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Heteroepitaxial HgCdTe/CdZnTe/GaAs/Si Materials for Infrared Focal Plane Arrays

Published online by Cambridge University Press:  25 February 2011

S.M. Johnson ,
J.B. James ,
W.L. Ahlgren ,
W.J. Hamilton Jr. ,
M. Ray  and
G.S. TOMPA
S.M. Johnson
Affiliation:
Santa Barbara Research Center, 75 Coromar Drive, Goleta, CA 93117
J.B. James
Affiliation:
Santa Barbara Research Center, 75 Coromar Drive, Goleta, CA 93117
W.L. Ahlgren
Affiliation:
Santa Barbara Research Center, 75 Coromar Drive, Goleta, CA 93117
W.J. Hamilton Jr.
Affiliation:
Santa Barbara Research Center, 75 Coromar Drive, Goleta, CA 93117
M. Ray
Affiliation:
Santa Barbara Research Center, 75 Coromar Drive, Goleta, CA 93117
G.S. TOMPA
Affiliation:
EMCORE Corporation, 35 Elizabeth Avenue, Somerset, NJ 08873
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Abstract

The structural properties of LPE-grown HgCdTe on heteroepitaxial MOCVD-grown CdZnTe/GaAs/Si substrates were evaluated using high-resolution x-ray diffraction techniques and TEM. Large tilts {up to 4°} between CdZnTe layers and GaAs/Si substrates are a general characteristic of this heteroepitaxial system and are are attributed to the interaction of closely spaced misfit dislocations that arrange to form a tilt boundary. Either {112}CdTe or {552}CdTe can be grown on {112}GaAs/Si; the {552} was shown to result from a first-order twinning operation of {112}. Lamnella {111} microtwins in {111}CdZnTe/{100}GaAs/Si substrates, measured by x-ray techniques, are not readily propagated into the LPE-grown HgCdTe layer. The x-ray FWHM of the LPE HgCdTe is typically at least a factor of two lower than that of the Si-based substrate from annealing and due to the increased thickness of the layer; both mechanisms promote dislocation interaction and annihilation. High performance MWIR and LWIR HgCdTe 128×128 hybrid focal plane arrays were fabricated on these Si-based substrates. An array average of ROAj = 17.8 ohmcm2 for a cutoff wavelength of 10.8 μm at 78K was demonstrated.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 216: Symposium T – Long-Wavelength Semiconductor Devices, Materials and Processes , 1990 , 141
Copyright
Copyright © Materials Research Society 1991

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References

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