Design Principles for 2-Dimensional Molecular Aggregates using Kasha’s Model: Tunable Photophysics in Near and Shortwave Infrared

Deshmukh, Arundhati; Koppel, Danielle; Chuang, Chern; Cadena, Danielle; Cao, Jianshu; Caram, Justin R.

doi:10.26434/chemrxiv.7699358.v4

Cited by 4 publications

(12 citation statements)

References 57 publications

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“…2D molecular aggregates can host H-, I-, and J-type excitonic coupling between their constituent molecules. 20,40,41,46 In both H-and I-type excitonic coupling, fluorescence is almost completely quenched, whereas J-type excitonic coupling leads to a radiative rate enhancement and an increased QY. 27 Therefore, it is necessary to tune the structures of the monomers to favor the formation of highly emissive J-aggregates over I-or H-aggregates.…”

Section: Characterization Of J-aggregates Of Cy3ub In Water-methanol ...mentioning

confidence: 99%

“…This type of absorption and emission behavior suggests J-type excitonic coupling, which results in temperature dependent linewidths. 20,46 There are homogenous and inhomogenous contributions to the linewidth, where the former contribution arises due to the exciton's interaction with the environment at timescales faster than the lifetime of the exciton.…”

Section: Characterization Of J-aggregates Of Cy3ub In Water-methanol ...mentioning

confidence: 99%

“…17 Many J-Aggregates emitting in the visible and NIR have QYs below 10%. [18][19][20] The low QY of J-Aggregates has been attributed to large homogenous and inhomogenous disorder, 12,21 charge-transfer states, 12 vibronic coupling and self-trapped excitons. [22][23][24] The type of nonradiative pathways dominant in a J-aggregate is different for different classes of chromophores.…”

Section: Introductionmentioning

confidence: 99%

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Designing Highly Luminescent Molecular Aggregates via Bottom-Up Nanoscale Engineering

et al. 2021

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Coupling of excitations between organic fluorophores in J-aggregates leads to coherent delocalization of excitons across multiple molecules, resulting in materials with high extinction coefficients, long-range exciton transport, and, in particular, short radiative lifetimes. Despite these favorable optical properties, uses of J-aggregates as high-speed light sources have been hindered by their low photoluminescence quantum yields. Here, we take a bottom-up approach to design a novel J-aggregate system with a large extinction coefficient, a high quantum yield and a short lifetime. To achieve this goal, we first select a J-aggregating cyanine chromophore and reduce its nonradiative pathways by rigidifying the backbone of the cyanine dye. The resulting conformationally-restrained cyanine dye exhibits strong absorbance at 530 nm and fluorescence at 550 nm with 90% quantum yield and 2.3 ns lifetime. We develop optimal conditions for the self-assembly of highly emissive J-aggregates. Cryogenic transmission electron microscopy (cryo-TEM) and dynamic light scattering (DLS) reveal micron-scale extended structures with 2D sheet-like morphology, indicating long-range structural order. These novel J-aggregates have a strong red-shifted absorption at 600 nm, resonant fluorescence with no Stokes shift, 50% quantum yield, and 220 ps lifetime at room temperature. We further stabilize these aggregates in a glassy sugar matrix and study their excitonic behavior using 2 temperature-dependent absorption and fluorescence spectroscopy. These temperaturedependent studies confirm J-type excitonic coupling and superradiance. Our results have implications for the development of a new generation of organic fluorophores that combine high speed, high quantum yield and solution processing.

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Section: Characterization Of J-aggregates Of Cy3ub In Water-methanol ...mentioning

confidence: 99%

Section: Characterization Of J-aggregates Of Cy3ub In Water-methanol ...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Designing Highly Luminescent Molecular Aggregates via Bottom-Up Nanoscale Engineering

et al. 2021

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“…(2) spontaneous emission of phonons and relaxation to the band edge. 20 The stimulated absorption/emission of phonons depends on the thermal occupation of phonons, and therefore, it is temperature dependent. In contrast, the spontaneous emission of phonons and relaxation to the band edge depends on the available density of states below the band edge, and is temperature independent.…”

Section: Characterization Of J-aggregates Of Cy3ub In Water-methanol Mixturesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Designing Highly Luminescent Molecular Aggregates via Bottom-Up Nanoscale Engineering

Barotov

Klein

Wang

et al. 2021

Preprint

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Coupling of excitations between organic fluorophores in J-aggregates leads to coherent delocalization of excitons across multiple molecules, resulting in materials with high extinction coefficients, long-range exciton transport, and, in particular, short radiative lifetimes. Despite these favorable optical properties, uses of J-aggregates as high-speed light sources have been hindered by their low photoluminescence quantum yields. Here, we take a bottom-up approach to design a novel J-aggregate system with a large extinction coefficient, a high quantum yield and a short lifetime. To achieve this goal, we first select a J-aggregating cyanine chromophore and reduce its nonradiative pathways by rigidifying the backbone of the cyanine dye. The resulting conformationally-restrained cyanine dye exhibits strong absorbance at 530 nm and fluorescence at 550 nm with 90% quantum yield and 2.3 ns lifetime. We develop optimal conditions for the self-assembly of highly emissive J-aggregates. Cryogenic transmission electron microscopy (cryo-TEM) and dynamic light scattering (DLS) reveal micron-scale extended structures with 2D sheet-like morphology, indicating long-range structural order. These novel J-aggregates have a strong red-shifted absorption at 600 nm, resonant fluorescence with no Stokes shift, 50% quantum yield, and 220 ps lifetime at room temperature. We further stabilize these aggregates in a glassy sugar matrix and study their excitonic behavior using temperature-dependent absorption and fluorescence spectroscopy. These temperature- dependent studies confirm J-type excitonic coupling and superradiance. Our results have implications for the development of a new generation of organic fluorophores that combine high speed, high quantum yield and solution processing.

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Exploring the design of superradiant J-aggregates from amphiphilic monomer units

et al. 2023

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Design Principles for 2-Dimensional Molecular Aggregates using Kasha’s Model: Tunable Photophysics in Near and Shortwave Infrared

Cited by 4 publications

References 57 publications

Designing Highly Luminescent Molecular Aggregates via Bottom-Up Nanoscale Engineering

Designing Highly Luminescent Molecular Aggregates via Bottom-Up Nanoscale Engineering

Designing Highly Luminescent Molecular Aggregates via Bottom-Up Nanoscale Engineering

Exploring the design of superradiant J-aggregates from amphiphilic monomer units

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