Long-range energy transport in single supramolecular nanofibres at room temperature

Haedler, Andreas T.; Kreger, Klaus; Issac, Abey; Wittmann, Bernd K.; Kivala, Milan; Hammer, Natalie; Köhler, Jürgen; Schmidt, Hans‐Werner; Hildner, Richard

doi:10.1038/nature14570

Cited by 295 publications

(343 citation statements)

References 32 publications

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“…4 Recent studies, however, have shown that an efficient singlet exciton migration can occur in highly ordered supramolecular materials. [6][7][8] In particular, Sung et al. have shown by ultrafast transient fluorescence spectroscopy that in helical π-stacks of perylene bisimides delocalized excitons are initially formed and move coherently along the chain in tens of femtoseconds prior to the excimer formation.…”

Section: Introductionmentioning

confidence: 99%

“…6 Haedler et al have demonstrated that one-dimensional self-assembled nanofibers, based on carbonylbridged triarylamine building blocks, are able to efficiently transport singlet excitons over more than 4 μm at room temperature by means of a predominantly coherent mechanism. 7 Heechul et al have obtained a tunable light-harvesting material, based on a selfassembled chromophore network controlled by a genetically-engineered virus template, which has exhibited enhanced exciton transport via a partially coherent regime. 8 These recent examples clearly highlight the growing interest for obtaining controllable molecular materials for potential nanophotonic and quantum information applications where excitons move beyond the incoherent transport regime.…”

Section: Introductionmentioning

confidence: 99%

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Exciton Dynamics in Phthalocyanine Molecular Crystals

2016

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In this paper, the exciton transport properties of an octa(butyl)-substituted metal-free phthalocyanine (H2-OBPc) molecular crystal have been explored by means of a combined computational (molecular dynamics and electronic structure calculations) and theoretical (model Hamiltonian) approximation. The excitonic couplings in phthalocyanines, where multiple quasi-degenerate excited states are present in the isolated chromophore, are computed with a multistate diabatization scheme which is able to capture both short-and long-range excitonic coupling effects. Thermal motions in phthalocyanine molecular crystals at room temperature cause substantial fluctuation of the excitonic couplings between neighboring molecules (dynamic disorder). The average values of the excitonic couplings are found to be not much smaller than the reorganization energy for the excitation energy transfer and the commonly assumed incoherent regime for this class of materials cannot be invoked. A simple but realistic model Hamiltonian is proposed to study the exciton dynamics in phthalocyanine molecular crystals or aggregates beyond the incoherent regime.2

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Exciton Dynamics in Phthalocyanine Molecular Crystals

2016

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“…Not only can nanostructure morphology be controlled through judicious molecular design, 4 but it is also well-established that chromophore arrays can facilitate manybody interactions, such as resonant energy transfer, making them attractive candidates for artificial photosynthesis. 5 However, the majority of photocatalysis investigations to date that involved organic chromophores were done with the molecules fully dissolved in solution. 6−8 In order to move forward with designing artificial systems based on chromophore arrays that can be considered photocatalytic materials, a detailed understanding of how intermolecular coupling modes and environmental effects impact their performance is required.…”

Section: Introductionmentioning

confidence: 99%

Extended-Charge-Transfer Excitons in Crystalline Supramolecular Photocatalytic Scaffolds

Hestand

Kazantsev²,

Weingarten³

et al. 2016

J. Am. Chem. Soc.

163

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Coupling among chromophores in molecular assemblies is responsible for phenomena such as resonant energy transfer and intermolecular charge transfer. These processes are central to the fields of organic photovoltaics and photocatalysis, where it is necessary to funnel energy or charge to specific regions within the system. As such, a fundamental understanding of these transport processes is essential for developing new materials for photovoltaic and photocatalytic applications. Recently, photocatalytic systems based on photosensitizing perylene monomimide (PMI) chromophore amphiphiles were found to show variation in hydrogen gas (H 2 ) production as a function of nanostructure crystallinity. The 2D crystalline systems form in aqueous electrolyte solution, which provides a high dielectric environment where the Coulomb potential between charges is mitigated. This results in relatively weakly bound excitons that are ideal for reducing protons. In order to understand how variations in crystalline structure affect H 2 generation, two representative PMI systems are investigated theoretically using a modified Holstein Hamiltonian. The Hamiltonian includes both molecular Frenkel excitations (FE) and charge-transfer excitations (CTE) coupled nonadiabatically to local intramolecular vibrations. Signatures of FE/CTE mixing and the extent of electron/hole separation are identified in the optical absorption spectrum and are found to correlate strongly to the observed H 2 production rates. The absorption spectral signatures are found to sensitively depend on the relative phase between the electron and hole transfer integrals, as well as the diabatic energy difference between the Frenkel and CT exciton bands. Our analysis provides design rules for artificial photosynthetic systems based on organic chromophore arrays.

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“…Quasi-particles with such tunnelling properties also arise in experiments probing excitonic energy transfer in molecular crystals [49], molecular aggregates [50], photo-sythetic complexes [51][52][53][54][55][56][57], artificial light-harvesting materials [58], and ensembles of Rydberg atoms [32,59]. The long-range tunnelling amplitudes are known to have a significant effect on the dynamical properties of quantum particles in lattice po-tentials [60][61][62][63][64][65][66]. In particular, the long-range tunnelling events may substantially decrease the mixing or hitting times of the corresponding quantum walkers.…”

Section: Introductionmentioning

confidence: 99%

Effects of long-range hopping and interactions on quantum walks in ordered and disordered lattices

Chattaraj

Krems

2016

Phys. Rev. A

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We study the effects of long-range hopping and long-range inter-particle interactions on quantum walk of hard-core bosons in ideal and disordered one-dimensional lattices. We find that the range of hopping has a much more significant effect on the particle correlation dynamics than the range of interactions. We illustrate that long-range hopping makes the correlation diagrams asymmetric with respect to the sign of the interaction and examine the relative role of repulsive and attractive interactions on the dynamics of scattering by isolated impurities and Anderson localization in disordered lattices. We show that weakly repulsive interactions increase the probability of tunnelling through isolated impurities and decrease the localization.

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Long-range energy transport in single supramolecular nanofibres at room temperature

Cited by 295 publications

References 32 publications

Exciton Dynamics in Phthalocyanine Molecular Crystals

Exciton Dynamics in Phthalocyanine Molecular Crystals

Extended-Charge-Transfer Excitons in Crystalline Supramolecular Photocatalytic Scaffolds

Effects of long-range hopping and interactions on quantum walks in ordered and disordered lattices

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