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Focused Ion Beam Sample Preparation of Non-Semiconductor Materials

Published online by Cambridge University Press:  10 February 2011

M. W. Phaneuf
Affiliation:
Fibics Incorporated, 568 Booth Street, Ottawa, ON, CANADA
N. Rowlands
Affiliation:
Micrion Corporation, One Corporation Way, Peabody, MA 01960
G. J. C. Carpenter
Affiliation:
CANMET, Materials Technology Laboratory, 568 Booth Street, Ottawa, ON CANADA K1A 0G1.
G. Sundaram
Affiliation:
Micrion Corporation, One Corporation Way, Peabody, MA 01960
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Abstract

Focused Ion Beam (FIB) systems have been steadily gaining acceptance as specimen preparation tools in the semiconductor industry. This is largely due to the fact that such instruments are relatively commonplace as failure analysis tools in semiconductor houses, and are commonly used in the preparation of cross-sections for imaging under the ion beam or using an electron beam in an SEM. Additionally, the ease with which cross-sectional TEM specimens of semiconductor devices can be prepared using FIB systems has been well demonstrated. However, this technology is largely unknown outside the semiconductor industry. Relatively few references exist in the literature on the preparation of cross-sectional TEM specimens of non-semiconductor materials by FIB. This paper discusses a specific use of FIB technology in the preparation of cross-sectional TEM specimens of non-semiconductor samples that are difficult to prepare by conventional means. One example of such materials is commercial galvannealed steel sheet that is used to form corrosion resistant auto-bodies for the automobile industry. Cross-sectional TEM specimens of this material have proved difficult and time-intensive to prepare by standard polishing and ion milling techniques due to galvanneal's inherent flaking and powdering difficulties, as well as the different sputtering rates of the various Fe-Zn intermetallic phases present in the galvannealed coatings. TEM results from cross-sectional samples of commercial galvannealed steel coatings prepared by conventional ion milling and FIB techniques are compared to assess image quality, the size of the electron-transparent thin regions that can be readily prepared and the quality of samples produced by both techniques. Specimen preparation times for both techniques are reported.

Type
Research Article
Copyright
Copyright © Materials Research Society 1997

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