材料科学
电致发光
光电子学
红外线的
纳米晶
二极管
量子效率
光发射
量子阱
发光二极管
量子点
激光器
纳米技术
发光
光学
物理
图层(电子)
作者
Junling Qu,Mateusz Weis,Eva Izquierdo,Simon Gwénaël Mizrahi,Audrey Chu,Corentin Dabard,Charlie Gréboval,Erwan Bossavit,Yoann Prado,Emmanuel Péronne,Sandrine Ithurria,G. Patriarche,Mathieu G. Silly,Grégory Vincent,D. Boschetto,Emmanuel Lhuillier
出处
期刊:Nature Photonics
[Nature Portfolio]
日期:2021-12-13
卷期号:16 (1): 38-44
被引量:48
标识
DOI:10.1038/s41566-021-00902-y
摘要
Visible nanocrystal-based light-emitting diodes (LEDs) are about to become commercially available. However, their infrared counterparts suffer from two key limitations. First, III–V semiconductor technologies are strong competitors. Second, their potential for operation beyond 1.7 µm remains unexplored. The range from 1.5 to 4 µm corresponds to a technological gap in which the efficiency of interband quantum-well-based devices vanishes and quantum cascade lasers are not efficient enough. Powerful infrared LEDs in this range are needed for applications such as active imaging, organic molecule sensing and airfield lighting. Here we report the design of a HgTe nanocrystal-based LED with luminescence between 2 and 2.3 µm. With an external quantum efficiency of 0.3% and radiance up to 3 W Sr−1 m−2, these HgTe LEDs already present a competitive performance for emission above 2 µm. Near-infrared emission at around 2 µm is observed from HgTe nanocrystals. LEDs based on this material platform could prove to be a useful low-cost, convenient light source for applications in gas sensing and other tasks.
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