Photochemical Control of Exciton Superradiance in Light-Harvesting Nanotubes
Year: 2018
Authors: Doria S., Sinclair TS., Klein ND., Bennett DIG., Chuang C., Freyria FS., Steiner CP., Foggi P., Nelson KA., Cao JS., Aspuru-Guzik A., Lloyd S., Caram JR., Bawendi MG.
Autors Affiliation: MIT, Dept Chem, Cambridge, MA 02139 USA; MIT, Dept Mech Engn, Cambridge, MA 02139 USA; Univ Firenze, European Lab Non Linear Spect LENS, Via Nello Carrara 1, I-50019 Florence, Italy; Univ Firenze, Dipartimento Chim Ugo Schiff, Via Lastruccia 3-13, I-50019 Florence, Italy; Harvard Univ, Dept Chem & Chem Biol, 12 Oxford St, Cambridge, MA 02138 USA; CNR, INO, Largo Fermi 6, I-50125 Florence, Italy; Univ Perugia, Dipartimento Chim Biol & Biotecnol, Via Elce Sotto 8, I-06123 Perugia, Italy; Univ Calif Los Angeles, Dept Chem & Biochem, Los Angeles, CA 90095 USA.
Abstract: Photosynthetic antennae and organic electronic materials use topological, structural, and molecular control of delocalized excitons to enhance and direct energy transfer. Interactions between the transition dipoles of individual chromophore units allow for coherent delocalization across multiple molecular sites. This delocalization, for specific geometries, greatly enhances the transition dipole moment of the lowest energy excitonic state relative to the chromophore and increases its radiative rate, a phenomenon known as superradiance. In this study, we show that ordered, self-assembled light-harvesting nanotubes (LHNs) display excitation-induced photobrightening and photo-darkening. These changes in quantum yield arise due to changes in energetic disorder, which in turn increases/decreases excitonic superradiance. Through a combination of experiment and modeling, we show that intense illumination induces different types of chemical change in LHNs that reproducibly alter absorption and fluorescence properties, indicating control over excitonic delocalization. We also show that changes in spectral width and shift can be sensitive measures of system dimensionality, illustrating the mixed 1-2D nature of LHN excitons. Our results demonstrate a path forward for mastery of energetic disorder in an excitonic antenna, with implications for fundamental studies of coherent energy transport.
Journal/Review: ACS NANO
Volume: 12 (5) Pages from: 4556 to: 4564
More Information: J.R.C. and T.S. were funded by the Department of Energy (DOE) through the DOE Center for Excitonics (an Energy Frontiers Research Center funded by the U.S. DOE, Office of Science, Office of Basic Energy Sciences, through grant no. DE-527 SC0001088). F.S.F. was supported by Eni SpA under the Eni- MIT Alliance Solar Frontiers Center. N.D.K. was funded by the DOE Office of Science, Basic Energy Sciences through grant no. DE-FG02-07ER46454. S.D., T.S.S., N.D.K, F.S.F, C.P.S., and J.RC. performed the experiments. T.S.S., D.I.G.B., C.C., performed simulations. All authors contributed to data interpretation and writing the manuscript. We would also like to acknowledge the reviewers for helpful feedback and ideas for additional experiments.KeyWords: Antennas; Chromophores; Energy transfer; Nanotubes; Radiation; Superradiance; Yarn, Direct energy transfers; Excitonic delocalization; Fluorescence properties; Fundamental studies; Molecular controls; Organic electronic materials; Photochemical control; Transition dipole moments, ExcitonsDOI: 10.1021/acsnano.8b00911ImpactFactor: 13.903Citations: 38data from “WEB OF SCIENCE” (of Thomson Reuters) are update at: 2024-12-08References taken from IsiWeb of Knowledge: (subscribers only)Connecting to view paper tab on IsiWeb: Click hereConnecting to view citations from IsiWeb: Click here