Ultrahigh Efficiency Fluorescent Single and Bi‐Layer Organic Light Emitting Diodes: The Key Role of Triplet Fusion

Chiang, Chien-Jung; Kimyonok, Alpay; Etherington, Marc K.; Griffiths, Gareth C.; Jankus, Vygintas; Türksoy, Figen; Monkman, A. P.

doi:10.1002/adfm.201201750

Cited by 276 publications

(208 citation statements)

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“…Maximum external quantum efficiencies (EQE) of about 6% or above have been obtained for DPA, perylene, and rubrene ( Figure 3c and Table S1, Supporting Information). These values exceed the EQE limit (5%) of conventional electrofluorescence (assuming an optical outcoupling factor of 0.2), [6][7][8] suggesting a significant contribution from triplets toward the total EL. We found that a high emitter doping concentration (20%) results in optimum OLED performance ( Figure S2, Supporting Information), consistent with the view that a small intermolecular separation is required for efficient bimolecular TTA process.…”

Section: Doi: 101002/adma201605987mentioning

confidence: 86%

“…[5] Another strategy to utilize triplet excitons in fluorescent OLEDs is through the generation of singlets by triplet-triplet annihilation (TTA) or "triplet fusion." [6][7][8] At the same time, photon upconversion through TTA has been widely considered for next-generation photovoltaic applications. [9][10][11][12][13][14] Effective upconverters have been demonstrated using combinations of a triplet sensitizer such as platinum octaethylporphyrin (PtOEP) [3] and a triplet acceptor/annihilator such as 9,10-diphenylanthracene (DPA), [15] perylene, [16] or rubrene.…”

Section: Doi: 101002/adma201605987mentioning

confidence: 99%

“…f outcoupling is assumed to be 0.2. [6][7][8] A more practical quantity we investigate is the TTA-UC quantum yield (or triplet-to-photon quantum yield), Φ TTA-UC , which calculates the number of TTA-generated photons emitted per triplet exciton entering the upconverter. It is given by the following equation: …”

Section: Doi: 101002/adma201605987mentioning

confidence: 99%

“…[9][10][11][12]18] A summary of the efficiencies of solution systems [17,18,[31][32][33] is shown in Table S2 (Supporting Information). Comparisons of our devices with other solid-state TTA-UC systems [13,14,19,31,34] and other TTA-enhanced OLEDs [7,8,[35][36][37] are presented in Tables S3 and S4 (Supporting Information), respectively. The remarkably high TTA-UC efficiencies in our best devices suggest that only singlets are formed during the TTA process.…”

Section: Doi: 101002/adma201605987mentioning

confidence: 99%

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Efficient Triplet Exciton Fusion in Molecularly Doped Polymer Light‐Emitting Diodes

et al. 2017

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probability of a triplet pair forming a singlet) in solution is >60%, much higher than the spin-statistical prediction of 25% (one pair of triplets collides to form one of the four states: one singlet S 1 and three triplets T 1 , assuming higher triplet and quintet states are inaccessible). Practical application of solar energy conversion requires the TTA-UC material to be in solid state rather than in solution phase. However, the TTA-UC quantum yield of solidstate systems remains low, typically below 5%, [10] and is moderately high (about 10%) in only one example. [19] To achieve high efficiencies, high excitation intensities (200 mW cm −2 or above) are commonly required. These imply that in solid state, the experimentally observed reaction efficiency of TTA-UC was up to about 20%, below the 25% spin-statistical limit.To achieve highly efficient triplet fusion (TTA-UC) in OLEDs and other TTA upconverters, we consider four criteria for the selection of emitters: (1) high fluorescence quantum yield, (2) short singlet lifetime, (3) long triplet lifetime, and (4) the energy of two triplet excitons, 2E(T 1 ) lies slightly above that of the singlet exciton, E(S 1 ), but below the second triplet state, E(T 2 ) (and also the energies of any spin-quintet states) (E(S 1 ) ≲ 2E(T 1 ) < E(T 2 )). The first and second criteria are prerequisites for efficient fluorescence. The third criterion is essential for the accumulation of a sufficiently high triplet population density required for rapid triplet-triplet collision processes. The fourth criterion ensures that higher-lying triplet or quintet states do not provide loss channels. The spin states of the triplet excitons give in principle nine spin configurations for the interacting triplet exciton pair, five associated with a quintet, three with a triplet, and one with the singlet state. It is generally considered that the quintet is always higher in energy than the initial triplet pair, so is neglected. If there are no energetically accessible higher-lying triplet states at E(T 2 ), we expect only the S 1 and T 1 excitons to form. Triplets produced from this reaction can be recycled and participate in a further fusion reaction. [7] The basic working principle of a triplet fusion LED (FuLED) is illustrated in Figure 1a. The initial stage (Stage I) of the device operation includes charge injection and exciton formation. Exciton formation on the emissive molecules may occur directly or indirectly through an additional exciton transfer step from a host material. If a host material is present, the S 1 and T 1 of the host are required to be higher than that of the emitter to allow efficient host-emitter energy transfer and to ensure long triplet lifetime of the emitter (Criterion 3 discussed above). The 25% singlet population can be converted to light emission (and nonradiative losses) from the singlet channel immediately, resulting in prompt electroluminescence (EL). The 75% triplet excitons remain nonemissive, but the population of triplets is When an organic light-emitting dio...

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Section: Doi: 101002/adma201605987mentioning

confidence: 86%

Section: Doi: 101002/adma201605987mentioning

confidence: 99%

Section: Doi: 101002/adma201605987mentioning

confidence: 99%

Section: Doi: 101002/adma201605987mentioning

confidence: 99%

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Efficient Triplet Exciton Fusion in Molecularly Doped Polymer Light‐Emitting Diodes

et al. 2017

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“…Considerable attention has been paid to white organic light-emitting devices (OLEDs) in flat panel displays (FPDs) and solid-state lighting in the next generation due to several potential advantages such as diffusive emission of surfaces, large-range area manufacturability, ecofriendliness, and effective fabrication process for the cost [1][2][3][4][5][6][7][8][9] . Such interesting advantages in white OLEDs have activated the field and, though they are entering the marketplace, outstanding challenges in achieving high efficiency and color rendering index (CRI) still remain.…”

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confidence: 99%

Effect of various red phosphorescent dopants in single emissive white phosphorescent organic light-emitting devices

et al. 2017

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In order to realize single emissive white phosphorescent organic light-emitting devices (PHOLEDs) with three color phosphorescent dopants (red, green, and blue), the energy transfer between the host material and the three dopants, as well as the among the three dopants themselves, should be considered and optimized. To explore the effect of red phosphorescent dopant on the color rendering index (CRI), the authors investigate the wavelength position of the maximum emission peak from three phosphorescent dopants. The CRI and luminous efficiency of white PHOLED in which IrðpqÞ 2 ðacacÞ acts as the red phosphorescent dopant are found to be greater than those of devices prepared using IrðpiqÞ 3 and IrðbtpÞ 2 ðacacÞ as the emission spectrum has a relatively high intensity near the human perception of blue, red, and green wavelengths. Furthermore, we demonstrate that the performance of the three dopants is related to the absorption characteristics of the red phosphorescent dopant. With a maximum emission peak at 600 nm, IrðpqÞ 2 ðacacÞ has a higher intensity in the concave section between 550 and 600 nm seen for red and blue dopants. In addition, the long metal-to-ligand charge transfer (MLCT) absorption tail of IrðpqÞ 2 ðacacÞ overlaps with the emission spectra of the green dopant, enhancing emission. Such energy transfer mechanisms are confirmed to optimize white emission in the single emissive white PHOLEDs.OCIS codes: 160.4890, 300.1030, 260.2160. doi: 10.3788/COL201715.051602.Considerable attention has been paid to white organic light-emitting devices (OLEDs) in flat panel displays (FPDs) and solid-state lighting in the next generation due to several potential advantages such as diffusive emission of surfaces, large-range area manufacturability, ecofriendliness, and effective fabrication process for the cost [1][2][3][4][5][6][7][8][9] . Such interesting advantages in white OLEDs have activated the field and, though they are entering the marketplace, outstanding challenges in achieving high efficiency and color rendering index (CRI) still remain. A key strategy for improving the efficiency in white OLEDs is to increase the external quantum efficiency to 100% by harvesting both singlet and triplet excitons. This is possible in a phosphorescent OLED (PHOLED) [10][11][12] . In the case of the longterm degradation processes, they need both optimized device structure considering organic materials in each functional layerand a good encapsulation process. Many structures have been attempted for white OLEDs to achieve a high performance [13][14][15][16][17][18] . The most easily manufacturable and simplest structures for PHOLEDs are single emissive layer (SEL) devices with phosphorescent dopants. SEL in OLEDs means only one emitting layer in the OLED device. On the other hand, multi-emissive layer (MEL) defines two, or more than two, different and distinct emitting layers in OLED devices. Though two white dopant in PHOLEDs have been realized, their low CRI makes them unsuitable for a variety of applications. It is relativ...

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Efficiency Enhancement of Organic Light‐Emitting Diodes Exhibiting Delayed Fluorescence and Nonisotropic Emitter Orientation

Schmidt

Brütting

2018

Highly Efficient OLEDs

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Ultrahigh Efficiency Fluorescent Single and Bi‐Layer Organic Light Emitting Diodes: The Key Role of Triplet Fusion

Cited by 276 publications

References 35 publications

Efficient Triplet Exciton Fusion in Molecularly Doped Polymer Light‐Emitting Diodes

Efficient Triplet Exciton Fusion in Molecularly Doped Polymer Light‐Emitting Diodes

Effect of various red phosphorescent dopants in single emissive white phosphorescent organic light-emitting devices

Efficiency Enhancement of Organic Light‐Emitting Diodes Exhibiting Delayed Fluorescence and Nonisotropic Emitter Orientation

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