One-Pot Synthesis of Stable Poly([c2]Daisy–chain Rotaxane) with Pseudo-Stopper via Metathesis Reaction and Thiol-Ene Reaction

Reactions Pub Date : 2023-08-23 DOI:10.3390/reactions4030027
Risako Kamoto, K. Onimura, K. Yamabuki
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引用次数: 0

Abstract

Rotaxanes, known as supramolecular compounds, are expected to find applications in functional materials due to their high degree of freedom. However, their synthesis requires multistep reactions, and there is a demand for more convenient methods to synthesize rotaxane materials. In this study, we aimed to investigate a simpler method for synthesizing highly functional rotaxane materials and explore the diversity of molecular designs. To achieve this, we successfully synthesized a host–guest conjugated compound that incorporates both crown ether as the host unit and secondary ammonium salts as the guest unit within the same molecule. Subsequently, the metathesis reaction of these compounds, which construct [c2]daisy-chain rotaxanes, enabled the one-pot synthesis of a topological polymer called “poly([c2]daisy-chain rotaxane)” with a pseudo-stopper. This methodology achieves the stabilization and polymerization of rotaxanes simultaneously, contributing to the easy materialization of rotaxanes. Furthermore, the thiol-ene reaction achieved the extension of the distance between rotaxane units and provided a useful approach to diversify the design of functional materials with rotaxane structures.
通过复分解反应和巯基烯反应一锅合成具有伪塞的稳定聚([c2]菊链轮烷)
轮烷被称为超分子化合物,由于其高度的自由度,有望在功能材料中找到应用。然而,它们的合成需要多步反应,需要更方便的方法来合成轮烷材料。在本研究中,我们旨在探索一种更简单的方法来合成高功能轮烷材料,并探索分子设计的多样性。为了实现这一目标,我们成功地合成了一种主客体共轭化合物,该化合物在同一分子内将冠醚作为宿主单位和仲铵盐作为客体单位。随后,这些化合物的复合反应,构建了[c2]雏菊链轮烷,使得一锅合成一种具有伪塞的拓扑聚合物“聚([c2]雏菊链轮烷)”成为可能。该方法同时实现了轮烷的稳定和聚合,有利于轮烷的物化。此外,巯基烯反应实现了轮烷单元之间距离的延长,为具有轮烷结构的功能材料的多样化设计提供了有益的途径。
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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CiteScore
2.70
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0.00%
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