全有机和混合多组分系统中基于敏化三重态-三重态湮灭的光子上转换

IF 6.1 Q2 CHEMISTRY, PHYSICAL
A. Ronchi, A. Monguzzi
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引用次数: 4

摘要

在最近的15 多年来,由于人们对三重态机制(如单重态裂变、热激活延迟荧光和系统间交叉增强磷光)的重新关注,对有机共轭体系的关注经历了显著的增长。通过敏化三重态-三重态湮灭(sTTA)实现的光子上转换能够将低能光子转换为高能光子,并已在多组分系统中被提出作为非相干光子的有效管理策略。这种机制利用发射极部分的两个光学暗三重态的湮灭来产生高能光子。湮灭三重态通过光采集器(通常是共轭分子或纳米晶体)的Dexter能量转移进行敏化,因此sTTA上转换通常在双组分系统中进行。在低激发强度下观察到的高产率刺激了该领域蓬勃发展的研究,从而开发了一大家族的全有机和混合sTTA多组分上变频器。在这里,根据文献中报道的结果,我们比较了这两个系统家族在sTTA上转换主要优点方面的演变,强调了两种方法的优势和劣势。所提供的数据也从该领域未来发展的角度进行了讨论,指出了sTTA上转换过程的技术使用仍然面临的挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Sensitized triplet–triplet annihilation based photon upconversion in full organic and hybrid multicomponent systems
In the last 15 years, the attention dedicated to organic conjugated systems experienced outstanding growth because of the renewed interest in mechanisms involving triplet states such as singlet fission, thermally activated delayed fluorescence, and intersystem crossing enhanced phosphorescence. Photon upconversion via sensitized triplet–triplet annihilation ( sTTA) enables the conversion of low-energy photons into high-energy ones, and it has been proposed in multicomponent systems as an efficient managing strategy of non-coherent photons. This mechanism exploits the annihilation of two optically dark triplet states of emitter moieties to produce high-energy photons. The annihilating triplets are sensitized through Dexter energy transfer by a light-harvester, typically a conjugated molecule or a nanocrystal, so sTTA upconversion is usually performed in bi-component systems. The high yield observed at low excitation intensities stimulated thriving research in the field, leading to the development of a large family of fully organic and hybrid sTTA multicomponent upconverters. Here, we compare the evolution of these two families of systems with respect to the sTTA upconversion main figures of merit, highlighting the strengths and weaknesses of both approaches, according to the results reported in the literature. The data presented are also discussed in the perspective of future developments in the field, pointing out the challenges that are still to be faced for the technological use of the sTTA upconversion process.
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