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Panchromatic light-harvesting antenna by supramolecular exciton band engineering for heteromeric dye foldamer

Alexander Schulz, Rebecca Fröhlich, Ajay Jayachandran, Franziska Schneider, Matthias Stolte, Tobias Brixner, Frank Würthner

2024Chem12 citationsDOIOpen Access PDF

Abstract

Natural photosystems accomplish panchromatic light absorption by different chromophores that are non-covalently embedded in protein matrices and mostly lack close dye-dye interactions. In this article, we introduce a light-harvesting (LH) system established by four different merocyanine dyes that are co-facially stacked by dipole-dipole interactions and a peptide-like backbone in a folded heteromer architecture to afford a panchromatic absorption band consisting of several strongly coupled exciton states. This exciton manifold allows for ultrafast and efficient energy transport in the artificial antenna. Furthermore, due to the tight stacking of the dyes in their folded state, non-radiative processes are slowed down, thereby increasing the lifetime of the excited state and the fluorescence quantum yield from <3% for the individual dyes up to 38% for the folda-heteromer. Together with the panchromatic absorption, this leads to a substantial improvement of the fluorescence brightness upon broadband excitation in comparison with its constituent chromophores.

Topics & Concepts

ChromophorePhotochemistryExcitonFluorescenceQuantum yieldSupramolecular chemistryPeryleneMaterials scienceExcited stateAbsorption (acoustics)ChemistryPhysicsOpticsCrystallographyAtomic physicsQuantum mechanicsCrystal structureComposite materialPhotoreceptor and optogenetics researchMolecular Junctions and NanostructuresLuminescence and Fluorescent Materials
Panchromatic light-harvesting antenna by supramolecular exciton band engineering for heteromeric dye foldamer | Litcius