Computational study of energetic nitrogen‐rich derivatives of 1,1′‐ and 5,5′‐bridged ditetrazoles

Zhu, Weihua; Zhang, Chenchen; Wei, Tao; Xiao, Heming

doi:10.1002/jcc.21819

Cited by 44 publications

(35 citation statements)

References 78 publications

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“…However, the four nitrogen atoms in this system that are attached directly to each other will destabilizes the entire fused system and the lack of energetic dense substituents makes the molecule possess low detonation performance. As the nitrogenous heterocyclic compounds possess large densities and high heat of formations, introducing two N‐oxide into pyrazino [2, 3‐e] [1, 2, 3, 4] tetrazine may overcome the problem of destabilization and substituting nitrogenous heterocycles and give the molecule to have high energetic properties.…”

Section: Introductionmentioning

confidence: 99%

Theoretical Studies on Energetic Nitrogen‐Rich Heterocyclic Substituted Derivatives of Pyrazino [2, 3‐e] [1, 2, 3, 4] Tetrazine‐1, 3‐di‐N‐oxide

Khan

Zhu

2019

ChemistrySelect

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We used an effective approach to design a series of new energetic compounds by incorporating nitrogenous heterocyclic substituents (furazan, imidazole, triazole, oxazine, pyrazine, triazine, and tetrazine) together with two N-oxide into pyrazino [2, 3-e] [1, 2, 3, 4] tetrazine molecule. Their heat of formations (HOFs) were calculated by employing DFTÀ B3LYP method with 6-311G** basis set. The findings reveal that the substitution of the -N 3 and N 3 -substituted tetrazine groups causes a sufficiently large increase in the HOFs. The energy gap decreases for all the derivatives. The calculated values of detonation pressure and detonation velocity show that the substitution of the NF 2 -, N (NO 2 ) 2 -, and ONO 2 -substituted heterocycles is very helpful to enhance the detonation properties. The calculated bond dissociation energy values for few weakest bonds reflect that the nitrogen-nitrogen (N2-N3) bond in the pyrazino [2, 3-e] [1, 2,3, 4] tetrazine molecule is a weakest bond and ring cleavage may happen during thermal decomposition except for nitroxy (-ONO 2 ) substituted derivatives, where O-NO 2 bond may rupture rather than ring cleavage. By considering detonation properties, thermal stabilities, and other properties, 9 of our designed compounds may be consider as potential candidates of high energy density compounds because of their ambitious detonation performance and suitable thermal stability.[a] R.

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Section: Introductionmentioning

confidence: 99%

Theoretical Studies on Energetic Nitrogen‐Rich Heterocyclic Substituted Derivatives of Pyrazino [2, 3‐e] [1, 2, 3, 4] Tetrazine‐1, 3‐di‐N‐oxide

Khan

Zhu

2019

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“…Quantum chemistry calculations have proven to be a valuable tool in studying structure–property relationships for compounds that would otherwise be difficult and dangerous to synthesize in the laboratory . In this study, the heats of formation and decomposition pathways for the N 10 compound and its functionalized derivatives are determined using quantum chemistry composite approaches (CA) and density functional theory (DFT) intrinsic reaction coordinate (IRC) analysis.…”

Section: Introductionmentioning

confidence: 99%

“…Quantum chemistry calculations have proven to be a valuable tool in studying structure-property relationships for compounds that would otherwise be difficult and dangerous to synthesize in the laboratory. [18][19][20][21][22] In this study, the heats of formation and decomposition pathways for the N 10 compound and its functionalized derivatives are determined using quantum chemistry composite approaches (CA) and density functional theory (DFT) intrinsic reaction coordinate (IRC) analysis. The main goal of this work is to probe the properties of the N 10 compounds by modifying the structure through the inclusion of substituents in the design of new energetic materials with acceptable thermal stabilities and energy content.…”

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confidence: 99%

Heats of formation and thermal stability of substituted 1,1′‐Azobis(tetrazole) compounds with an extended nitrogen chain

Pimienta

Patkowski

2018

Int J of Quantum Chemistry

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The molecular structures of 1,1′‐Azobis(tetrazole) (N10) and monosubstituted compounds involving F, CH3, CN, NH2, OH, OCH3, N3, NF2, NO2, and CH2NO2 groups are investigated using density functional theory. The heats of formation of these compounds are investigated using ab initio composite methods. Intrinsic reaction coordinate calculations are performed to determine the energies along the decomposition pathways. The optimized geometries of the N10 compounds indicate planar configurations consisting of aromatic nitrogen–nitrogen and carbon–nitrogen bonds. The stability and energy content of the substituted compounds are highly correlated with the nature of the substituents. Electron‐donating groups reduce the heats of formation but increase the exothermicity of the decomposition. The decomposition of the N10 compounds is classified into two general pathways: (1) a scheme involving straight‐up decomposition and (2) a scheme involving functional rearrangement. Compounds undergoing decomposition pathway (1) are more exothermic with lower rate‐determining activation barriers than those undergoing the latter pathway (2).

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“…1,3,5-Triazido-2,4,6-trinitrobenzene (TATNB) [33] is a green powerful lead-free initiating explosive with the density of 1.805 g cm À3 [33], D f H8 c of 1131.3 kJ mol À1 [38], VOD of 8.58 km s À1 [38], and impact sensitivity of 5.0 N m [33]. The effect of ÀN 3 group for increasing D f H8 c has also been studied for tetrazines [34], triazoles [36], and tetrazoles [39].…”

Section: Introductionmentioning

confidence: 99%

Assessing the Detonation Performance of New Tetrazole Base High Energy Density materials

Jafari

Ghani

Keshavarz

et al. 2018

Propellants Explo Pyrotec

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Tetrazole derivatives containing energetic groups can be considered as high energy density materials due to their high positive standard enthalpies of formation and high densities. The effects of two energetic groups ÀNO 2 and ÀN 3 as well as stabilizing group ÀNH 2 and methyl group are investigated for assessment of detonation performance of 50 tetrazole derivatives where 12 derivatives have been synthesized. The velocities of detonation and detonation pressures are estimated on the basis of two new predictive methods, which require the condensed phase standard enthalpy of formation (D f H8 c ) and crystal density(1). Quantum mechanical and quantitative structure-property relationship (QSPR) methods are used for calculation of D f H8 c . In order to calculate the 1 values, the electrostatic potentials mapped onto the 0.001 a.u. isosurface of electron densities of isolated molecules is used. Detonation performances of tetrazole derivatives are compared to three common high explosives, i. e. TNT, RDX, and HMX. Among many tetrazole derivatives, four new tetrazole derivatives are introduced as new potential high energy density materials.

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Computational study of energetic nitrogen‐rich derivatives of 1,1′‐ and 5,5′‐bridged ditetrazoles

Cited by 44 publications

References 78 publications

Theoretical Studies on Energetic Nitrogen‐Rich Heterocyclic Substituted Derivatives of Pyrazino [2, 3‐e] [1, 2, 3, 4] Tetrazine‐1, 3‐di‐N‐oxide

Theoretical Studies on Energetic Nitrogen‐Rich Heterocyclic Substituted Derivatives of Pyrazino [2, 3‐e] [1, 2, 3, 4] Tetrazine‐1, 3‐di‐N‐oxide

Heats of formation and thermal stability of substituted 1,1′‐Azobis(tetrazole) compounds with an extended nitrogen chain

Assessing the Detonation Performance of New Tetrazole Base High Energy Density materials

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