Vibrational Spectroscopy Study of β and α RDX Deposits

Torres, Perla M.; Mercado, Liza; Cotte, Ismael; Hernandez, Samuel; Mina, Nairmen; Santana, Alberto; Chamberlain, R. Thomas; Lareau, and Richard; Castro, Miguel E.

doi:10.1021/jp0373550

Cited by 66 publications

(118 citation statements)

References 29 publications

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“…(3) and the average difference in assigned peaks in spectral range 0-4270 cm -1 is about 2 cm -1 . Standoff spectrum of C4 is in a good agreement with the spectrum obtained by other authors [5][6][7][8][9] and the average difference in assigned peaks in spectral range 0 -4270 cm -1 is about 2 cm -1 . One of the aims of the study is to study the influence of integration time and laser power on Raman cross section and to determine the integration time and laser power at which the optimal signal to noise (S/N) ratio is achieved for standoff Raman spectra.…”

Section: Standoff Raman Spectrum Of Plastic Explosive C4supporting

confidence: 79%

Untitled

2017

JNUS

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In this paper standoff Raman spectroscopy SRS system for explosive materials is developed. Standoff Raman detection of C4 substance under dark laboratory condition at 4 m distance is achieved. A frequency doubled Nd:YAG laser at 532 nm excitation is used. The Raman scattered light is collected by a telescope and then transferred via fiber optics cable to spectrograph and finally into CCD detector. Notch filter used to reject Rayleigh scattering light. Carbon tetrachloride CCL 4 and Acetone (CH 3 ) 2 CO are used as a calibration standard for the Raman measurements because of their strong and intensive scattering capability. Raman measurement of C4 explosive is also acquired using conventional Raman microscopy for verification of standoff Raman measurements. The effects of integration time and laser power on Raman cross section under dark condition were studied. Standoff Raman detection of C4 substance at 4 m distance under partially illuminated condition has been achieved and hence the effect of higher integration time was studied under the same condition.

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Section: Standoff Raman Spectrum Of Plastic Explosive C4supporting

confidence: 79%

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2017

JNUS

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“…The peak shape at the region from 2900 to 3100 cm −1 convinced that the our RDX sample was α polymorph, which was known to be the most stable form in the room tempertaure. 12 The HMX sample was also measured at confocal Raman microscope. The result was shown in Figure 4(c).…”

Section: Resultsmentioning

confidence: 99%

Standoff Raman Spectroscopic Detection of Explosive Molecules

Chung¹,

Cho

2013

Bulletin of the Korean Chemical Society

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We developed a standoff Raman detection system for explosive molecules (EMs). Our system was composed of reflective telescope with 310 mm diameter lens, 532 nm pulse laser, and Intensified Charge-Coupled Device (ICCD) camera. In order to remove huge background noise coming from ambient light, laser pulses with nanosecond time width were fired to target sample and ICCD was gated to open only during the time when the scattered Raman signal from the sample arrived at ICCD camera. We performed standoff experiments with military EMs by putting the detector at 10, 20 and 30 m away from the source. The standoff results were compared with the confocal Raman results. Based on our standoff experiments, we were able to observe the peaks in the range of 1200 and 1600 cm, where vibrational modes of nitro groups were appeared. The wave numbers and shapes of these peaks may serve as good references in detecting and identifying various EMs.

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“…For example, formation of RDX α-and β-crystalline phases has been observed to depend on the amount of RDX deposited from solutions onto surfaces, and different infrared spectral properties have been observed for the two phases. 26 The examples of explosives particles and residues in this manuscript are not intended to present a comprehensive study of particle size and sample preparation techniques for explosives detection; however, similar applications of the hyperspectral microscopy technique would be valuable for future systematic studies of the dependence of the infrared spectrum on particle morphology. For the examples presented in this manuscript, two sample preparation methods were used.…”

Section: Methodsmentioning

confidence: 99%

Hyperspectral microscopy of explosives particles using an external cavity quantum cascade laser

Phillips

Bernacki

2012

Opt. Eng

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Abstract. Using infrared hyperspectral imaging, microscopy of small particles of the explosives compounds RDX, tetryl, and PETN with near diffraction-limited performance is demonstrated. The custom microscope apparatus includes an external cavity quantum cascade laser illuminator scanned over its tuning range of 9.13 to 10.53 μm in 4 s, coupled with a microbolometer focal plane array to record infrared transmission images. The hyperspectral microscopy technique is used to study the infrared absorption spectra of individual explosives particles, and demonstrate subnanogram detection limits.

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Vibrational Spectroscopy Study of β and α RDX Deposits

Cited by 66 publications

References 29 publications

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Standoff Raman Spectroscopic Detection of Explosive Molecules

Hyperspectral microscopy of explosives particles using an external cavity quantum cascade laser

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