The origin and mitigation of volcano-like morphologies in micron-thick AlGaN/AlN heteroepitaxy

Chia-Yen Huang; Kai Shiang Chang; Cheng Yao Huang; Yun Hsiang Lin; Wei Chih Peng; Hung Wei Yen; Ray Ming Lin; Hao-Chung Kuo

doi:10.1063/1.4999767

The origin and mitigation of volcano-like morphologies in micron-thick AlGaN/AlN heteroepitaxy

Chia-Yen Huang, Kai Shiang Chang, Cheng Yao Huang, Yun Hsiang Lin, Wei Chih Peng, Hung Wei Yen, Ray Ming Lin, Hao-Chung Kuo

光電工程學系

研究成果: Article › 同行評審

8 引文斯高帕斯（Scopus）

摘要

We investigated the origin of morphological instability in 2 μm thick Al_0.6Ga_0.4N/AlN heteroepitaxy. The primary morphology was driven by the residual epitaxial strain, forming hill-like morphologies via surface diffusion. The secondary morphology was driven by the interaction between the primary morphology and dislocation clusters in the epitaxial layers. The difference in the local growth rate yields volcano-like morphologies centering on deep pits. Insertion of multi-stack superlattice transition layers between AlGaN and GaN effectively suppressed the secondary morphologies by simultaneously pre-relaxing the template and filtering treading dislocations.

原文	American English
文章編號	072110
頁（從 - 到）	1-5
頁數	5
期刊	Applied Physics Letters
卷	111
發行號	7
DOIs	https://doi.org/10.1063/1.4999767
出版狀態	Published - 14 8月 2017

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abstract = "We investigated the origin of morphological instability in 2 μm thick Al0.6Ga0.4N/AlN heteroepitaxy. The primary morphology was driven by the residual epitaxial strain, forming hill-like morphologies via surface diffusion. The secondary morphology was driven by the interaction between the primary morphology and dislocation clusters in the epitaxial layers. The difference in the local growth rate yields volcano-like morphologies centering on deep pits. Insertion of multi-stack superlattice transition layers between AlGaN and GaN effectively suppressed the secondary morphologies by simultaneously pre-relaxing the template and filtering treading dislocations.",

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AU - Huang, Chia-Yen

AU - Chang, Kai Shiang

AU - Huang, Cheng Yao

AU - Lin, Yun Hsiang

AU - Peng, Wei Chih

AU - Yen, Hung Wei

AU - Lin, Ray Ming

AU - Kuo, Hao-Chung

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N2 - We investigated the origin of morphological instability in 2 μm thick Al0.6Ga0.4N/AlN heteroepitaxy. The primary morphology was driven by the residual epitaxial strain, forming hill-like morphologies via surface diffusion. The secondary morphology was driven by the interaction between the primary morphology and dislocation clusters in the epitaxial layers. The difference in the local growth rate yields volcano-like morphologies centering on deep pits. Insertion of multi-stack superlattice transition layers between AlGaN and GaN effectively suppressed the secondary morphologies by simultaneously pre-relaxing the template and filtering treading dislocations.

AB - We investigated the origin of morphological instability in 2 μm thick Al0.6Ga0.4N/AlN heteroepitaxy. The primary morphology was driven by the residual epitaxial strain, forming hill-like morphologies via surface diffusion. The secondary morphology was driven by the interaction between the primary morphology and dislocation clusters in the epitaxial layers. The difference in the local growth rate yields volcano-like morphologies centering on deep pits. Insertion of multi-stack superlattice transition layers between AlGaN and GaN effectively suppressed the secondary morphologies by simultaneously pre-relaxing the template and filtering treading dislocations.

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The origin and mitigation of volcano-like morphologies in micron-thick AlGaN/AlN heteroepitaxy

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