, due to a common bonding/antibonding and atomic orbital character of the electronic band-edge states. In this way, we provide a deeper understanding of the gap temperature dependence in the general case when the A-site cation dynamics is not involved in the electron-phonon interaction.

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CsPbBr$_3$ 纳米晶体间隙的温度重正化中不存在反常电子-鹭鸶耦合现象

当结晶为四方或立方晶相时，金属卤化物包光体的带隙在温度升高时呈相当线性的增长。一般来说，热膨胀效应和电子-声子相互作用效应对这种带隙随温度变化的影响是相同的。在这里，我们通过测量光致发光（PL）与温度（从 80 K 到环境温度）和静水压力（从大气压到约 1 GPa）的函数关系，对胶体 CsPbBr$_3$ 纳米晶体（NCs）的情况进行了分析。在室温左右，CsPbBr$_3$ NCs 的带隙也随温度呈线性增长，其斜率与典型的甲基碘化铵铅 (MAPbI$_3$) 包晶的斜率相似。鉴于最近在铯含量较低的混合阳离子 Cs$_x$MA$_{1-x}$PbI$_3$ 单晶中观察到的情况，这多少有些出乎意料。这种效应可归因于笼状空隙内与 C 晶体动态混合的振动模式耦合引起的异常电子-声子相互作用。因此，在 CsPbBr$_3$ NCs 中没有发现异常耦合的痕迹。事实上，我们的研究表明，CsPbBr$_3$ NCs 间隙所表现出的线性温度重正化与大多数金属卤化物包晶石相同，这是由于电子带边态具有共同的成键/反成键和原子轨道特性。这样，当 A 位阳离子动力学不参与电子-声子相互作用时，我们就能更深入地理解一般情况下的间隙温度依赖性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Materials Science

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