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High‐Efficiency InGaN Red Mini‐LEDs on Sapphire Toward Full‐Color Nitride Displays: Effect of Strain Modulation

Zhaoying Chen, Bowen Sheng, Fang Liu, Shangfeng Liu, Duo Li, Zexing Yuan, Tao Wang, Xin Rong, Jingsheng Huang, Jiangying Qiu, Wenji Liang, Chunlei Zhao, Long Yan, Jason Hu, Shiping Guo, Weikun Ge, Bo Shen, Xinqiang Wang

2023Advanced Functional Materials61 citationsDOI

Abstract

Abstract InGaN red light emitting diode (LED) is one of the crucial bottlenecks that must be broken through to realize high‐resolution full‐color mini/micro‐LED displays. The efficiency of InGaN LEDs drops rapidly as the emission spectra go from blue/green to red range due to the poor quality of high‐indium‐content InGaN materials. Here, high‐performance InGaN red LEDs on sapphire grown by metal–organic chemical vapor deposition through strain modulation are reported. A composite buffer layer is proposed to increase the surface lattice constant of GaN and hence successfully enhances the indium incorporation efficiency of the following InGaN active layers. Consequently, a high‐efficiency InGaN red mini‐LED chip (mesa area: 100 × 200 µm 2 ) with a peak wavelength of 629 nm and an external quantum efficiency of 7.4% is realized. Finally, a full‐color nitride mini‐LED display panel with 74.1% coverage of Rec.2020 color gamut by using the InGaN red mini‐LED chips is fabricated. The study signifies the great potentials of full‐nitrides high‐resolution full‐color mini/micro‐LED displays.

Topics & Concepts

Materials scienceLight-emitting diodeOptoelectronicsIndium gallium nitrideNitrideSapphireIndium nitrideQuantum efficiencyIndiumChemical vapor depositionGallium nitrideDiodeQuantum-confined Stark effectQuantum wellOpticsLayer (electronics)NanotechnologyLaserPhysicsGaN-based semiconductor devices and materialsZnO doping and propertiesGa2O3 and related materials
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