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In situ n-doped nanocrystalline electron-injection-layer for general-lighting quantum-dot LEDs

Yizhen Zheng, Xing Lin, Jiongzhao Li, Jianan Chen, Wenhao Wu, Zixuan Song, Yuan Gao, Zhuang Hu, Huifeng Wang, Zikang Ye, Haiyan Qin, Xiaogang Peng

2025Nature Communications32 citationsDOIOpen Access PDF

Abstract

Quantum-dot optoelectronics, pivotal for lighting, lasing and photovoltaics, rely on nanocrystalline oxide electron-injection layer. Here, we discover that the prevalent surface magnesium-modified zinc oxide electron-injection layer possesses poor n-type attributes, leading to the suboptimal and encapsulation-resin-sensitive performance of quantum-dot light-emitting diodes. A heavily n-doped nanocrystalline electron-injection layer-exhibiting ohmic transport with 1000 times higher electron conductivity and improved hole blockage-is developed via a simple reductive treatment. The resulting sub-bandgap-driven quantum-dot light-emitting diodes exhibit optimal efficiency and extraordinarily-high brightness, surpassing current benchmarks by at least 2.6-fold, and reaching levels suitable for quantum-dot laser diodes with only modest bias. This breakthrough further empowers white-lighting quantum-dot light-emitting diodes to exceed the 2035 U.S. Department of Energy's targets for general lighting, which currently accounts for ~15% of global electricity consumption. Our work opens a door for understanding and optimizing carrier transport in nanocrystalline semiconductors shared by various types of solution-processed optoelectronic devices.

Topics & Concepts

OptoelectronicsQuantum dotMaterials scienceLight-emitting diodeNanocrystalline materialDiodePhotovoltaicsWide-bandgap semiconductorDopingQuantum efficiencyNanotechnologyPhotovoltaic systemElectrical engineeringEngineeringQuantum Dots Synthesis And PropertiesZnO doping and propertiesChalcogenide Semiconductor Thin Films