Excitons in organic materials: revisiting old concepts with new insights

IF 2.9 Q3 CHEMISTRY, PHYSICAL Electronic Structure Pub Date : 2023-08-22 DOI:10.1088/2516-1075/acf2d4
A. M. Valencia, D. Bischof, Sebastian Anhäuser, Marc Zeplichal, A. Terfort, G. Witte, C. Cocchi
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Abstract

The development of advanced experimental and theoretical methods for the characterization of excitations in materials enables revisiting established concepts that are sometimes misleadingly transferred from one field to another without the necessary disclaimers. This is precisely the situation that occurs for excitons in organic materials: different states of matter and peculiarities related to their structural arrangements and their environment may substantially alter the nature of the photo-induced excited states compared to inorganic semiconductors for which the concept of an exciton was originally developed. Adopting the examples of tetracene and perfluorotetracene, in this review, we analyze the nature of the excitations in the isolated compounds in solution, in the crystalline materials, and in melt. Using single crystals or films with large crystalline domains enables polarization-resolved optical absorption measurements, and thus the determination of the energy and polarization of different excitons. These experiments are complemented by state-of-the-art first-principles calculations based on density-functional theory and many-body perturbation theory. The employed methodologies offer unprecedented insight into the optical response of the systems, allowing us to clarify the single-particle character of the excitations in isolated molecules and the collective nature of the electron–hole pairs in the aggregated phases. Our results reveal that the turning point between these two scenarios is the quantum-mechanical interactions between the molecules: when their wave-function distributions and the Coulomb interactions among them are explicitly described in the adopted theoretical scheme, the excitonic character of the optical transitions can be captured. Semi-classical models accounting only for electrostatic couplings between the photo-activated molecules and their environment are unable to reproduce these effects. The outcomes of this work offer a deeper understanding of excitations in organic semiconductors from both theoretical and experimental perspectives.
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有机材料中的激子:用新见解重新审视旧概念
材料中激发态表征的先进实验和理论方法的发展使人们能够重新审视那些有时在没有必要的免责声明的情况下从一个领域误导性地转移到另一个领域的既定概念。这正是发生在有机材料中的激子的情况:与激子概念最初发展的无机半导体相比,物质的不同状态和与其结构排列及其环境相关的特性可能会大大改变光诱导激发态的性质。本文以四烯和全氟四烯为例,分析了分离化合物在溶液、结晶材料和熔体中的激发性质。使用单晶或具有大晶体域的薄膜可以实现偏振分辨光学吸收测量,从而确定不同激子的能量和偏振。这些实验是由基于密度泛函理论和多体微扰理论的最先进的第一性原理计算补充的。所采用的方法为系统的光学响应提供了前所未有的见解,使我们能够阐明孤立分子中激发的单粒子特征以及聚集相中电子-空穴对的集体性质。我们的结果表明,这两种情况之间的转折点是分子之间的量子力学相互作用:当它们的波函数分布和它们之间的库仑相互作用在所采用的理论方案中被明确描述时,可以捕获光学跃迁的激子特征。仅考虑光活化分子与其环境之间静电耦合的半经典模型无法再现这些效应。这项工作的结果从理论和实验的角度对有机半导体的激发有了更深入的了解。
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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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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