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Structural and Electrical Characterization of Hydrophobic Direct-Bonded Silicon Interfaces

Published online by Cambridge University Press:  21 February 2011

Gordon Tam ,
F. Secco d'Aragona  and
N. David Theodore
Gordon Tam
Affiliation:
Advanced Custom Technologies
F. Secco d'Aragona
Affiliation:
Material Research and Strategic Technologies Motorola Inc., 2200 W. Broadway Road, Mesa, AZ 85202
N. David Theodore
Affiliation:
Material Research and Strategic Technologies Motorola Inc., 2200 W. Broadway Road, Mesa, AZ 85202
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Abstract

Direct wafer bonding is a viable technique for fabricating high-voltage devices. An understanding of the microstructure and electrical behavior of the bonded interface is critical for device fabrication. In this paper, we investigated the microstructure of the silicon-to-silicon bonded interface using cross-sectional transmission electron microscopy and the corresponding electrical behavior using spreading resistance probing. Results indicate that oxide precipitates were present at the bonded interface when Czochralski silicon wafer were used in the process. Oxide precipitates were noticeably absent from the bonded interface when float zone wafers were bonded to each other. We find that oxide precipitates at the interface arise not due to the residual oxide at the surface prior to wafer bonding but due to gettering of oxygen from the Czochralski wafer. Spreading resistance measurements show occurrence of a high resistivity region at the bonding interface whether or not oxide precipitates are present.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 318: Symposium Ca – Interface Control of Electrical, Chemical, and Mechanical Properties , 1993 , 299
Copyright
Copyright © Materials Research Society 1994

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References

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