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Abstract
With a predicted record heat formation, energy density, and an outstanding performance as a rocket propellant, dinitroacetylene stretches the imagination for what is possible in terms of organic chemical explosives and monopropellants. In this study, we employ quantum chemical methods to predict its thermodynamic properties, ionization potential, electron affinity, UV/Vis spectra, NMR, and vibrational spectra, and to investigate proposed decomposition mechanisms. While unimolecular decomposition pathways are predicted to have high activation energies, NOx radical species – commonly present in reaction mixtures of energetic materials – are found to significantly catalyze the decomposition of dinitroacetylene. This catalytic effect may explain previous unsuccessful synthesis attempts. A frontier orbital analysis suggests that partial reduction could increase C–N bond order, offering a strategy to stabilize this elusive high-energy-density material.
Supplementary materials
Title
Further computational details
Description
Further details on energy content comparisons, on the dinitroacetylene dianion, on other decomposition mechanisms and on dinitrosoacetylene derivatives. Predicted vibrational, UV-Vis and NMR spectroscopic data.
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Supplementary weblinks
Title
.log files for all structures
Description
Optimized geometries and .log files from Gaussian calculations.
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