Issue 72, 2021

Synthesis and properties of a nanographene-embedded conjugated macrocyclic nanoring via the Scholl reaction

Abstract

Direct π-extension by the Scholl reaction for solution-based growth of armchair edges in curved macrocyclic hydrocarbon nanostructures is a great challenge. To date, several attempts at direct π-extension of small highly strained macrocycles have failed. Herein, we report a fixed two-bond approach for direct functionalization of small strained macrocyclic nanorings. The reaction occurs selectively to produce large π-extended molecular crowns with high yields. The design of these precursors features two peripheral C–C bonds that are readily incorporated into the extended aromatic moiety to overcome strain-induced side reactions, such as 1,2-phenyl shift. The crown-shaped macrocycle 10 showed a significant redshift (∼100 nm for absorption) compared with its precursor. This synthesis strategy could pave the way towards the π-extension of strained conjugated macrocycles and their potential applications in electron-transport devices.

Graphical abstract: Synthesis and properties of a nanographene-embedded conjugated macrocyclic nanoring via the Scholl reaction

Supplementary files

Article information

Article type
Communication
Submitted
24 Jun 2021
Accepted
05 Aug 2021
First published
07 Aug 2021

Chem. Commun., 2021,57, 9104-9107

Synthesis and properties of a nanographene-embedded conjugated macrocyclic nanoring via the Scholl reaction

S. Wang, X. Li, G. Zhuang, M. Chen, P. Huang, S. Yang and P. Du, Chem. Commun., 2021, 57, 9104 DOI: 10.1039/D1CC03374C

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