Wu Haifeng, Lin Xiao, Shuai Qin, Zhu Youliang, Fu Yi, Liao Xiaoqin, Wang Yazhou, Wang Yizhe, Cheng Chaowei, Liu Yong, Sun Lei, Luo Xinyi, Zhu Xiaoli, Wang Liancheng, Li Ziwei, Wang Xiao, Li Dong, Pan Anlian
Key Laboratory for Micro-Nano Physics and Technology of Hunan Province, State Key Laboratory of Chemo/Biosensing and Chemometrics, Hunan Institute of Optoelectronic Integration, College of Materials Science and Engineering, School of Physics and Electronics, Hunan University, 410082, Changsha, China.
Innovision Technology (Suzhou) Co. Ltd, 215000, Suzhou, China.
Light Sci Appl. 2024 Oct 9;13(1):284. doi: 10.1038/s41377-024-01639-3.
Owing to high pixel density and brightness, gallium nitride (GaN) based micro-light-emitting diodes (Micro-LEDs) are considered revolutionary display technology and have important application prospects in the fields of micro-display and virtual display. However, Micro-LEDs with pixel sizes smaller than 10 μm still encounter technical challenges such as sidewall damage and limited light extraction efficiency, resulting in reduced luminous efficiency and severe brightness non-uniformity. Here, we reported high-brightness green Micro-displays with a 5 μm pixel utilizing high-quality GaN-on-Si epilayers. Four-inch wafer-scale uniform green GaN epilayer is first grown on silicon substrate, which possesses a low dislocation density of 5.25 × 10 cm, small wafer bowing of 16.7 μm, and high wavelength uniformity (standard deviation STDEV < 1 nm), scalable to 6-inch sizes. Based on the high-quality GaN epilayers, green Micro-LEDs with 5 μm pixel sizes are designed with vertical non-alignment bonding technology. An atomic sidewall passivation method combined with wet treatment successfully addressed the Micro-LED sidewall damages and steadily produced nano-scale surface textures on the pixel top, which unlocked the internal quantum efficiency of the high-quality green GaN-on-Si epi-wafer. Ultra-high brightness exceeding 10 cd/m (nits) is thus achieved in the green Micro-LEDs, marking the highest reported results. Furthermore, integration of Micro-LEDs with Si-based CMOS circuits enables the realization of green Micro-LED displays with resolution up to 1080 × 780, realizing high-definition playback of movies and images. This work lays the foundation for the mass production of high-brightness Micro-LED displays on large-size GaN-on-Si epi-wafers.
由于具有高像素密度和亮度,基于氮化镓(GaN)的微型发光二极管(Micro-LED)被认为是具有革命性的显示技术,在微显示和虚拟显示领域具有重要的应用前景。然而,像素尺寸小于10μm的Micro-LED仍面临诸如侧壁损伤和光提取效率有限等技术挑战,导致发光效率降低和严重的亮度不均匀性。在此,我们报道了采用高质量的硅基氮化镓外延层制作的像素尺寸为5μm的高亮度绿色微显示器。首先在硅衬底上生长出四英寸晶圆级均匀的绿色氮化镓外延层,其具有5.25×10⁶cm的低位错密度、16.7μm的小晶圆翘曲以及高波长均匀性(标准偏差STDEV<1nm),可扩展到6英寸尺寸。基于高质量的氮化镓外延层,采用垂直非对准键合技术设计了像素尺寸为5μm的绿色Micro-LED。一种结合湿法处理的原子侧壁钝化方法成功解决了Micro-LED的侧壁损伤问题,并在像素顶部稳定地产生了纳米级表面纹理,从而释放了高质量硅基氮化镓外延晶圆的内部量子效率。因此,绿色Micro-LED实现了超过1000cd/m²(尼特)的超高亮度,这是迄今报道的最高结果。此外,将Micro-LED与基于硅的CMOS电路集成,能够实现分辨率高达1080×780的绿色Micro-LED显示器,实现电影和图像的高清播放。这项工作为在大尺寸硅基氮化镓外延晶圆上大规模生产高亮度Micro-LED显示器奠定了基础。
