自陷激子发光机理研究的第一性原理方法

IF 6.1 Q2 CHEMISTRY, PHYSICAL
Huai-Yang Sun, Lin Xiong, Hong Jiang
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引用次数: 1

摘要

近年来,由金属卤化物中的自陷激子(STE)引起的宽带光致发光现象,包括钙钛矿和各种低维衍生物和变体,因其潜在的各种光电子应用,如照明、显示、辐射检测和传感,而引起了越来越多的关注。尽管在实验中发现了许多有效的STE发射体,但目前对金属卤化物中STE发射机制的理解仍然不成熟,而且经常存在争议,这迫切需要预测第一性原理理论计算的帮助。尽管基于密度泛函理论(DFT)的计算通常用于提供材料的电子能带结构,并对发光机理的定性分析做出了巨大贡献,但仍需要更深入和定量的信息来为合理设计具有所需特征的新型发光材料提供指导。然而,由于STE发射的复杂性,特别是涉及基态和激发态的电子-声子耦合,DFT的使用不再是基态性质的常规工作。虽然在多体微扰理论框架下制定的更复杂的方法(如GW Bethe–Salpeter方程)是可用的,并对扩展系统中的电子跃迁提供了理论上严格和准确的描述,但由于计算成本高,它们在实际STE系统中的应用仍然受到严重限制。在实践中,使用近似DFT方法,这些方法有其自身的优势和局限性。在这篇综述中,我们重点介绍了在解释STE发光机制中大量使用的理论方法,特别强调了激子自捕获结构优化的理论方法。希望这篇综述通过总结STE发射理论研究的现状和局限性,将激励这一重要领域更多的方法论发展,推动材料激发态电子结构理论的前沿发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Toward first-principles approaches for mechanistic study of self-trapped exciton luminescence
In recent years, broadband photo-luminescence phenomena arising from self-trapped exciton (STE) in metal halides, including perovskites and various low-dimensional derivatives and variants, have attracted increasing attention for their potential diverse optoelectronic applications like lighting, display, radiation detection, and sensing. Despite great success in experimental discovery of many efficient STE emitters, the current understanding of the STE emission mechanism in metal halides is still immature, and often controversial, which calls for help urgently from predictive first-principles theoretical calculation. Although density-functional theory (DFT) based calculations are routinely used to provide electronic band structure of materials and have contributed greatly to qualitative analysis of luminescence mechanism, more in-depth and quantitative information is highly needed to provide guidelines for rational design of new luminescent materials with desirable features. However, due to the complicated nature of STE emission, involving in particular electron–phonon coupling in both ground and excited states, the usage of DFT is no longer a routine job as for ground state properties. While more sophisticated methods formulated in the framework of many-body perturbation theory like GW-Bethe–Salpeter equation are available and provide theoretically rigorous and accurate description of electronic transitions in extended systems, their application to real STE systems is still severely limited due to highly demanding computational cost. In practice, approximated DFT methods are employed, which have their own strengths and limitations. In this review, we focus on the theoretical approaches that have been heavily used in interpreting STE luminescence mechanism, with a particular emphasis on theoretical methods for exciton self-trapping structural optimization. It is hoped that this review, by summarizing the current status and limitations of theoretical research in the STE emission, will motivate more methodological development efforts in this important field, and push forward the frontiers of excited state electronic structure theory of materials in general.
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