Towards Unimolecular Luminescent Solar Concentrators: Bodipy‐Based Dendritic Energy‐Transfer Cascade with Panchromatic Absorption and Monochromatized Emission

Bozdemir, Ö. Altan; Erbaş-Çakmak, Sündüs; Ekiz, Okan Öner; Dâna, Aykutlu; Akkaya, Engin U.

doi:10.1002/anie.201104846

Cited by 200 publications

(135 citation statements)

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“…3e,10 Recently, in a dendritic light harvester designed for solar concentration, we have experimentally demonstrated that, in such flexible lightharvesting ensembles, simple calculations based on lifetime changes are not applicable. 11 Deviation between energy transfer efficiencies calculated by quantum yield/lifetime changes and calculations based on excitation spectra can be very large. This is due to disregarding any emergent quenching process in the covalent assembly and treating all nonradiative processes involving the donor as energy transfer.…”

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confidence: 99%

Tetrastyryl-BODIPY-Based Dendritic Light Harvester and Estimation of Energy Transfer Efficiency

et al. 2012

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Versatile BODIPY dyes can be transformed into bright near-IR-emitting fluorophores by quadruple styryl substitutions. When clickable functionalities on the styryl moieties are inserted, an efficient synthesis of a light harvester is possible. In addition, clear spectral evidence is presented showing that, in dendritic light harvesters, calculations commonly based on quantum yield or emission lifetime changes of the donor are bound to yield large overestimations of energy transfer efficiency.Efficient harvesting of solar radiation requires judiciously designed absorbers. Considering the fact that it would be difficult to have a single molecule with strong absorptions in the entire visible spectrum and near-IR (perfect black dye), it makes more sense to seek multichromophoric dye ensembles. Different chromophoric units can be brought together either by covalent bonds or by noncovalent interactions. In either case, excitation energy transfer (EET) from the donor chromophores (shorter wavelength absorption) to the acceptor (longer wavelength absorbing core) module is expected. The efficiency of energy transfer from the antenna chromophores to the central core is very important. In such multichromophoric light harvesters, energy transfer can be either through-space 1 or through-bond. 2 Through-space energy transfer is also possible between two or more free chromophoric units. This kind of energy transfer has been thoroughly studied, and in fact, the F€ orster (throughspace) energy transfer model is built on the interaction of such transition dipole coupled chromophoric pairs. Three important parameters determine the efficiency of energy transfer: donorÀacceptor distance, relative orientations of the transition dipoles, and the spectral overlap between the relevant absorption and emission bands. In proteins, either utilizing endogenous fluorescence of tryptophan or using fluorescent labels, EET efficiency calculations based on quantum yield or lifetime changes have been successful, but proteins are large and flexible enough for orientation of the dipoles to be averaged, and typically, reference fluorophores are in the same microenvironment. This simplified energy transfer calculation approach was later carried out on covalently linked multichromophoric light harvesters. In these energy transfer cassettes, energy funnels, or dendritic light harvesters, energy transfer efficiency is calculated assuming that the original bimolecular model can be directly related to an energy transfer process in a

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Tetrastyryl-BODIPY-Based Dendritic Light Harvester and Estimation of Energy Transfer Efficiency

et al. 2012

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“…The variety of synthetic pathways to BODIPY-based fluorophores allows efficient preparation. The fluorescence properties of BODIPY were tunable by simple substitution at various positions of the difluoroboron dipyrromethene core [25][26][27]. DPA and its derivatives DPEA and TPEA, are well-known receptors for heavy-metal ions [28][29][30].…”

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A fluorometric paper-based sensor array for the discrimination of heavy-metal ions

Feng

Niu

et al. 2013

Talanta

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“…[3][4][5] Alongside stimuli-responsive optics,aparticularly heavily studied topic in contemporary chemistry is Fçrster resonance energy transfer (FRET), the through-space migration of energy from an excited donor to an acceptor molecule that subsequently emits this energy as light. [6,7] FRET plays an important role in energy harvesting systems,f or instance in collecting panchromatic light in an arrow waveband [8] or directing energy to specific reaction centers in the case of photosynthesis. [9] Artificial temperature-responsive FRET systems in supramolecular assemblies have been reported, in which aggregation of the donor and acceptor monomers takes place at lower temperatures resulting in FRET, [10][11][12] while at higher temperatures,e mission is blue-shifted as the thermal disruption of the co-assemblies results in spatial separation of the donor/acceptor pair, causing emission from the donor to be observable.…”

Section: Temperature-responsivel Uminescents Olar Concentrators:t Unimentioning

confidence: 99%

Temperature‐Responsive Luminescent Solar Concentrators: Tuning Energy Transfer in a Liquid Crystalline Matrix

et al. 2017

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Towards Unimolecular Luminescent Solar Concentrators: Bodipy‐Based Dendritic Energy‐Transfer Cascade with Panchromatic Absorption and Monochromatized Emission

Cited by 200 publications

References 67 publications

Tetrastyryl-BODIPY-Based Dendritic Light Harvester and Estimation of Energy Transfer Efficiency

Tetrastyryl-BODIPY-Based Dendritic Light Harvester and Estimation of Energy Transfer Efficiency

A fluorometric paper-based sensor array for the discrimination of heavy-metal ions

Temperature‐Responsive Luminescent Solar Concentrators: Tuning Energy Transfer in a Liquid Crystalline Matrix

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