Surface Persistence of Trace Level Deposits of Highly Energetic Materials

Pacheco‐Londoño, Leonardo C.; Ruiz-Caballero, José L.; Ramírez-Cedeño, Michael L.; Infante-Castillo, Ricardo; Galán-Freyle, Nataly J.; Hernández‐Rivera, Samuel P.

doi:10.20944/preprints201909.0084.v1

Cited by 2 publications

(2 citation statements)

References 56 publications

(67 reference statements)

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“…Other signals that stand out include the band at 1234 cm -1 and the band at 1034 cm -1 for -N-C-N stretch; the signals at 1016 cm -1 for the combination -N-NO 2 stretch and in-plane C-H bending. [53][54][55] Fig. 2(b) shows the reflectance spectra of the seven soil samples, identified by Soil-1, Soil-2, Soil-3, Soil-4, Soil 5, Soil-6, and Soil-7.…”

Section: Qcl Mir Spectramentioning

confidence: 99%

“…[15] Several groups have demonstrated the capability of remote sensing of HE and others analytes using MIR laser spectroscopy with QCLs. [14,[16][17][18][19][20][21][22][23][24][25][26][27] The typical methods used to detect HE is destructive, require sampling, transferring samples to the lab, and performing a proper treatment of the sample for later detection. These methods include protocols based on gas chromatography-mass spectroscopy (GC-MS), gas chromatography-chemiluminescence (GC-CL), ion mobility spectrometry (IMS), [28] immunosensors, [29] electrophoresis, [30] fluorescence, [31] electrochemical methods, [30,32] high-pressure liquid chromatography (HPLC), [33,34] and HPLC-MS. [33] However, in situ detection of HE in the soil is not easy due to the presence of solid interfering materials such as organic and inorganic compounds, which vary for each type of soil [35][36][37] which makes this detection a challenge for the analyst.…”

Section: Introductionmentioning

confidence: 99%

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Self-Simulated Learning Artificial Intelligence for the Detection of High Explosives in Soil by Mid Infrared Laser Spectroscopy

Villareal-González¹,

Galán-Freyle²,

Pacheco‐Londoño³

et al.

Authorea

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A tunable mid-infrared (MIR) laser (quantum cascade laser, QCL) was used for the detection of TNT and RDX in soil samples at a concentration range from 0 to˜20% w/w. This type of sensing is complicated due to the complexity of the matrix, i.e., the diversity of compounds contained in soil. Thus, the high explosives (HE) detection in soil by QCL was assisted with an Artificial Intelligence (AI) system. AI managed to predict these HE in seven kinds of soils using minimum information Machine Learning (ML). The models were generated only from neat HE and soil spectra, without necessity using experimental spectra of the mixes. AI used these neat spectra to simulate the spectra of HEs/soil mixes. The simulated data was used to train the ML models and then were tested with real spectra of HEs/soils mixes. The method was designated as "Self-Simulated Learning Artificial Intelligence" (SSLAI). This methodology has advantages for applications in field scenarios where the matrices are unknown because SSLAI models do not need to be trained with real samples a priori. Models would only have to be fed with spectra for the neat components to train itself. The methodology was tested with mixes of seven soils and two explosives. Test samples were classified into three concentrations ranges: high concentration test (Test H > 10% w/w), medium concentration test (10% w/w > Test M > 3% w/w), and low concentration test (Test L < 3% w/w). The results show that it is possible to correctly predict these two HE/soil mixes from the simulated data. Specifically, for TNT and RDX, SSLAI achieved a high precision in the prediction for the high and medium concentration tests (Test H and Test M). However, for both samples with concentrations below 3% w/w (Test L), the number of false positives increased, and the precision was reduced.

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Section: Qcl Mir Spectramentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Self-Simulated Learning Artificial Intelligence for the Detection of High Explosives in Soil by Mid Infrared Laser Spectroscopy

Villareal-González¹,

Galán-Freyle²,

Pacheco‐Londoño³

et al.

Authorea

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A Mathematical Model for Sublimation of a Thin Film in Trace Explosive Detection Problem

Kudryashova

Titov

2022

Molecules

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Here, we introduce an advanced mathematical model for the sublimation of thin films of explosives. The model relies on the Hertz–Knudsen–Langmuir (HKL) equation that describes the vaporization rate of an explosive and controls the mass exchange between the surface and the ambient air. The latest experimental data on sublimation and diffusion of 2,4,6-trinitrotoluene (TNT) monocrystals were factored in, as well as the data on the sublimation rate of hexogen (RDX), octogen (HMX), and picramide (TNA) traces. To advance the mathematical model we suggested previously, we took into account the structure of a substrate on which a thin explosive layer was deposited. The measurement problem of the sublimation rate and limits of an explosive arises from developing and advancing remote detection methods for explosives traces. Using mathematical modelling, we can identify a detectable quantity of a specific explosive under given conditions. We calculated the mass of the explosive in the air upon sublimation of thin explosive films from the surfaces over a wide range of the parameters in question and made conclusions regarding the application limits of the devised standoff trace explosive detection techniques.

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Surface Persistence of Trace Level Deposits of Highly Energetic Materials

Cited by 2 publications

References 56 publications

Self-Simulated Learning Artificial Intelligence for the Detection of High Explosives in Soil by Mid Infrared Laser Spectroscopy

Self-Simulated Learning Artificial Intelligence for the Detection of High Explosives in Soil by Mid Infrared Laser Spectroscopy

A Mathematical Model for Sublimation of a Thin Film in Trace Explosive Detection Problem

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