Zhiyuan Liu, Haicheng Cao, Xiao Tang, Tingang Liu, Yi Lu, Zixian Jiang, Na Xiao, Xiaohang Li
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引用次数: 0
Abstract
The size of InGaN micro-LEDs is continuously decreasing to meet the demands of various emerging applications, especially in tiny micro-displays such as AR/VR. However, the conventional pixel definition based on plasma etching significantly damages the mesa sidewalls, leading to a severe reduction in efficiency as the micro-LED size decreases. This seriously impedes the development and application of micro-LEDs. In this work, we comprehensively explain the origin of micro-LED sidewall effects and corresponding physical models. Subsequently, we systematically review recent progress in micro-LED fabrication aiming at suppressing sidewall effects. Furthermore, we discuss advancements in micro-LED fabrication with “damage-free” techniques, which hold the potential to fundamentally address the issue of plasma damage in the micro-LED process. We believe this review will deepen the understanding of micro-LED sidewall effects and provide a better insight into the latest associated fabrication technologies for high-efficient InGaN micro-LEDs.
为了满足各种新兴应用的需求,特别是 AR/VR 等微型显示器的需求,InGaN 微型 LED 的尺寸正在不断缩小。然而,传统的基于等离子体蚀刻的像素定义会严重破坏中胚层侧壁,导致效率随着微型 LED 尺寸的减小而严重下降。这严重阻碍了微型 LED 的开发和应用。在这项工作中,我们全面解释了微型 LED 侧壁效应的起源和相应的物理模型。随后,我们系统地回顾了旨在抑制侧壁效应的微型 LED 制造的最新进展。此外,我们还讨论了采用 "无损伤 "技术制造微型 LED 的进展,这些技术有可能从根本上解决微型 LED 工艺中的等离子体损伤问题。我们相信,这篇综述将加深人们对微型 LED 侧壁效应的理解,并为高效 InGaN 微型 LED 的最新相关制造技术提供更好的见解。
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