Nanoparticle‐Enhanced Silver‐Nanowire Plasmonic Electrodes for High‐Performance Organic Optoelectronic Devices

Kim, Taehyo; Kang, Saewon; Heo, Jungwoo; Cho, Seungse; Kim, Jae Won; Choe, Ayoung; Walker, Bright; Shanker, Ravi; Ko, Hyunhyub; Kim, Jin Young

doi:10.1002/adma.201800659

Cited by 77 publications

(63 citation statements)

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“…These have the capabilities to increase the light‐scattering electric field due to gap plasmon effect. Kim et al have improved the efficiency in OLEDs and plasmonic OSCs via plasmonic transparent electrodes relay on aligned Ag NW networks based on the core–shell Ag@SiO 2 NPs as shown in Figure . They gained an outstanding light efficiency of 25.33 cd A −1 (at 3.2 V), PCE of 9.19%, and power efficiency of 25.14 lm W −1 (3.0 V) in OLEDs.…”

Section: Mechanism Of Plasmonic‐assisted Devicesmentioning

confidence: 99%

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Surface Plasmonic‐Assisted Photocatalysis and Optoelectronic Devices with Noble Metal Nanocrystals: Design, Synthesis, and Applications

Zada

Muhammad

Ahmad

et al. 2019

Adv Funct Materials

218

134

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The surface plasmon resonance (SPR) of noble metals is known to improve the efficiency of various processes and devices. The photocatalytic process is the production of fuels and storage of solar photons in chemical bonds without imposing harmful threats to the environment. Photovoltaics are other devices utilizing solar energy for electrical energy. Similarly, other optoelectronic devices like photodetectors absorb photons and convert it into charges via electron–hole dissociation processes. In contrast, light‐emitting optoelectronic devices work based on the phenomenon of charge recombination to produce light. All these devices, however, have efficiency limitations, which impede the application of novel functional materials in these devices. A more direct approach is the utilization of noble metals and their complexes, which significantly enhance the efficiencies of these devices by SPR. This article highlights recent works and applications of noble metals by SPR‐enhanced photocatalysis for hydrogen evolution from water, CO2 conversion into useful compounds, and oxidation of hazardous pollutants. In addition, the plasmon‐enhancement of optoelectronic devices is summarized. Several possible mechanisms that have been previously reported in the literature are discussed in this work, with particular emphasis on different features of these mechanisms involving devices that are not highlighted and therefore need more attention.

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Section: Mechanism Of Plasmonic‐assisted Devicesmentioning

confidence: 99%

Section: Mechanism Of Plasmonic‐assisted Devicesmentioning

confidence: 99%

Surface Plasmonic‐Assisted Photocatalysis and Optoelectronic Devices with Noble Metal Nanocrystals: Design, Synthesis, and Applications

Zada

Muhammad

Ahmad

et al. 2019

Adv Funct Materials

218

134

View full text Add to dashboard Cite

show abstract

“…Similar core–shell structures with metallic core and silica shell have also been reported by other groups, such as Ag nanocubes coated with silica shell, [ 37 ] Ag nanoparticles coated with silica shell. [ 104 ]…”

Section: Multifunctional Np Platform In Oledsmentioning

confidence: 99%

Toward High Efficiency Organic Light‐Emitting Diodes: Role of Nanoparticles

Zhang

Sun

2021

Advanced Optical Materials

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The rapid development of nanotechnology for the last 30 years has enabled a rapid expansion in the applications of functional nanoparticles (NPs) on optoelectronic devices. Especially, NPs are of high significance in organic light‐emitting diodes (OLEDs) as they provide feasible solutions to the enduring challenges related to higher device efficiency. The use of NPs with designed structure and functionality is demonstrated, indicative of their great application potentials in OLEDs. Herein, the recent advances in OLEDs with the utilization of functional NPs are summarized. Starting with a brief overview about the unique properties of NPs, comprehensive roles of NPs in OLEDs, which include improving carrier injection abilities, local surface plasmonic resonance, light scattering, and magnetic field effects, are discussed together with their latest research progresses. Furthermore, one‐component and multicomponent heterostructured NPs with multifunctional capabilities in OLEDs are overviewed. Following the summarization of the roles of NPs in OLEDs and their latest research progress, a brief conclusion and outlook regarding the future research directions of highly efficient OLEDs by incorporation of NPs are provided.

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“…Ag NWs networks generally have excellent light scattering and light capturing property as transparent electrodes and metal nanostructures. In order to overcome the disadvantages of short-circuit current or device https://engine.scichina.com/doi/10.1016/j.jechem.2020.04.060 performance deterioration originating from rough surface morphology and NW aggregation, some researchers modified the Ag NW network with core-shell silver-silica nanoparticles (Ag@SiO 2 NPs) as a transparent electrode and successfully obtained a PCE of 9.19% of OSCs [44]. Ag NPs can act as nanoantenna, coupling incident light into the delocalized surface plasmon polaritons (SPPs) on the NW surface as shown in Fig.…”

Section: Plasma Effect In Electrode Of Oscsmentioning

confidence: 99%