Chalcogenoviologen Enhanced Host–Guest Recognition

IF 9.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY CCS Chemistry Pub Date : 2024-10-25 DOI:10.31635/ccschem.024.202404812
Yuanning Feng, Xingang Zhao, Daniel A. Appleton, Han Han, Ryan M. Young, Wenqi Liu, Christopher K. Lee, Weixingyue Li, Bai-Tong Liu, Yong Wu, Chun Tang, Aspen X.-Y. Chen, Charlotte L. Stern, Dong Jun Kim, Michael R. Wasielewski, Yunyan Qiu, J. Fraser Stoddart
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Abstract

In the field of supramolecular chemistry, cyclophanes with novel properties are highly sought after since they can be tailored to fulfill specific tasks. In this article, we incorporate chalcogenoviologen-based units into tetracationic cyclophanes, resulting in enhanced host–guest recognition. The cyclophanes can be tuned through the addition of chalcogen bridging atoms—S, Se, and Te—which enhance their rigidity, regulate bond rotation and introduce additional steric bulk. Three cyclophanes containing chalcogen bridging atoms were synthesized and characterized in both the solution and solid states. The energy barriers for their interconversion between syn- and anti-conformations in solution were found to be correlated with chalcogen atom size. The photophysical properties of the cyclophanes are strongly dependent on the chalcogen atomic number, with intersystem crossing rates increasing from S to Se to Te. UV–vis-NIR spectroscopic and fluorometric titrations revealed that the chalcogenoviologen-based cyclophanes exhibit significantly stronger binding with electron-rich guests compared to the well-known, unsubstituted cyclobis(paraquat-p-phenylene). This enhancement in binding can be attributed to restricted rotation within the chalcogenoviologen units. This research provides insight into the rational design and tailored synthesis of cationic cyclophanes.

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Chalcogenoviologen 增强宿主-宿主识别能力
在超分子化学领域,具有新颖特性的环烷备受追捧,因为它们可以量身定制以完成特定任务。在本文中,我们在四阳离子环烷中加入了基于缩醛的单位,从而增强了主客体的识别能力。通过添加缩醛桥原子-S、Se 和 Te,可以对环烷进行调整,从而增强其刚性、调节键的旋转并引入额外的立体体积。我们合成了三种含有缩醛桥原子的环烷,并在溶液和固体状态下对其进行了表征。研究发现,它们在溶液中的同构型和反构型之间相互转换的能量障碍与查尔根原子的大小有关。环烷的光物理特性与查尔根原子序数密切相关,从 S 到 Se 再到 Te,系统间的交叉率不断增加。紫外-可见-近红外光谱仪和荧光滴定法显示,与众所周知的未取代环双(百草枯-对苯二甲酸)相比,基于链烯的环烷与富电子客体的结合力明显更强。这种结合力的增强可归因于链烯单元内旋转受限。这项研究为阳离子环烷的合理设计和定制合成提供了启示。
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来源期刊
CCS Chemistry
CCS Chemistry Chemistry-General Chemistry
CiteScore
13.60
自引率
13.40%
发文量
475
审稿时长
10 weeks
期刊介绍: CCS Chemistry, the flagship publication of the Chinese Chemical Society, stands as a leading international chemistry journal based in China. With a commitment to global outreach in both contributions and readership, the journal operates on a fully Open Access model, eliminating subscription fees for contributing authors. Issued monthly, all articles are published online promptly upon reaching final publishable form. Additionally, authors have the option to expedite the posting process through Immediate Online Accepted Article posting, making a PDF of their accepted article available online upon journal acceptance.
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