24.1% External Quantum Efficiency of Flexible Quantum Dot Light‐Emitting Diodes by Light Extraction of Silver Nanowire Transparent Electrodes

Ding, Ke; Fang, Yunsheng; Dong, Shaohua; Chen, Hongting; Luo, Beibei; Jiang, Kui; Gu, Honggang; Fan, Longlong; Liu, Shiyuan; Hu, Bin; Wang, Lei

doi:10.1002/adom.201800347

Cited by 59 publications

(35 citation statements)

References 50 publications

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“…due to their narrow and tunable emission spectral bandwidth, high stability, and wide luminescent spectral range . According to previous reports, the best external quantum efficiencies (EQEs) of Cd‐based‐blue, green, and red quantum dot‐light‐emitting diode (QLED) reach up to 21.4%, 27.6%, 24.1%, respectively, with device structure optimization and the improvement of QD synthesis technology. As a new star in the field of fluorescent materials, the EQEs of the perovskite QLEDs have also exceeded 10% .…”

Section: Introductionmentioning

confidence: 99%

High‐Efficiency Green InP Quantum Dot‐Based Electroluminescent Device Comprising Thick‐Shell Quantum Dots

Zhang

Zeng

et al. 2019

Advanced Optical Materials

153

146

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Indium phosphide (InP) core/shell quantum dots (QDs) without intrinsic toxicity have shown great potential to replace the widely applied cadmium‐containing QDs in next‐generation commercial display and lighting applications. However, it remains challenging to synthesize InP core/shell QDs with high quantum yields (QYs), uniform particle size, and simultaneously thicker shell thickness to reduce nonradiative Förster resonant energy transfer (FRET). Here, thick InP‐Based QLEDs shell InP/GaP/ZnS//ZnS core/shell QDs with high stability, high QY (≈70%), and large particle size (7.2 ± 1.3 nm) are successfully synthesized through extending the growth time of shell materials along with the timely replenishment of shelling precursor. The existence of GaP interface layer minimizes the lattice mismatch and reduces interfacial defects. While thick ZnS shell, which suppresses the FRET between closely packed QDs, ensures high PL QY and stability. The robustness of such properties is demonstrated by the fabrication of green electroluminescent LEDs based on InP core/shell QDs with the peak external quantum efficiency and current efficiency of 6.3% and 13.7 cd A−1, respectively, which are the most‐efficient InP‐based green quantum dot light‐emitting diodes (QLEDs) till now. This work provides an effective strategy to further improve heavy‐metal‐free QLED performance and moves a significant step toward the commercial application of InP‐based electroluminescent device.

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Section: Introductionmentioning

confidence: 99%

High‐Efficiency Green InP Quantum Dot‐Based Electroluminescent Device Comprising Thick‐Shell Quantum Dots

Zhang

Zeng

et al. 2019

Advanced Optical Materials

153

146

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“…Hence, the corresponding TNE20 electrode exhibited a slightly high haze of 6%–10%. A high haze of the substrate or electrode has been reported to increase the solar cell efficiency, enhance the light‐outcoupling for improved light extraction from a light emitting diode, and reduce the glare of a display …”

Section: Resultsmentioning

confidence: 99%

Highly Thermal‐Resilient AgNW Transparent Electrode and Optical Device on Thermomechanically Superstable Cellulose Nanorod‐Reinforced Nanocomposites

Biswas

Sano

Yang

et al. 2019

Advanced Optical Materials

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Transparent plastics coated with a nanonetwork of metal nanowires or carbon nanomaterials are promising future electrodes for large‐area, lightweight, and flexible optoelectronic devices. However, plastics are generally thermal‐ dimensionally instable, meaning that they expand and shrink in response to temperature change. This behavior may severe the ultrathin nanonetwork of the conducting nanomaterials, resulting in reduced performance of the electrodes and resulting optoelectronic devices. Herein, an incredibly thermal‐dimensionally stable (3.26–4.68 ppm K−1) transparent and flexible plastic substrate is presented that results in high thermal performance of the resulting silver nanowire (AgNW) electrode and smart optical device. The high thermal‐dimensional stability is achieved through the generation of a hierarchical network of cellulose nanorods (a highly regarded biobased reinforcing material) in the plastic via a water‐based process. The improved nanocomposite electrode exhibits good electro‐optical performance (12.4–15.6 Ω sq−1 vs 84%); high flexibility; good mechanics even at 150 °C; and the capability to withstand repeated extreme heating and cooling at 150 and −196 °C, respectively. The findings of this study combined with those reported in the literature can show a pathway for further performance improvement of transparent electrodes for future advanced devices.

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“…Recently, as shown in Figure (e), Ding el al. reported a red flexible QLED with record‐breaking maximum EQE of 24.1 % . This amazing efficiency was derived from the adoption of silver nanowires (AgNWs) that served as transparent conductive electrodes and light‐scatting centers simultaneously (Figure (d)).…”

Section: The Routes To High‐performance Qledsmentioning

confidence: 99%

Beyond OLED: Efficient Quantum Dot Light‐Emitting Diodes for Display and Lighting Application

Sun

Jiang

Sun

et al. 2019

The Chemical Record

113

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The unique features of solution-processed quantum dots (QDs) including emission tunability in the visible range, high-quality saturated color and outstanding intrinsic stability in environment are highly desired in various application fields. Especially, for the preparation of wide color gamut displays, QDs with high photoluminescence quantum yield are deemed as the optimal fluorescent emitter that has been utilized in the backlight for liquid crystal display. Nevertheless, the commercialization of electrically driven self-emissive quantum dot lightemitting diode (QLED) display is the ultimate target due to its merits of high contrast, slim configuration and compatibility with flexible substrate. Through the great efforts devoted to material engineering and device configuration, astonishing progresses have been made in device performance, giving the QLED technology a great chance to compete with other counterparts for next-generation displays. In this review, we retrospect the development roadmap of QLED technology and introduce the essential principles in the QLED devices. Moreover, we discuss the key factors that affect the QLED efficiency and lifetime. Finally, the advances in device architectures and pixel patterning are also summarized.

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24.1% External Quantum Efficiency of Flexible Quantum Dot Light‐Emitting Diodes by Light Extraction of Silver Nanowire Transparent Electrodes

Cited by 59 publications

References 50 publications

High‐Efficiency Green InP Quantum Dot‐Based Electroluminescent Device Comprising Thick‐Shell Quantum Dots

High‐Efficiency Green InP Quantum Dot‐Based Electroluminescent Device Comprising Thick‐Shell Quantum Dots

Highly Thermal‐Resilient AgNW Transparent Electrode and Optical Device on Thermomechanically Superstable Cellulose Nanorod‐Reinforced Nanocomposites

Beyond OLED: Efficient Quantum Dot Light‐Emitting Diodes for Display and Lighting Application

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