The optimal threading dislocation density of AlN template for micrometer-thick Al0.63Ga0.37N heteroepitaxy

Chia Yen Huang; Sylvia Hagedorn; Sebastian Walde; Chia Lung Tsai; Yi Keng Fu; Markus Weyers

doi:10.1016/j.jcrysgro.2022.126910

The optimal threading dislocation density of AlN template for micrometer-thick Al_0.63Ga_0.37N heteroepitaxy

Chia Yen Huang^*, Sylvia Hagedorn, Sebastian Walde, Chia Lung Tsai, Yi Keng Fu, Markus Weyers

^*Corresponding author for this work

Department of Photonics

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Growth of Si-doped AlN and of Al_0.63Ga_0.37N on high quality AlN templates grown by HVPE has been investigated. The strain state of Si-doped AlN is thickness-dependent due to the surface-mediated dislocation tilt which induces a tensile strain component. At very low dislocation density in the AlN buffer strain relaxation in micrometer-thick Al_0.63Ga_0.37N layers is dominated by generation of additional dislocations. As a result, the final threading dislocation density and the surface roughness increase significantly. For a 1.6 μm Al_0.63Ga_0.37N on 3.4 μm Si-doped AlN bi-layer structure, the optimal threading dislocation density (TDD) of the AlN:Si buffer is estimated to be 7 × 10⁸ cm⁻², where the low TDD can be still transferred from the buffer to the thick AlGaN heterostructure without generation of many new dislocations.

Original language	English
Article number	126910
Journal	Journal of Crystal Growth
Volume	600
DOIs	https://doi.org/10.1016/j.jcrysgro.2022.126910
State	Published - 15 Dec 2022

Keywords

A1. Line defects
A1. Stresses
A3. Metalorganic vapor phase epitaxy
B1. Nitrides
B2. Semiconducting ternary compounds
B3. Light emitting diodes

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10.1016/j.jcrysgro.2022.126910

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@article{277dbf90b4a9466d8dc655c7004465c1,

title = "The optimal threading dislocation density of AlN template for micrometer-thick Al0.63Ga0.37N heteroepitaxy",

abstract = "Growth of Si-doped AlN and of Al0.63Ga0.37N on high quality AlN templates grown by HVPE has been investigated. The strain state of Si-doped AlN is thickness-dependent due to the surface-mediated dislocation tilt which induces a tensile strain component. At very low dislocation density in the AlN buffer strain relaxation in micrometer-thick Al0.63Ga0.37N layers is dominated by generation of additional dislocations. As a result, the final threading dislocation density and the surface roughness increase significantly. For a 1.6 μm Al0.63Ga0.37N on 3.4 μm Si-doped AlN bi-layer structure, the optimal threading dislocation density (TDD) of the AlN:Si buffer is estimated to be 7 × 108 cm−2, where the low TDD can be still transferred from the buffer to the thick AlGaN heterostructure without generation of many new dislocations.",

keywords = "A1. Line defects, A1. Stresses, A3. Metalorganic vapor phase epitaxy, B1. Nitrides, B2. Semiconducting ternary compounds, B3. Light emitting diodes",

author = "Huang, {Chia Yen} and Sylvia Hagedorn and Sebastian Walde and Tsai, {Chia Lung} and Fu, {Yi Keng} and Markus Weyers",

note = "Publisher Copyright: {\textcopyright} 2022 Elsevier B.V.",

year = "2022",

month = dec,

day = "15",

doi = "10.1016/j.jcrysgro.2022.126910",

language = "English",

volume = "600",

journal = "Journal of Crystal Growth",

issn = "0022-0248",

publisher = "Elsevier B.V.",

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TY - JOUR

T1 - The optimal threading dislocation density of AlN template for micrometer-thick Al0.63Ga0.37N heteroepitaxy

AU - Huang, Chia Yen

AU - Hagedorn, Sylvia

AU - Walde, Sebastian

AU - Tsai, Chia Lung

AU - Fu, Yi Keng

AU - Weyers, Markus

PY - 2022/12/15

Y1 - 2022/12/15

N2 - Growth of Si-doped AlN and of Al0.63Ga0.37N on high quality AlN templates grown by HVPE has been investigated. The strain state of Si-doped AlN is thickness-dependent due to the surface-mediated dislocation tilt which induces a tensile strain component. At very low dislocation density in the AlN buffer strain relaxation in micrometer-thick Al0.63Ga0.37N layers is dominated by generation of additional dislocations. As a result, the final threading dislocation density and the surface roughness increase significantly. For a 1.6 μm Al0.63Ga0.37N on 3.4 μm Si-doped AlN bi-layer structure, the optimal threading dislocation density (TDD) of the AlN:Si buffer is estimated to be 7 × 108 cm−2, where the low TDD can be still transferred from the buffer to the thick AlGaN heterostructure without generation of many new dislocations.

AB - Growth of Si-doped AlN and of Al0.63Ga0.37N on high quality AlN templates grown by HVPE has been investigated. The strain state of Si-doped AlN is thickness-dependent due to the surface-mediated dislocation tilt which induces a tensile strain component. At very low dislocation density in the AlN buffer strain relaxation in micrometer-thick Al0.63Ga0.37N layers is dominated by generation of additional dislocations. As a result, the final threading dislocation density and the surface roughness increase significantly. For a 1.6 μm Al0.63Ga0.37N on 3.4 μm Si-doped AlN bi-layer structure, the optimal threading dislocation density (TDD) of the AlN:Si buffer is estimated to be 7 × 108 cm−2, where the low TDD can be still transferred from the buffer to the thick AlGaN heterostructure without generation of many new dislocations.

KW - A1. Line defects

KW - A1. Stresses

KW - A3. Metalorganic vapor phase epitaxy

KW - B1. Nitrides

KW - B2. Semiconducting ternary compounds

KW - B3. Light emitting diodes

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U2 - 10.1016/j.jcrysgro.2022.126910

DO - 10.1016/j.jcrysgro.2022.126910

M3 - Article

AN - SCOPUS:85140721031

SN - 0022-0248

VL - 600

JO - Journal of Crystal Growth

JF - Journal of Crystal Growth

M1 - 126910

ER -

The optimal threading dislocation density of AlN template for micrometer-thick Al_0.63Ga_0.37N heteroepitaxy

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Keywords

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