CAS Center for Excellence in Nanoscience, CAS Key Laboratory of Nanosystem and Hierarchical Fabrication, National Center for Nanoscience and Technology (NCNST), No.11, ZhongGuanCun BeiYiTiao, Beijing 100190, P.R. China.
University of Chinese Academy of Sciences, Beijing 100049, P. R. China.
Acc Chem Res. 2020 Jul 21;53(7):1279-1292. doi: 10.1021/acs.accounts.0c00112. Epub 2020 Jul 10.
Chiral functional materials with circularly polarized luminescence (CPL) have risen rapidly in recent years because of their fascinating characteristics and potential applications in various research fields. CPL refers to the differential spontaneous emission of left (L)- and right (R)-handed circularly polarized light upon photon or electron excitation. Generally, an outstanding CPL-active material needs to possess a high luminescence dissymmetry factor () (defined as 2( - )/( + ) where is the emission intensity), which is between -2 and +2. Although the exciting development in CPL-active materials was achieved, the modulation of CPL signs is still a challenge. For small organic systems, a relatively small value, one of the key parameters of CPL, limits their practical applications. Searching for efficient approaches for amplifying is important. Therefore, over the past decades, besides optimizing the structure of small molecules, many other strategies to obtain efficient CPL-active materials have been developed. For instance, self-assembly has been well demonstrated as an effective approach to amplify the supramolecular chirality as well as the values. On the other hand, chiral liquid crystals (CLCs), which are capable of selective reflection of left- and right-handed circularly polarized light, also to serve as a host matrix for endowing guest emitters with CPL activity and high values. However, self-assembly focuses on modulating the conformation and spatial arrangement of chiral emitters. And the CPL of a luminophore-doped CLC matrix depends on the helix pitch and band gap positions. Lately, novel photophysical approaches to modulate CPL signs have gradually emerged.In this Account, we discuss the recent progress of excited-state-regulation involved CPL-active materials. The emergence, amplification, and inversion of CPL can be adjusted through regulation of the excited state of chiral emitters. For example, Förster resonance energy transfer (FRET) can amplify the values of chiral energy acceptors in chiral supramolecular assemblies. By combining the concepts of photon upconversion and CPL, high-energy upconverted circularly polarized emission was achieved under excitation of low-energy light, accompanied by an amplified . In addition, the organic systems with unpaired electrons, i.e., charge transfer (CT) system and open-shell π-radical, show favorable CPL properties, which can be flexibly tuned with an applied magnetic field. It should be noted that these photophysical process are associated with the excited state of chiral emitters. So far, while the main focus is on the regulation of the molecular and supramolecular nanostructures, direct regulation of the excited state of the chiral system will serve as a new platform to understand and regulate the CPL activity and will be helpful to develop smart chiroptical materials.
具有圆偏振发光 (CPL) 的手性功能材料近年来发展迅速,因为它们具有迷人的特性和在各个研究领域的潜在应用。CPL 是指在光子或电子激发下,左 (L)-和右 (R)-手性圆偏振光的自发发射差异。通常,一个出色的 CPL 活性材料需要具有高发光不对称因子 ()(定义为 2( - )/( + ),其中 是发射强度),其值介于 -2 和 +2 之间。尽管 CPL 活性材料取得了令人瞩目的发展,但 CPL 符号的调制仍然是一个挑战。对于小分子系统,CPL 的一个关键参数 值相对较小,限制了它们的实际应用。寻找有效的方法来放大 值很重要。因此,在过去的几十年中,除了优化小分子的结构外,还开发了许多其他策略来获得高效的 CPL 活性材料。例如,自组装已被证明是放大超分子手性以及 值的有效方法。另一方面,手性液晶 (CLC) 能够选择性地反射左旋和右旋圆偏振光,也可用作赋予客体发光体 CPL 活性和高 值的主体基质。然而,自组装侧重于调节手性发射器的构象和空间排列。并且掺杂发光体的 CLC 基质的 CPL 取决于螺旋节距和能带隙位置。最近,出现了调节 CPL 符号的新光物理方法。在本报告中,我们讨论了涉及 CPL 活性材料的激发态调控的最新进展。CPL 的出现、放大和反转可以通过调节手性发射器的激发态来调节。例如,在手性超分子组装体中,Förster 共振能量转移 (FRET) 可以放大手性能量受体的 值。通过结合上转换和 CPL 的概念,在低能光激发下实现了高能上转换圆偏振发射,同时伴随着放大的 。此外,具有未配对电子的有机体系,即电荷转移 (CT) 体系和开壳 π-自由基,表现出有利的 CPL 性质,可通过施加磁场灵活调节。应该注意的是,这些光物理过程与手性发射器的激发态有关。到目前为止,虽然主要关注的是分子和超分子纳米结构的调节,但手性系统的激发态的直接调节将作为一个新的平台来理解和调节 CPL 活性,并有助于开发智能手性光学材料。
