Molecular Self‐Doping Controls Luminescence of Pure Organic Single Crystals

Parashchuk, Olga D.; Mannanov, Artur A.; Konstantinov, Vladislav G.; Dominskiy, Dmitry I.; Сурин, Н. М.; Борщев, О. В.; Ponomarenko, Sergei A.; Pshenichnikov, Maxim S.; Paraschuk, Dmitry Yu.

doi:10.1002/adfm.201800116

Cited by 42 publications

(81 citation statements)

References 39 publications

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“…The PLE spectrum measured at λ em = 493 nm corresponding to the 0–2 emission shows a broad band absorption at λ < 470 nm with a weak shoulder around 450 nm. It is known that the TPCO crystals include unintentional impurities, in particular, longer oligomer byproducts act as a doped acceptor which gives rise to red‐shifted emission based on Förster resonance energy transfer (FRET) . One may assign the weak absorption shoulder to such a self‐dopant; however, no red‐shifted band is visible in the fluorescence spectrum.…”

Section: Enhanced Raman Scattering From Single‐crystal Tpcosmentioning

confidence: 99%

Cooperative Behaviors in Amplified Emission from Single Microcrystals of Thiophene/Phenylene Co‐Oligomers toward Organic Polariton Laser

Yanagi

Sasaki

Yamashita

2019

Advanced Optical Materials

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After successful commercialization of organic light‐emitting diodes (OLEDs), organic semiconductor lasers have become a practical research target for versatile optoelectronic applications. Realization of electrically pumped lasing with molecular materials faces critical issues such as exciton quenching by injected carriers, nonradiative triplet states, and difficulties in introduction of resonators. One of potential routes to overcome them is to utilize polaritonic emission based on cooperative coupling of photons with excitons and/or phonons in molecular crystals. This report overviews cooperative behaviors observed in amplified emissions from single‐crystal thiophene/phenylene co‐oligomers (TPCOs) and discusses their expected potential toward organic polariton lasers. First, amplified emission accompanied with unusual time delay, spectral splitting, and fluence dependence of lasing threshold is presented, suggesting superfluorescence from macroscopically correlated molecular excitons, not based on the conventional stimulated emission process. Second, selectively enhanced Raman scattering under off‐resonant condition is shown, which is interpreted as a result of contribution of coherent vibrations in the TPCO crystals. Then, angle‐resolved spectroscopies demonstrate a stable existence of exciton polaritons at room temperature in microcavity devices with TPCO crystals. It is concluded that all those unique behaviors are ascribed to the TPCO excitons and vibrations having large oscillator strength under the uniaxially oriented molecular alignment.

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Section: Enhanced Raman Scattering From Single‐crystal Tpcosmentioning

confidence: 99%

Cooperative Behaviors in Amplified Emission from Single Microcrystals of Thiophene/Phenylene Co‐Oligomers toward Organic Polariton Laser

Yanagi

Sasaki

Yamashita

2019

Advanced Optical Materials

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“…The observed inverse temperature dependence of exciton transport rate is also an attribute of rigid molecular structures, which lead to lower torsional disorder in crystal. Opposite behavior showing temperature activated energy transport was previously observed in bifluorene and thiophene–phenylene co‐oligomer single crystals featuring similar J‐type molecular packing . Evidently, linkers between fragments enabling torsional degrees of freedom contributed to broad distribution of states evidenced by the featureless ground state absorption in the crystals.…”

Section: Resultsmentioning

confidence: 54%

Enhanced Energy Transfer in Doped Bifluorene Single Crystals: Prospects for Organic Lasers

Baronas

Kreiza

Mamada

et al. 2019

Advanced Optical Materials

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Organic single crystals with long‐range molecular order ensure enhanced carrier mobility and stability as well as emission outcoupling, which makes them attractive as gain medium for electrically pumped organic lasers. Unfortunately, effects of excitonic coupling introduce losses degrading optical performance in crystals, hence higher lasing thresholds are observed compared to amorphous films. Here, crystal doping strategy is investigated as a method to avoid pronounced reabsorption and annihilation losses associated with J‐type excitonic coupling, while taking advantage of enhanced exciton transport for efficient energy transfer. Bifluorene‐based derivatives linked with acetylene and ethylene rigid bridges are suitable as host and dopant system forming high‐quality crystals doped at various concentrations (0.5–11.0%). Enhanced exciton transport in host crystal mediates picosecond host–dopant energy transfer enabling 100% transfer efficiency at lower doping concentrations compared to amorphous films. Amplified spontaneous emission threshold of 1.9 µJ cm−2 in 3.5% doped crystal is enabled by minimized exciton annihilation and emission reabsorption losses at optimal doping concentration.

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“…By taking advantage of this host–guest system, molecular doping technique is employed in organic single‐crystalline semiconductors to combine high mobility and the enhanced light‐emitting properties. It allows to increase the photoluminescence (PL) internal quantum efficiency through suppressing luminescence quenching of the H ‐ aggregate ‐like molecular dipole–dipole interaction . Wang and co‐workers have prepared the tetracene‐ and pentacene‐doped oligo( p ‐phenylenevinylene) crystals which exhibit high luminescent efficiency and color‐tunable emission, and further elucidated their thermodynamics characteristics and charge transport properties .…”

mentioning

confidence: 99%

“…They also found that thiophene/phenylene co‐oligomer‐doped oligo( p ‐phenylenevinylene) crystals possess tunable light‐amplification characteristics with an extremely low‐threshold amplified spontaneous emission . Recently, Parashchuk and co‐workers even introduced a novel concept of self‐doping by the synthesis of byproduct in thiophene/phenylene co‐oligomer crystals which doubled the PL efficiency . In addition, research on steady‐state and time‐resolved fluorescence measurements indicated that Förster energy transfer is the dominant process in the doped crystals .…”

mentioning

confidence: 99%

“…However, the pace of understanding the doping mechanism of the basic stacking modes between host and guest molecules in organic single‐crystalline semiconductors has lagged far behind the rapid progress in research on their applications . It is generally believed that doping molecules are dispersed throughout the host crystal lattice by strong molecular interactions during crystal growth, and that their potential to replace the original host molecules in the crystal lattice is high.…”

mentioning

confidence: 99%

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Clarification of the Molecular Doping Mechanism in Organic Single‐Crystalline Semiconductors and their Application in Color‐Tunable Light‐Emitting Devices

et al. 2018

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Organic single-crystalline semiconductors with long-range periodic order have attracted much attention for potential applications in electronic and optoelectronic devices due to their high carrier mobility, highly thermal stability, and low impurity content. Molecular doping has been proposed as a valuable strategy for improving the performance of organic semiconductors and semiconductor-based devices. However, a fundamental understanding of the inherent doping mechanism is still a key challenge impeding its practical application. In this study, solid evidence for the "perfect" substitutional doping mechanism of the stacking mode between the guest and host molecules in organic single-crystalline semiconductors using polarized photoluminescence spectrum measurements and first-principles calculations is provided. The molecular host-guest doping is further exploited for efficient color-tunable and even white organic single-crystal-based light-emitting devices by controlling the doping concentration. The clarification of the molecular doping mechanism in organic single-crystalline semiconductor host-guest system paves the way for their practical application in high-performance electronic and optoelectronic devices.

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Molecular Self‐Doping Controls Luminescence of Pure Organic Single Crystals

Cited by 42 publications

References 39 publications

Cooperative Behaviors in Amplified Emission from Single Microcrystals of Thiophene/Phenylene Co‐Oligomers toward Organic Polariton Laser

Cooperative Behaviors in Amplified Emission from Single Microcrystals of Thiophene/Phenylene Co‐Oligomers toward Organic Polariton Laser

Enhanced Energy Transfer in Doped Bifluorene Single Crystals: Prospects for Organic Lasers

Clarification of the Molecular Doping Mechanism in Organic Single‐Crystalline Semiconductors and their Application in Color‐Tunable Light‐Emitting Devices

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