等离子刻蚀结合离子注入工艺的 InGaN 基微型 LED 性能研究

Yun-Cheng Hsu , Yu-Hsuan Hsu , Chien-Chung Lin , Ming Hsien Wu , Hao Chung Kuo , Dong-Sing Wuu , Ching-Lien Hsiao , Ray-Hua Horng
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引用次数: 0

摘要

本研究利用蓝光外延晶片,采用无掩模激光写入、干蚀刻、湿蚀刻、钝化层沉积、电子束蒸发和离子注入等半导体工艺,制造出像素尺寸不同但发光面积相同(900 μm²)的微型发光二极管(μLED)阵列。制作的微发光二极管阵列的单像素尺寸分别为 5 μm、10 μm 和 15 μm,阵列数分别为 6×6、3×3 和 2×2。本研究提出在蚀刻沟道区材料的同时保留一定宽度进行植入,即侧壁离子注入工艺,旨在利用离子注入技术对侧壁区域进行绝缘处理,从而获得更好的绝缘特性。它包括对等离子刻蚀后产生的缺陷区域进行离子轰击,并使用钝化层进行保护。与仅采用等离子体处理的μLED阵列相比,采用侧壁植入技术处理的μLED阵列具有更好的电气隔离特性。当器件微型化到 5 μm 时,侧壁植入工艺的光输出功率、外部量子效率和壁插效率都更胜一筹。总之,侧壁植入工艺与等离子体干蚀刻相结合,有效地改善了光输出特性,随着器件的微型化,增强率也在不断提高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Study on the performance of InGaN-based micro-LED by plasma etching combined with ion implantation process

This study utilized blue-light epitaxial wafers and employed semiconductor processes such as maskless laser writing, dry etching, wet etching, passivation layer deposition, electron beam evaporation, and ion implantation to fabricate micro-light emitting diode (μLED) arrays with different pixel sizes but the same emitting area (900 μm²). The μLED arrays with single pixel sizes of 5 μm, 10 μm, and 15 μm were fabricated, with array numbers of 6×6, 3×3, and 2×2, respectively. This study proposes etching the material in the channel region while retaining a certain width for implantation, known as the sidewall ion implantation process, aiming to achieve better insulation characteristics by using ion implantation technology to insulate the sidewall regions. It involves ion bombardment of the defect areas generated after plasma etching and the use of a passivation layer for protection. The isolation characteristics of μLED arrays processed by sidewall implantation exhibited better electrical isolation than those of μLED arrays processed only by plasma. The light output power, external quantum efficiency, and wall-plug efficiency were all superior for the sidewall implantation process when the device was miniaturized to 5 μm. Overall, the sidewall implantation process combined with plasma dry etching effectively improved the light output characteristics, with the enhancement ratio increasing as the device was miniaturized.

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