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Enhanced Emission of Deep Ultraviolet Light-Emitting Diodes through Using Work Function Tunable Cu Nanowires as the Top Transparent Electrode

Zongxing Huang, Zhibai Zhong, Huachun Wang, Shiqiang Lu, Jun Wang, Guozhen Liu, Tongbo Wei, Jianchang Yan, Jung‐Hong Min, Woo‐Lim Jeong, Dong‐Seon Lee, Xuefen Cai, Fuchun Xu, Xiaohong Chen, Duanjun Cai, Junxi Wang, Junyong Kang

2020The Journal of Physical Chemistry Letters24 citationsDOI

Abstract

Deep ultraviolet light-emitting diodes (DUV LEDs) (<280 nm) have been important light sources for broad applications in, e.g., sterilization, purification, and high-density storage. However, the lack of excellent transparent electrodes in the DUV region remains a challenging issue. Here, we demonstrate an architectural engineering scheme to flexibly tune the work function of Cu@shell nanowires (NWs) as top transparent electrodes in DUV LEDs. By fast encapsulation of shell metals on Cu NWs and a shift of electron binding energy, the electronic work function could be widely tailored down to 4.37 eV and up to 5.73 eV. It is revealed that the high work function of Cu@Ni and Cu@Pt NWs could overcome the interfacial barrier to p-AlGaN and achieve direct ohmic contact with high transparency (91%) in 200-400 nm. Completely transparent DUV LED chips are fabricated and successfully lighted with sharp top emission (wall-plug efficiency reaches 3%) under a turn-on voltage of 6.4 V. This architectural strategy is of importance in providing highly transparent ohmic electrodes for optoelectronic devices in broad wavelength regions.

Topics & Concepts

Materials scienceOptoelectronicsOhmic contactWork functionLight-emitting diodeDiodeNanowireElectrodeUltravioletNanotechnologyChemistryPhysical chemistryLayer (electronics)GaN-based semiconductor devices and materialsZnO doping and propertiesAdvanced Sensor and Energy Harvesting Materials