A Computational Study of Density of Some High Energy Molecules

Moxnes, John F.; Hansen, Finn Knut; Jensen, Tomas Lunde; Sele, Marta Lill; Unneberg, Erik

doi:10.1002/prep.201600105

Cited by 8 publications

(5 citation statements)

References 28 publications

(33 reference statements)

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“…This suggests that the anarot methodology could be used to determine the range of low-energy crystal structures that could be adopted by a nitroaromatic energetic molecule within the Ψ mol approach to crystal structure prediction 88 and thus could improve the prediction of crystal packing from the molecular diagram of new energetic molecules. 74 This method is suitable as an initial approximation of the potential energy landscape, but the relative energy differences in Table 1 are large in comparison with the lattice energy differences between polymorphs, which are usually much less than 5 kJ mol –1 for small molecules. 89 The conclusion that analytical rotation does not reproduce relative electrostatic energies well was also reached in the study on the transferability of electrostatic models between polypeptides.…”

Section: Discussionmentioning

confidence: 99%

“…It seems that cell geometries can be obtained relatively accurately and very quickly without recalculating the charge density as the nitro groups rotate (Table ), by analytically rotating the multipole moments. This suggests that the anarot methodology could be used to determine the range of low-energy crystal structures that could be adopted by a nitroaromatic energetic molecule within the Ψ mol approach to crystal structure prediction and thus could improve the prediction of crystal packing from the molecular diagram of new energetic molecules . This method is suitable as an initial approximation of the potential energy landscape, but the relative energy differences in Table are large in comparison with the lattice energy differences between polymorphs, which are usually much less than 5 kJ mol –1 for small molecules .…”

Section: Discussionmentioning

confidence: 99%

“…This surface has recently been used to define the molecular volume for use in estimating the density of energetic materials. 74 The electrostatic potential on this isodensity surface is approximately 3 Å from the nearest nucleus in the molecule and so gives the electrostatic potential sampled by the nonhydrogenic nuclei that would be in van der Waals contact with the molecule in the crystal. Lattice energies were calculated using a combination of the ISA distributed multipoles, to obtain the electrostatic energy, and the exp-6 FIT potential, for all other contributions using DMACRYS.…”

Section: Methodsmentioning

confidence: 99%

“…This isodensity surface was chosen as the majority of electrostatic potential studies on energetic materials and their sensitivities use this surface, following the suggestion by Bader, , as it can include more than 95% of a molecule’s true electronic density. This surface has recently been used to define the molecular volume for use in estimating the density of energetic materials . The electrostatic potential on this isodensity surface is approximately 3 Å from the nearest nucleus in the molecule and so gives the electrostatic potential sampled by the nonhydrogenic nuclei that would be in van der Waals contact with the molecule in the crystal.…”

Section: Methodsmentioning

confidence: 99%

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Charge Distributions of Nitro Groups Within Organic Explosive Crystals: Effects on Sensitivity and Modeling

et al. 2019

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The charge distribution of NO 2 groups within the crystalline polymorphs of energetic materials strongly affects their explosive properties. We use the recently introduced basis-space iterated stockholder atom partitioning of high-quality charge distributions to examine the approximations that can be made in modeling polymorphs and their physical properties, using 1,3,5-trinitroperhydro-1,3,5-triazine, trinitrotoluene, 1-3-5-trinitrobenzene, and hexanitrobenzene as exemplars. The NO 2 charge distribution is strongly affected by the neighboring atoms, the rest of the molecules, and also significantly by the NO 2 torsion angle within the possible variations found in observed crystal structures. Thus, the proposed correlations between the molecular electrostatic properties, such as trigger-bond potential or maxima in the electrostatic potential, and impact sensitivity will be affected by the changes in conformation that occur on crystallization. We establish the relationship between the NO 2 torsion angle and the likelihood of occurrence in observed crystal structures, the conformational energy, and the charge and dipole magnitude on each atom, and how this varies with the neighboring groups. We examine the effect of analytically rotating the atomic multipole moments to model changes in torsion angle and establish that this is a viable approach for crystal structures but is not accurate enough to model the relative lattice energies. This establishes the basis of transferability of the NO 2 charge distribution for realistic nonempirical model intermolecular potentials for simulating energetic materials.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Charge Distributions of Nitro Groups Within Organic Explosive Crystals: Effects on Sensitivity and Modeling

et al. 2019

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“…The optimized structures and vibrational analyses of the designed molecules were carried out by Gaussian 03 software 23 combined with B3LYP method at 6-31G (d,p) level of density functional theory (DFT) which have demonstrated as a reliable way to calculate the accurate energy. [24][25][26][27] The optimizations were performed without any symmetry restrictions using the default convergence criteria in the Gaussian program. All of the optimized structures were characterized to be true local energy minima on the potential energy surfaces without imaginary frequencies.…”

Section: Computational Approachmentioning

confidence: 99%

Molecule Design and Properties of Cyclic Energetic Materials Based on Nitroguanidine and 1,1-Diamino-2,2-Dinitroethene

Xiao¹,

Jin²,

Zhou³

et al. 2018

Quim. Nova

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A series of cyclic energetic derivatives based on nitroguanidine and 1,1-diamino-2,2-dinitroethene were theoretically designed. The spatial structures, infrared spectrometry, heats of formation, electronic structures, detonation properties, and thermal stabilities of these designed compounds were fully investigated by density functional theory. It is found that all the designed compounds have moderate stabilities (bond dissociation energies range from 11.3 to 99.0 kJ mol-1), high crystal densities (from 1.9589 to 2.00188 g cm-3), high positive heats of formation (from 649.6 to 1060.8 kJ mol-1) and high positive heats of detonation (from 1074.77 to 1332.06 cal g-1) which lead to the excellent detonation properties (detonation velocities range from 8.71 to 9.05 km s-1 while detonation pressures range from 35.47 to 38.55 GPa). Electronic structures such as electrostatic potentials on the surface, electronic densities, highest occupied molecular orbitals, lowest unoccupied molecular orbitals and their energy gaps were also simulated to give a better understanding of chemical and physical properties of these compounds. All the data may shine lights on the explosive searching and synthesis.

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Assessment of Recent Researches for Reliable Prediction of Density of Organic Compounds as well as Ionic Liquids and Salts Containing Energetic Groups at Room Temperature

Keshavarz

Makvandi

2020

Propellants Explo Pyrotec

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Organic and ionic compounds containing energetic groups have wide applications in industries because they can release their stored chemical energy upon external stimuli. Many different methods have been developed in recent years for reliable prediction of the densities of these compounds at room temperature because their detonation performance depends strongly on density. This work reviews the best available predictive models for important classes of energetic organic and ionic compounds that reduce the high costs of synthesis and development of the new proposed compounds. The advantages and limitations of different methods are discussed and compared for different kinds of neutral and ionic energetic compounds. Among different approaches, quantum‐chemical methods based on molecular surface electrostatic potential (MESP) and quantitative structure‐property relationship (QSPR) approaches are attractive for scientists and industries in recent years because they can be applied for a wide range of various types of compounds. For 25 neutral energetic organic compounds and 11 energetic ionic compounds where the percentages of deviations of the outputs of quantum‐chemical MESP‐based methods are large, it is shown that the outputs of the best available QSPR methods, which were embedded in new computer code (EMDB_1.0), are more accurate.

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A Computational Study of Density of Some High Energy Molecules

Cited by 8 publications

References 28 publications

Charge Distributions of Nitro Groups Within Organic Explosive Crystals: Effects on Sensitivity and Modeling

Charge Distributions of Nitro Groups Within Organic Explosive Crystals: Effects on Sensitivity and Modeling

Molecule Design and Properties of Cyclic Energetic Materials Based on Nitroguanidine and 1,1-Diamino-2,2-Dinitroethene

Assessment of Recent Researches for Reliable Prediction of Density of Organic Compounds as well as Ionic Liquids and Salts Containing Energetic Groups at Room Temperature

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