Control of Explosive Chemical Reactions by Optical Excitations: Defect-Induced Decomposition of Trinitrotoluene at Metal Oxide Surfaces

Tsyshevsky, Roman; Rashkeev, Sergey N.; Kuklja, Maija M.

doi:10.3390/molecules28030953

Molecules

2023

DOI: 10.3390/molecules28030953

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Control of Explosive Chemical Reactions by Optical Excitations: Defect-Induced Decomposition of Trinitrotoluene at Metal Oxide Surfaces

Roman Tsyshevsky

Sergey N. Rashkeev

Maija M. Kuklja

Abstract: Interfaces formed by high energy density materials and metal oxides present intriguing new opportunities for a large set of novel applications that depend on the control of the energy release and initiation of explosive chemical reactions. We studied the role of structural defects at a MgO surface in the modification of electronic and optical properties of the energetic material TNT (2-methyl-1,3,5-trinitrobenzene, also known as trinitrotoluene, C7H5N3O6) deposited at the surface. Using density functional theo… Show more

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2024

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QSPR study to predict the detonation velocity of explosives with emphasis on studying the electronic spectra of RDX

Hamid,

Saeed

2024

J. Basrah Res. (Sci.)

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The study devoted to calculate and interpret the electronic spectra of the RDX molecule. The six isomers of the RDX molecule were geometry optimized with the MP2/cc-pVTZ level of theory. The twist isomer was shown to be the most stable isomer. The electronic spectra of the six isomers were calculated with acetonitrile as a solvent. The electronic spectra were calculated using the PBE0/def2-tzvppd level of theory in acetonitrile as a solvent. The combined PBE0/def2-tzvppd// MP2/cc-pVTZ methods succeeded in reproduce fairly the experimentally measured main band at 236 nm. The calculated wavelength was 237 nm and the band was shown as mainly originated from the HOMO to LUMO transition with a transition probability of 0.49688 which is 49.4% of the overall transitions responsible for this band. The calculated spectrum of the most stable isomer (twist) was most relevant to the experimental spectrum. In order to predict the detonation velocity of explosives the Quantity Structural-Property Relationship calculations were done and a statistical empirical equation was built based on the measured detonation velocity of well-known explosives and several structural and electronic descriptors.

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QSPR study to predict the detonation velocity of explosives with emphasis on studying the electronic spectra of RDX

Hamid,

Saeed

2024

J. Basrah Res. (Sci.)

View full text Add to dashboard Cite

show abstract

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Control of Explosive Chemical Reactions by Optical Excitations: Defect-Induced Decomposition of Trinitrotoluene at Metal Oxide Surfaces

Cited by 1 publication

References 54 publications

QSPR study to predict the detonation velocity of explosives with emphasis on studying the electronic spectra of RDX

QSPR study to predict the detonation velocity of explosives with emphasis on studying the electronic spectra of RDX

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