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Efficient Artificial Light-Harvesting System Based on Supramolecular Peptide Nanotubes in Water

Qiao Song, Sofia Goia, Jie Yang, Stephen C. L. Hall, Michael Staniforth, Vasilios G. Stavros, Sébastien Perrier

2020Journal of the American Chemical Society188 citationsDOIOpen Access PDF

Abstract

Artificial light-harvesting systems in aqueous media which mimic nature are of significant importance; however, they are often restrained by the solubility and the undesired aggregation-caused quenching effect of the hydrophobic chromophores. Here, we report a generalized strategy toward the construction of efficient artificial light-harvesting systems based on supramolecular peptide nanotubes in water. By molecularly aligning the hydrophobic chromophores along the nanotubes in a slipped manner, an artificial light-harvesting system with a two-step sequential Förster resonance energy transfer process is successfully fabricated, showing an energy transfer efficiency up to 95% and a remarkably high fluorescence quantum yield of 30%, along with high stability. Furthermore, the spectral emission could be continuously tuned from blue through green to orange, as well as outputted as a white light continuum with a fluorescence quantum yield of 29.9%. Our findings provide a versatile approach of designing efficient artificial light-harvesting systems and constructing highly emissive organic materials in aqueous media.

Topics & Concepts

ChromophoreQuantum yieldChemistrySupramolecular chemistryFluorescenceAqueous solutionArtificial photosynthesisQuenching (fluorescence)NanotechnologyPhotochemistryMoleculeOrganic chemistryMaterials sciencePhotocatalysisCatalysisQuantum mechanicsPhysicsLuminescence and Fluorescent MaterialsSupramolecular Self-Assembly in MaterialsPolydiacetylene-based materials and applications