Vibronic coupling in quantum wires: Applications to polydiacetylene

Yamagata, H.; Spano, Frank C.

doi:10.1063/1.3617432

Cited by 61 publications

(126 citation statements)

References 44 publications

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“…In Ref. 31 it was also shown that the 0-0/0-1 line strength ratio in the PL spectrum of the single chain increases with intrachain exciton bandwidth -as expected for a J-aggregate -while the 0-2/0-1 ratio decreases. The behavior can be crudely described as a decrease in the effective single chain Huang-Rhys factor with increasing exciton coupling, although the relative intensities are generally not Poissonian.…”

Section: Results and Analysismentioning

confidence: 99%

“…Hence, within a π-stack of such chains, the exciton is delocalized over two dimensions; along the polymer backbone as well as along the stacking axis. Because the Wannier-Mott excitons in one dimension lead to J-aggregate photophysics, 31 the aggregate can be understood as J-like along the backbone dimension and H-like along the stacking direction, allowing for interesting hybrid H-J photophysical properties. If disorder is absent, as was the case treated in Ref.…”

Section: B Relationship Between Exciton Signatures and Solid-state Mmentioning

confidence: 99%

“…A compelling example of this limit is provided by isolated, extended chains of red-phase polydiacetylene derivatives, 27 which show ultra narrow photoluminescence linewidths and superradiance [28][29][30] characteristic of J-aggregates at low temperature. 31 The work by Niles et al 1 therefore demonstrates that in regioregular P3HT films, there is a competition between J-like (intrachain) and H-like (interchain) excitonic coupling. 32 This interplay between through-bond and through-space excitonic coupling of adjacent chromophores must be strongly influenced by energetic disorder and hence the macromolecular conformation and packing in the solid state.…”

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confidence: 99%

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Two-dimensional spatial coherence of excitons in semicrystalline polymeric semiconductors: Effect of molecular weight

et al. 2013

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The electronic properties of macromolecular semiconductor thin films depend profoundly on their solid-state microstructure, which in turn is governed, among other things, by the processing conditions selected and the polymer's chemical nature and molecular weight. Specifically, lowmolecular-weight materials form crystalline domains of cofacially π-stacked molecules, while the usually entangled nature of higher molecular-weight polymers leads to microstructures comprised of molecularly ordered crystallites interconnected by amorphous regions. Here, we examine the interplay between extended exciton states delocalized along the polymer backbones and across polymer chains within the π-stack, depending on the structural development with molecular weight.Such two-dimensional excitations can be considered as Frenkel excitons in the limit of weak intersite coupling. We combine optical spectroscopies, thermal probes, and theoretical modeling, focusing on neat poly(3-hexylthiophene) (P3HT) -one of the most extensively studied polymer semiconductors -of weight-average molecular weight (M w ) of 3-450 kg/mol. In thin-film structures of high-molecular-weight materials (M w > 50 kg/mol), a balance of intramolecular and intermolecular excitonic coupling results in high exciton coherence lengths along chains (~4 thiophene units), with interchain coherence limited to ~2.5 chains. In contrast, for structures of low-M w P3HT (<40 kg/mol), the interchain exciton coherence is dominant (~20% higher than in architectures formed by high-molecular-weight materials). In addition, the spatial coherence within the chain is significantly reduced (by nearly 30%). These observations give valuable structural information; they suggest that the macromolecules in aggregated regions of high-molecular-weight P3HT adopt a more planar conformation compared to low-molecular-weight materials. This results in the observed increase in intrachain exciton coherence. In contrast, shorter chains seem to lead to torsionally more disordered architectures. A rigorous, fundamental description of primary photoexcitations in π-conjugated polymers is hence developed: two-dimensional excitons are defined by the chain-length dependent molecular arrangement and interconnectivity of the conjugated macromolecules, leading to interplay between intramolecular and intermolecular spatial coherence.

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Section: Results and Analysismentioning

confidence: 99%

Section: B Relationship Between Exciton Signatures and Solid-state Mmentioning

confidence: 99%

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confidence: 99%

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Two-dimensional spatial coherence of excitons in semicrystalline polymeric semiconductors: Effect of molecular weight

et al. 2013

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“…As well as modifying spectral band progressions, vibronic coupling can localize excitation or charge. The manifestation of vibronic coupling in spectra of molecular aggregates can therefore be used to measure exciton delocalization by relating the mean delocalization length of excitons to the ratio of the electronic photoluminescence band intensity (I 0-0 ) and the first vibronic band (I 0-1 ) 50,51 . Analysis of the photoluminescence ratio reveals the extraordinary coherent delocalization of the exciton along disorder-free polydiacetyelene chains 50,52 (Fig.…”

Section: Measuring and Assessing Coherencementioning

confidence: 99%

Using coherence to enhance function in chemical and biophysical systems

Scholes

Fleming

Chen

et al. 2017

Nature

536

550

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“…demonstrated the idea experimentally by utilizing time-resolved PL to monitor subpicosecond exciton localization in perylene diimide aggregates [33]. The PL ratio has also been used to justify the ultra-large coherence lengths measured in practically defect-free polyacetylene chains, also referred to as quantum wires [34,35]; to determine N coh in polyacenes crystals [31,36] and dinaptho-thieno-thiophene (DNTT) crystals [37]; and to monitor coherence in a phosphorescent Pt-containing polymer. [38] In this work we extend our analysis of the PL ratio to include aggregates with significant intermolecular charge transfer.…”

Section: Introductionmentioning

confidence: 98%

Determining the spatial coherence of excitons from the photoluminescence spectrum in charge-transfer J-aggregates

Hestand

Spano

2016

Chemical Physics

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The importance of spatial coherence in energy and charge transfer processes in biological systems and photovoltaic devices has been hotly debated over the past several years. While larger spatial coherences are thought to benefit transport, a clear correlation has yet to be established, partly because a simple and accurate measure of the coherence length has, for the most part, remained elusive. Previously, it was shown that the number of coherently connected chromophores, Coh N , can be determined directly from the ratio ( R S ) of the 0-0 and 0-1 vibronic line strengths in the photoluminescence (PL) spectrum. The relation,where 2 0 λ is the associated Huang-Rhys parameter, was derived in the Frenkel exciton limit. Here, it is shown that R S remains a highly accurate measure of coherence for systems characterized by significant charge transfer interactions (e.g. conjugated π-stacked systems). The only requirement is that the exciton band curvature must be positive, as in a J-aggregate.

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Vibronic coupling in quantum wires: Applications to polydiacetylene

Cited by 61 publications

References 44 publications

Two-dimensional spatial coherence of excitons in semicrystalline polymeric semiconductors: Effect of molecular weight

Two-dimensional spatial coherence of excitons in semicrystalline polymeric semiconductors: Effect of molecular weight

Using coherence to enhance function in chemical and biophysical systems

Determining the spatial coherence of excitons from the photoluminescence spectrum in charge-transfer J-aggregates

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