Your search keyword '"Emmons, Erik D."' showing total 3 results

1. Characterization of Polymorphic States in Energetic Samples of 1,3,5-Trinitro-1,3,5-Triazine (RDX) Fabricated Using Drop-on-Demand Inkjet Technology.

Author

EMMONS, ERIK D., FARRELL, MIKELLA E., HOLTHOFF, ELLEN L., TRIPATHI, ASHISH, GREEN, NORMAN, MOON, RAPHAEL P., GUICHETEAU, JASON A., CHRISTESEN, STEVEN D., PELLEGRINO, PAUL M., and III, AUGUSTUS W. FOUNTAIN

Subjects

*POLYMORPHISM (Crystallography), *CYCLONITE, *COMPARATIVE studies, *SPECTRUM analysis, UNITED States armed forces

Abstract

The United States Army and the first responder community are evaluating optical detection systems for the trace detection of hazardous energetic materials. Fielded detection systems must be evaluated with the appropriate material concentrations to accurately identify the residue in theater. Trace levels of energetic materials have been observed in mutable polymorphic phases and, therefore, the systems being evaluated must be able to detect and accurately identify variant sample phases observed in spectral data. In this work, we report on the novel application of drop-on-demand technology for the fabrication of standardized trace 1,3,5-trinitro-1,3,5-triazine (RDX) samples. The drop-on-demand sample fabrication technique is compared both visually and spectrally to the more commonly used drop-and-dry technique. As the drop-on-demand technique allows for the fabrication of trace level hazard materials, concerted efforts focused on characterization of the polymorphic phase changes observed with low concentrations of RDX commonly used in drop-on-demand processing. This information is important when evaluating optical detection technologies using samples prepared with a drop-on-demand inkjet system, as the technology may be “trained” to detect the common bulk α phase of the explosive based on its spectral features but fall short in positively detecting a trace quantity of RDX (β-phase). We report the polymorphic shifts observed between α- and β-phases of this energetic material and discuss the conditions leading to the favoring of one phase over the other. [ABSTRACT FROM AUTHOR]

Published

2012

2. Recent Advances and Remaining Challenges for the Spectroscopic Detection of Explosive Threats.

Author

Fountain, Augustus W., Christesen, Steven D., Moon, Raphael P., Guicheteau, Jason A., and Emmons, Erik D.

Subjects

*SPECTRUM analysis, *EXPLOSIVES, *SENSITIVITY analysis, *ALGORITHMS, UNITED States armed forces

Abstract

In 2010, the U.S. Army initiated a program through the Edgewood Chemical Biological Center to identify viable spectroscopic signatures of explosives and initiate environmental persistence, fate, and transport studies for trace residues. These studies were ultimately designed to integrate these signatures into algorithms and experimentally evaluate sensor performance for explosives and precursor materials in existing chemical point and standoff detection systems. Accurate and validated optical cross sections and signatures are critical in benchmarking spectroscopic-based sensors. This program has provided important information for the scientists and engineers currently developing trace-detection solutions to the homemade explosive problem. With this information, the sensitivity of spectroscopic methods for explosives detection can now be quantitatively evaluated before the sensor is deployed and tested. [ABSTRACT FROM AUTHOR]

Published

2014

3. Bioaerosol Analysis with Raman Chemical Imaging Microspectroscopy.

Author

Tripathi, Ashish, Jabbour, Rabih E., Guicheteau, Jason A., Christesen, Steven D., Emge, Darren K., Fountain, Augustus W., Bottiger, Jerold R., Emmons, Erik D., and Snyder, A. Peter

Subjects

*RAMAN spectroscopy, *IMAGING systems in chemistry, *POLYSTYRENE, *BACILLUS (Bacteria), *WATERBORNE infection, *SPECTRUM analysis

Abstract

Raman chemical imaging microspectroscopy is evaluated as a technology for waterborne pathogen and bioaerosol detection. Raman imaging produces a three-dimensional data cube consisting of a Raman spectrum at every pixel in a microscope field of view. Binary and ternary mixtures including combinations of polystyrene beads, Gram- positive Bacillus anthracis, B. thuringiensis, and B. atrophaeus spores, and B. cereus vegetative cells were investigated by Raman imaging for differentiation and characterization purposes. Bacillus spore aerosol sizes were varied to provide visual proof for corroboration of spectral assignments. Conventional applications of Raman imaging consist of differentiating relatively broad areas of a sample in a microscope field of view. The spectral angle mapping data analysis algorithm was used to compare a library spectrum with experimental spectra from pixels in the microscope field of view. This direct one-to-one matching is straightforward, does not require a training set, is independent of absolute spectral intensity, and only requires univariate statistics. Raman imaging is expanded in its capabilities to differentiate and distinguish between discrete 1-6 μm size bacterial species in single particles, clusters of mixed species, and bioaerosols with interference background particles. [ABSTRACT FROM AUTHOR]

Published

2009