Improvement of electroluminescent performance of n-ZnO/AlN/p-GaN light-emitting diodes by optimizing the AlN barrier layer

Zhang, S. G.; Zhang, X. W.; Yin, Z. G.; Wang, J. X.; Dong, Jun; Wang, Z. G.; Qu, Sheng Guan; Cui, B.; Wowchak, A. M.; Dabiran, A. M.; Chow, P. P.

doi:10.1063/1.3590399

Cited by 27 publications

(13 citation statements)

References 28 publications

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“…In contrast, for the PAIT Q‐LED, the injected electrons from ITO cathode will first be transported in the T layer and then be retarded (or even blocked) by the inserted Al 2 O 3 dielectric layer (see Figure b). Although most of these injected electrons could still tunnel through this thin Al 2 O 3 layer under forward bias, their migration ability is weakened because these electrons have experienced strong scattering with the Al 2 O 3 host‐lattice/defect‐sites during the tunneling process and lost some of their kinetic energy . In such a case, these electrons will be detained in the A layer QDs emissive region.…”

Section: Resultsmentioning

confidence: 99%

Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al₂O₃ Retarding Layer and Ag@ZnO Hybrid Nanodots

Yang

et al. 2017

Advanced Optical Materials

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Short‐wavelength light‐emitting diodes (LEDs), a prevalent research topic in modern optoelectronics, have attracted considerable attention in recent years because of their vast application potential in both civil and military domains. Herein, blue‐violet LEDs are constructed via a spin‐coating solution‐processed ZnO quantum dots (QDs) onto p‐GaN: Mg wafers. By inserting a thin Al2O3 dielectric retarding layer into the ZnO QDs side, electrons injected from ITO cathode are effectively slowed and detained in the QDs emissive layer, resulting in a ≈30‐fold improvement of near‐UV electroluminescence intensity from this p‐GaN/ZnO QDs/Al2O3/ZnO QDs LED. Furthermore, by replacing pure ZnO QDs with Ag@ZnO hybrid nanodots (synthesized through a simple one‐step wet chemical route) as the electron transport layer, the device electroluminescence intensity is further increased. Time‐resolved and temperature‐dependent spectroscopy reveals that both the spontaneous emission rate and internal quantum efficiency of the ZnO QDs active layer are simultaneously increased as a result of the exciton‐localized surface plasmon resonant coupling, which leads to the observed blue‐violet electroluminescence enhancement.

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Section: Resultsmentioning

confidence: 99%

Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al₂O₃ Retarding Layer and Ag@ZnO Hybrid Nanodots

Yang

et al. 2017

Advanced Optical Materials

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“…The wide band energy of intrinsic layer in LED structure was necessary to obtain a required band offset of more than 1 eV in the conduction band for the n-ZnO semiconductor and less than 1 eV in the valence band for the p-GaN semiconductor. In consequence, the optimized intrinsic layer should block (reduce) the flow of electrons and facilitate the diffusion of holes in the junction structure [21]. This means that the interlayer in junction was desirable because the n-ZnO/p-GaN LED emitted mainly from the p-type GaN region and not from the n-type ZnO.…”

Section: Resultsmentioning

confidence: 99%

ALD Oxides-Based n-i-p Heterostructure Light Emitting Diodes

2018

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The aim of this work was an analysis of structural, electrical and optical properties of n-type ZnO/i/p-type (called as n-i-p) GaN heterostructure with interlayer between these semiconductors. Such junctions are promising structures for light-emitting diodes, light detectors in the range of ultraviolet radiation and photovoltaic cells. This work concentrates on the investigation of the influence of oxide interlayers in optoelectronic structures, and optimization of growth parameters (in the atomic layer deposition-ALD process) of all oxide layers. Composition of HfO2, TiO2, ZrO2 and Al2O3 films was also optimized. The layers were used as intrinsic barriers to improve the performance and realize color shift of the n-ZnO/p-GaN heterojunction LEDs. The rectification ratio of n-i-p junctions was Ion/I off = 1 × 10 2-10 3 for the voltage of 20 V. The color emission of these devices was adjusted from violet to white light in a room temperature depending on the growth parameters and composition of the ALD oxide layers.

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“…Figure 4 b presents the EL spectra of the ZnO nanorod array-based LEDs with different diameters (170, 220, 300, and 380 nm) at the injection current of 6 mA, and all the four diodes show a dominant NBE emission at 390 nm. Compared with the PL spectra, there is a 10-nm red shift of the EL NBE emission, which is caused by the junction-heating effect under a constant injection current [ 14 , 19 ] and difference between PL and EL processes (the PL process depends on the recombination of nonequilibrium carriers in the surface layer, whereas the EL process is determined via the carrier recombination within the space charge region of heterojunction [ 20 ]).…”

Section: Resultsmentioning

confidence: 99%

Electroluminescence of ordered ZnO nanorod array/p-GaN light-emitting diodes with graphene current spreading layer

et al. 2014

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Ordered ZnO nanorod array/p-GaN heterojunction light-emitting diodes (LEDs) have been fabricated by introducing graphene as the current spreading layer, which exhibit improved electroluminescence performance by comparison to the LED using a conventional structure (indium-tin-oxide as the current spreading layer). In addition, by adjusting the diameter of ZnO nanorod array in use, the light emission of the ZnO nanorod array/p-GaN heterojunction LEDs was enhanced further. This work has great potential applications in solid-state lighting, high performance optoelectronic devices, and so on.PACS78.60.Fi; 85.60.Jb; 78.67.Lt; 81.10.Dn

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Improvement of electroluminescent performance of n-ZnO/AlN/p-GaN light-emitting diodes by optimizing the AlN barrier layer

Cited by 27 publications

References 28 publications

Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al₂O₃ Retarding Layer and Ag@ZnO Hybrid Nanodots

Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al₂O₃ Retarding Layer and Ag@ZnO Hybrid Nanodots

ALD Oxides-Based <i>n-i-p</i> Heterostructure Light Emitting Diodes

Electroluminescence of ordered ZnO nanorod array/p-GaN light-emitting diodes with graphene current spreading layer

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Improvement of electroluminescent performance of n-ZnO/AlN/p-GaN light-emitting diodes by optimizing the AlN barrier layer

Cited by 27 publications

References 28 publications

Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al2O3 Retarding Layer and Ag@ZnO Hybrid Nanodots

Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al2O3 Retarding Layer and Ag@ZnO Hybrid Nanodots

ALD Oxides-Based <i>n-i-p</i> Heterostructure Light Emitting Diodes

Electroluminescence of ordered ZnO nanorod array/p-GaN light-emitting diodes with graphene current spreading layer

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Resources

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Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al₂O₃ Retarding Layer and Ag@ZnO Hybrid Nanodots

Enhanced Electroluminescence from ZnO Quantum Dot Light‐Emitting Diodes via Introducing Al₂O₃ Retarding Layer and Ag@ZnO Hybrid Nanodots