S-Graded Buffet Layers for Lattice-Mismatched Heteroepitaxial Devices

We have conducted a theoretical study of the equilibrium strain and misfit dislocation density profiles for "S-graded" buffer layers of In sub(x)Ga sub(1-x) As on GaAs (001) substrates in which the compositional profile follows a normal cumulative distribution function. On the basis of thi...

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Veröffentlicht in:	Journal of electronic materials 2011-12, Vol.40 (12), p.2348-2354
Hauptverfasser:	Xhurxhi, S, Obst, F, Sidoti, D, Bertoli, B, Kujofsa, T
Format:	Artikel
Sprache:	eng
Schlagworte:	Buffer layers Density Devices Dislocation density Gallium arsenide Optimization Surface chemistry Threading dislocations
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creator	Xhurxhi, S Obst, F Sidoti, D Bertoli, B Kujofsa, T
description	We have conducted a theoretical study of the equilibrium strain and misfit dislocation density profiles for "S-graded" buffer layers of In sub(x)Ga sub(1-x) As on GaAs (001) substrates in which the compositional profile follows a normal cumulative distribution function. On the basis of this modeling work we show that the S-graded layer exhibits misfit dislocation-free regions near the substrate interface and the free surface (or device interface). The equilibrium peak misfit dislocation density as well as the thicknesses of the dislocation-free regions may be tailored by design of the compositional profile; this in turn should enable minimization of the density of electronically active threading dislocations at the top surface. S-graded buffer layers may therefore facilitate the achievement of metamorphic device structures with improved performance compared with similar structures having uniform or linearly graded buffers.
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On the basis of this modeling work we show that the S-graded layer exhibits misfit dislocation-free regions near the substrate interface and the free surface (or device interface). The equilibrium peak misfit dislocation density as well as the thicknesses of the dislocation-free regions may be tailored by design of the compositional profile; this in turn should enable minimization of the density of electronically active threading dislocations at the top surface. 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subjects	Buffer layers Density Devices Dislocation density Gallium arsenide Optimization Surface chemistry Threading dislocations
title	S-Graded Buffet Layers for Lattice-Mismatched Heteroepitaxial Devices
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