Raman Chemical Imaging of Explosive-Contaminated Fingerprints for Forensic Attribution

Augustus W. Fountain; Ashish Tripathi; Erik D. Emmons; Phillip G. Wilcox; Jason A. Guicheteau; Darren K. Emge; Steven D. Christesen

doi:10.1364/AIO.2011.AIWA1

Imaging and Applied Optics
OSA Technical Digest (CD) (Optica Publishing Group, 2011),
paper AIWA1
•https://doi.org/10.1364/AIO.2011.AIWA1

Raman Chemical Imaging of Explosive-Contaminated Fingerprints for Forensic Attribution

Augustus W. Fountain, Ashish Tripathi, Erik D. Emmons, Phillip G. Wilcox, Jason A. Guicheteau, Darren K. Emge, and Steven D. Christesen

Applied Industrial Optics: Spectroscopy, Imaging and Metrology 2011

Toronto Canada
10–14 July 2011
ISBN: 978-1-55752-914-5

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A. W. Fountain, A. Tripathi, E. D. Emmons, P. G. Wilcox, J. A. Guicheteau, D. K. Emge, and S. D. Christesen, "Raman Chemical Imaging of Explosive-Contaminated Fingerprints for Forensic Attribution," in Imaging and Applied Optics, OSA Technical Digest (CD) (Optica Publishing Group, 2011), paper AIWA1.

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Abstract

Raman chemical imaging (RCI) has been used to detect and identify explosives in contaminated fingerprints. Bright-field imaging is used to identify regions of interest within a fingerprint, which can then be examined to determine their chemical composition using RCI and fluorescence imaging. Results are presented where explosives in contaminated fingerprints are identified and their spatial distributions are obtained. Identification of explosives is obtained using Pearson’s cosine cross correlation technique using the characteristic region (500-1850 cm⁻¹) of the spectrum. This study shows the ability to identify explosives non-destructively so that the fingerprint remains intact for further biometric analysis. Prospects for forensic examination of contaminated fingerprints are discussed.

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