Macroscopic Change in Luminescent Color by Thermally Driven Sliding Motion in [3]Rotaxanes

Systematic investigation of rotaxane structures has revealed a rational design for thermally driven switching of their macroscopic properties. At low temperature, the luminophore is insulated by the macrocycles and displays monomer emission, whereas at high temperature, the luminophore is exposed ow...

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Veröffentlicht in:Chemistry : a European journal 2020-03, Vol.26 (15), p.3385-3389
Hauptverfasser: Inamori, Daiki, Masai, Hiroshi, Tamaki, Takashi, Terao, Jun
Format: Artikel
Sprache:eng
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Zusammenfassung:Systematic investigation of rotaxane structures has revealed a rational design for thermally driven switching of their macroscopic properties. At low temperature, the luminophore is insulated by the macrocycles and displays monomer emission, whereas at high temperature, the luminophore is exposed owing to a change in the macrocyclic location distribution and interacts with external molecules, affording a thermally driven luminescent color change with high reversibility and responsiveness. This macroscopic switching through efficient thermal sliding was made possible by appropriate tuning of both the macrocycle–luminophore interactions within the rotaxane and the coupling between the excited luminophore and external molecules in an exciplex. The ability to switch properties by a simple and clean thermal stimuli should expand the utilization of rotaxanes as components of thermally driven molecular systems. Slide on by: A rational design for thermally driven switching of macroscopic properties in rotaxanes is described. At low temperatures, the luminophore is insulated by macrocycles and displays monomer emission, whereas at high temperatures, the luminophore is exposed owing to a change in the location of the macrocyclic and interacts with external molecules.
ISSN:0947-6539
1521-3765
DOI:10.1002/chem.201905342