弥合H-和J-聚集体之间的差距:二维分子聚集体中激子能带结构的分类和超分子可调谐性

IF 6.1 Q2 CHEMISTRY, PHYSICAL Chemical physics reviews Pub Date : 2021-09-21 DOI:10.33774/chemrxiv-2021-ql3b7-v2
Arundhati Deshmukh, Niklas Geue, N. Bradbury, T. Atallah, Chern Chuang, Monica Pengshung, Jianshu Cao, Ellen M. Sletten, D. Neuhauser, Justin R. Caram
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引用次数: 9

摘要

与单体对应物相比,具有长程激子耦合的分子聚集体具有截然不同的光物理性质。根据一维系统的Kasha模型,正或负激子耦合导致单体的光谱发生蓝移或红移,分别标记为H和J聚集体。高维系统中的整体激子耦合要复杂得多,不能仅从其光谱位移进行简单分类。在这里,我们使用温度相关的峰移、热增宽和量子产率为扩展的2D聚集体提供了统一的分类。我们讨论了六个具有类J吸收光谱但量子产率和超辐射率变化相当剧烈的2D聚集体的例子。事实上,我们发现差异的根源是不同的激子带结构,其中亮态的能量低于单体,但仍远离带边缘。我们称之为“I-aggregate”。我们的结果提供了复杂激子行为的描述,而这些行为不能仅用Kasha模型来解释。此外,这种性质可以通过聚集体内的堆积几何形状来调节,从而提供用于控制它们的超分子途径。这将允许在光电子、光子学、激子能量转移和短波红外技术领域的应用中精确优化聚集体性质。
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Bridging the Gap between H- and J-Aggregates: Classification and Supramolecular Tunability for Excitonic Band Structures in 2-Dimensional Molecular Aggregates
Molecular aggregates with long-range excitonic couplings have drastically different photophysical properties compared to their monomer counterparts. From Kasha’s model for 1-dimensional systems, positive or negative excitonic couplings lead to blue or red shifted optical spectra with respect to the monomers, labelled H-and J-aggregates respectively. The overall excitonic couplings in higher dimensional systems are much more complicated and cannot be simply classified from their spectral shifts alone. Here, we provide a unified classification for extended 2D aggregates using temperature dependent peak shifts, thermal broadening and quantum yields. We discuss the examples of six 2D aggregates with J-like absorption spectra but quite drastic changes quantum yields and superradiance. We find the origin of the differences is, in fact, a different excitonic band structure where the bright state is lower energy than the monomer but still away from the band edge. We call this an ‘I-aggregate’. Our results provide a description of the complex excitonic behaviors that cannot be explained solely on Kasha’s model. Further, such properties can be tuned with the packing geometries within the aggregates providing supramolecular pathways for controlling them. This will allow for precise optimizations of aggregate properties in their applications across the areas of optoelectronics, photonics, excitonic energy transfer, and shortwave infrared technologies.
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