Preventing phase separation in MOCVD-grown InAlAs compositionally graded buffer on silicon substrate using InGaAs interlayers

•Compositionally graded InAlAs buffers are grown on Ge-on-Silicon substrates.•Final composition of the InAlAs buffer is 60% [In].•Phase separation in the InAlAs compositionally graded buffer is prevented using InGaAs interlayers.•InP virtual substrates with TDD around 1×108/cm2 is demonstrated. Comp...

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Bibliographic Details
Published in:Journal of crystal growth 2017-11, Vol.478, p.64-70
Main Authors: Kohen, David, Nguyen, Xuan Sang, Made, Riko I., Heidelberger, Christopher, Lee, Kwang Hong, Lee, Kenneth Eng Kian, Fitzgerald, Eugene A.
Format: Article
Language:English
Subjects:
A1. Defects
A3. Metalorganic chemical vapor deposition
A3. Metalorganic vapor phase epitaxy
B2. Semiconducting III–V materials
B2. Semiconducting ternary compounds
Buffers
Chemical vapor deposition
Dislocation density
Evaluation
Gallium arsenide
Indium aluminum arsenides
Interlayers
Metalorganic chemical vapor deposition
Phase separation
Silicon
Silicon substrates
Studies
Surface roughness
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Summary:•Compositionally graded InAlAs buffers are grown on Ge-on-Silicon substrates.•Final composition of the InAlAs buffer is 60% [In].•Phase separation in the InAlAs compositionally graded buffer is prevented using InGaAs interlayers.•InP virtual substrates with TDD around 1×108/cm2 is demonstrated. Compositionally graded InAlAs buffers grown by metal–organic chemical vapor deposition are impaired by phase separation occurring at In content higher than 35%. Phase separation results in rough epilayers with poor crystalline material quality. By introducing low temperature grown InGaAs interlayers in the compositionally graded InAlAs buffer, the surface roughness decreases, allowing a grading of up to In0.60Al0.40As without any phase separation occurring. This composite buffer is applied to fabricate a 200mm diameter InP-on-Si virtual substrate with a threading dislocation density around 1×108cm−2.
ISSN:0022-0248
1873-5002
DOI:10.1016/j.jcrysgro.2017.08.025