发光二极管
光电子学
材料科学
宽禁带半导体
制作
化学气相沉积
光学
二极管
蒙特卡罗方法
领域(数学)
色阶
电介质
光场
防反射涂料
光子
电场
等离子体子
可扩展性
再现性
氮化镓
光强度
色差
宽带
沉积(地质)
图层(电子)
微波食品加热
激光器
透射率
原子层沉积
探测器
传输(电信)
光功率
作者
Yi Wei,Shuhan Zhang,Qian Fan,Xianfeng Ni,Yongkang Fan,Dongliang Fan,Siyi Zhang,Li Tao,Xing Gu
摘要
This study addresses the coupled challenges of low vertical light extraction efficiency and insufficient color uniformity in red InGaN micro-light-emitting diodes (Micro-LEDs) by implementing an evolutionary-algorithm-driven optimization strategy for the thickness design of multilayer dielectric stacks. Through multi-objective optimization of Si3N4/SiO2 layer thicknesses, photon propagation modes were engineered via wavelength-selective interference, simultaneously enhancing vertical extraction and achieving spectral compression of the red emission for improved color purity. The designed stacks with optimized thickness were validated through Monte Carlo ray-tracing simulations modeling light manipulation over the proximal light field, with fabrication feasibility confirmed via plasma-enhanced chemical vapor deposition growth demonstrating sub-nanometer thickness control. Experimental results demonstrate a 47.52% directional intensity increment within the 70°–90° angular domain, a 6.0% reduction in chromatic dispersion, and robust reproducibility characterized by thickness uniformity <2% and spectral error <6.88%. This framework enables spectro-angular co-regulation of light emission, significantly advancing monolithic Micro-LED performance for high-fidelity augmented reality/virtual reality displays while providing a scalable solution to optical bottlenecks in nitride-based micro-optoelectronics for next-generation displays.
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