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Comparison of Buffer Layer Grading Approaches in InGaAs/GaAs (001)

Johanna Raphael

Electrical and Computer Engineering Department, University of Hartford, Hartford, CT 06117, USA

E-mail Address: johanna.raphael@gmail.com

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Tedi Kujofsa

Electrical and Computer Engineering Department, 371 Fairfield Way, Unit 4157, Storrs, CT 06269-4157, USA

E-mail Address: tedi.kujofsa@gmail.com

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J. E. Ayers

Electrical and Computer Engineering Department, 371 Fairfield Way, Unit 4157, Storrs, CT 06269-4157, USA

E-mail Address: john.ayers@uconn.edu

Corresponding author.

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https://doi.org/10.1142/S0129156420400029Cited by:0 (Source: Crossref)

This article is part of the issue:

Special Issue on Nanotechnology for Electronics, Biosensors, Additive Manufacturing and Emerging Systems Applications
Guest Editors: F. Jain, C. Broadbridge, M. Gherasimova and H. Tang

Abstract

Metamorphic semiconductor devices often utilize compositionally-graded buffer layers for the accommodation of the lattice mismatch with controlled threading dislocation density and residual strain. Linear or step-graded buffers have been used extensively in these applications, but there are indications that sublinear, superlinear, S-graded, or overshoot graded structures could offer advantages in the control of defect densities. In this work we compare linear, step-graded, and nonlinear grading approaches in terms of the resulting strain and dislocations density profiles using a state-of-the-art model for strain relaxation and dislocation dynamics. We find that sublinear grading results in lower surface dislocation densities than either linear or superlinear grading approaches.

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