Dissolution of antiphase domain boundaries in GaAs on Si(001) via post-growth annealing

GaAs-on-Si epitaxial crystal quality has historically been limited by a number of growth-related defects. In particular, antiphase domain boundaries (APBs) can nucleate at the GaAs/Si interface and propagate throughout the entire GaAs layer. Still little is known about how thermal processing can aff...

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Bibliographic Details
Published in:Journal of materials science 2019-05, Vol.54 (9), p.7028-7034
Main Authors: Barrett, C. S. C., Atassi, A., Kennon, E. L., Weinrich, Z., Haynes, K., Bao, X.-Y., Martin, P., Jones, K. S.
Format: Article
Language:English
Subjects:
Activation energy
Annealing
Antiphase boundaries
Characterization and Evaluation of Materials
Chemical vapor deposition
Chemistry and Materials Science
Classical Mechanics
Crystal defects
Crystallography and Scattering Methods
Density
Dissolution
Electronic Materials
Epitaxial growth
Epitaxy
Gallium arsenide
heat treatment
Materials Science
Metalorganic chemical vapor deposition
Organic chemicals
Organic chemistry
Polymer Sciences
silicon
Solid Mechanics
temperature
Temperature dependence
vapors
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Summary:GaAs-on-Si epitaxial crystal quality has historically been limited by a number of growth-related defects. In particular, antiphase domain boundaries (APBs) can nucleate at the GaAs/Si interface and propagate throughout the entire GaAs layer. Still little is known about how thermal processing can affect the APB density in GaAs. In this study, GaAs was grown on nominally on-axis Si(001) by metal–organic chemical vapor deposition. The effect of ex situ post-growth annealing was evaluated for a temperature range of 550–700 °C. It was found that upon annealing the APB density was decreased significantly. The rate of APB density decrease was found to be temperature dependent. At annealing temperatures of 650 °C and above, the APB density was reduced from 0.10 μm −1 to approximately 0.010 μm −1 in less than 10 min. The activation energy for APB dissolution was determined to be 3.8 eV. The mechanism of APB dissolution is discussed.
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-019-03353-7