Induced Axial Chirality by a Tight Belt: Naphthalene Chromophores Fixed in a 2,5-substituted Cofacial -phenylene-ethynylene Framework

Overview

Journal J Mater Chem C Mater

Publisher Royal Society of Chemistry

Date 2021 Dec 16

PMID 34912562

Citations 2

Authors

Eric Sidler

Juraj Malincik

Alessandro Prescimone

Marcel Mayor

Affiliations

Soon will be listed here.

Abstract

We report the design of a synthetically easy accessible axial chirality-inducing framework for a chromophore of choice. The scaffold consists of two basic -phenylene-ethynylene backbones separated by laterally placed corner units. Substitution with an inherently achiral chromophore at the 2 and 5 positions of the central phenylene excitonically couples the chromophore associated transition and thereby results in chiroptical properties. Using 6-methoxynaphthalene as a model chromophore, we present the synthesis, structural analysis and spectroscopic investigation of the framework. The chiral framework was synthesized in three straightforward synthetic steps and fully characterized. The obtained racemic compounds were resolved using HPLC and assignment of the absolute configuration was performed using the exciton chirality method, crystallography and DFT calculations. This simple yet potent framework might prove useful to enrich the structural diversity of chiral materials.

Citing Articles

A cross-shaped organic framework: a multi-functional template arranging chromophores.

Kroonen C, DAddio A, Prescimone A, Haussinger D, Mayor M Org Chem Front. 2024; 12(5):1399-1408.

PMID: 39722802 PMC: 11664314. DOI: 10.1039/d4qo01808g.

A Cycloparaphenylene Acetylene as Potential Precursor for an Armchair Carbon Nanotube.

Sidler E, Rothlisberger R, Mayor M Chemistry. 2024; 30(69):e202403084.

PMID: 39325698 PMC: 11632400. DOI: 10.1002/chem.202403084.

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