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Fourier Transform Infrared Imaging to Elucidate Failures in Polyurethanes

Published online by Cambridge University Press:  12 February 2013

Ellen V. Miseo  and
Jay R. Powell
Ellen V. Miseo
Affiliation:
Analytical Answers, Inc., 4 Arrow Drive, Woburn, MA 01801-2040
Jay R. Powell
Affiliation:
Analytical Answers, Inc., 4 Arrow Drive, Woburn, MA 01801-2040
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Abstract

Polyurethanes are widely used, from medical devices to electrical materials to consumer goods. These materials have chemical stability issues which impact the mechanical stability. Infrared micro spectroscopy has been used to study polyurethane degradation, but due to experimental limitations, samples examined were no smaller than approximately 15 microns on a side. Because of the complex chemistry of urethanes, chemical examination of the material on a much higher spatial resolution scale would be valuable.

A relatively new technique, Attenuated Total Reflection Fourier Transform Infrared Spectrochemical MicroImaging has been used to examine degraded polyester urethanes. Rather than using a single-element detector, a two dimensional array detector generates thousands of spectra simultaneously. In addition, a germanium prism generates a magnification effect; resulting in a significantly higher spatial resolution. The net output of the analysis is a hypercube of high resolution infrared spectra showing urethane degradation progression on a much smaller spatial scale than was previously possible.

Keywords

infrared (IR) spectroscopypolymerdefects
Type
Articles
Information
MRS Online Proceedings Library (OPL) , Volume 1522: Symposium PP – Frontiers of Chemical Imaging—Integrating Electrons, Photons and Ions , 2013 , mrsf12-1522-pp03-03
Copyright
Copyright © Materials Research Society 2013

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References

REFERENCES

Miseo, E.V., Guilmette, L. W., Industrial Problem Solving by Microscopic Fourier Transform Infrared Spectrophotometry. The Design, Sample Handling and Applications of Infrared Microscopes ASTM STP 949, 1987: p. 97–107.10.1520/STP19443SCrossRefGoogle Scholar
Kodali, D.R., et al. . Applied Spectroscopy, 1991. 45(8): p. 13101317.10.1366/0003702914335878CrossRefGoogle Scholar
Lewis, E.N., et al. . Analytical Chemistry, 1995. 67(19): p. 33773381.10.1021/ac00115a003CrossRefGoogle Scholar
Kidder, L.H., et al. . Optics Letters, 1997. 22(10): p. 742744.10.1364/OL.22.000742CrossRefGoogle Scholar
Milosevic, M. “Internal Reflection and ATR Spectroscopy”. 2012: John Wiley & Sons, Inc.CrossRefGoogle Scholar
Kierein-Young, Kathryn S., F.A.K., Boardman, Joseph W., Crocombe, Richard A. and Wright, Norman A.. Hyperspectral Remote Sensing Analysis: Tools for Analytical Chemistry. in Fourier Transform Spectroscopy, Twelfth International Conference: Waseda University Press.Google Scholar