材料科学
发光
氮化镓
显微镜
钝化
光电子学
发光二极管
蚀刻(微加工)
镓
砷化镓
二极管
氮化物
光学
等离子体刻蚀
微等离子体
亮度
表征(材料科学)
光致发光
宽禁带半导体
量子点
高光谱成像
反应离子刻蚀
荧光寿命成像显微镜
纳米技术
近场扫描光学显微镜
量子效率
图像分辨率
载流子寿命
量子阱
等离子体
光学显微镜
炸薯条
作者
Jinjian Yan,Zhuoying Jiang,Linjue Zhang,Mengyu Chen,Jinchai Li,Kai Huang,Cheng Li,Rong Zhang
摘要
Localization and characterization of defects are particularly critical for optimizing the performance of a gallium nitride (GaN) micro light-emitting diode (Micro LED). In this work, we develop a multi-physical field microscopic imaging system, which is capable of achieving high spatiotemporal resolution characterization in an individual GaN Micro LED. By integrating fluorescence imaging, fluorescence lifetime imaging microscopy, hyperspectral imaging, and time-correlated single-photon counting, our system enables real-time tracking of the evolution of defects under coupled optical, electrical, and thermal fields. Equipped with this system, we systematically analyze the spatial distribution and depth of defects introduced by inductively coupled plasma (ICP) etching. Two distinct regions are observed: a narrow fluorescence lifetime decrease zone (∼2 μm) near the chip edges and a broader fluorescence intensity decrease zone (∼5 μm). To explain this, we propose a physical model that describes the interplay between defect-induced non-radiative recombination and carrier diffusion. Furthermore, we demonstrate that wet etching effectively mitigates these ICP-induced damages, leading to enhanced brightness across a wide range of Micro LED sizes. Notably, this passivation process enables a 3 μm size blue Micro LED chip to achieve a peak external quantum efficiency of 27.6% with a current density of 33.7 A/cm2. These findings provide insights into the localized impact of plasma etching and highlight the potential of wet etching for enhanced performance in Micro LED.
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