Investigating the Stabilizing Forces of Pentazolate Salts

Nonmetallic pentazolate (cyclo-N 5 − ) salts are novel polynitrogen high-energydensity materials with great potential and application prospects. Hydrogen bond networks play a vital role in improving the thermal stability of these compounds. In order to further increase the decomposition temperature (T d ) and attain a more thorough exploration of these compounds, we evaluated and visualized the energy of hydrogen bonds (E_HBs) and the effects of HBs on T d , aromaticity, and the Mayer bond order (MBO). The increase in the total E_HBs can increase the T d , such as with 3,6,7-triamino-7H-[1,2,4]triazolo[4,3-b][1,2,4]triazol-2-ium and biguanidinium pentazolates. Moreover, an increase in the maximum E_HBs can reduce the aromaticity of the cyclo-N 5 − anion and increase the difference between the maximum and minimum MBO, like 3,9-diamino-6,7-dihydro-5H-bis ([1,2,4]triazolo)[4,3e:3′,4′-g][1,2,4,5]tetrazepine-2,10-diium and O-(carboxymethyl)hydroxylammonium pentazolates. In addition, increasing the number of donors of hydrogen bonds, especially the proportion of O−H bonds, can significantly increase the T d of pentazolate salts.

Section: Introductionmentioning

confidence: 99%

Effect of Hydrogen Bond Interaction on the Decomposition Temperature, Aromaticity, and Bond Order of Nonmetallic Pentazolate Salts

Jiang

et al. 2022

“…Polynitrogen materials have attracted substantial interest in materials science because of their promising applications in modern military and aerospace fields. − As a representative polynitrogen compound, the five-membered pentazolate anion, c -N 5 – , which was not synthesized and isolated in bulk until 2017, has become an attractive scaffold for the design and synthesis of energetic materials and inorganic ferrocene analogues. − Currently, the development of nonmetallic pentazolate salts is receiving increased attention in the field of pentazole chemistry because of the prospects of such salts to be promising explosives.…”

Section: Introductionmentioning

confidence: 99%

Anion–Cation Bonding and Structure–Property Relationships of Three cyclo-Pentazolate Compounds

Yang

Chen

et al. 2021

Self Cite

The all-nitrogen cyclo-pentazolate (c-N5 –) anion has attracted considerable attention because of its potential applications in high-energy density materials. However, achieving comprehensive insight into the chemical properties of c-N5 – is challenging because of its complex chemical behavior. To elucidate this behavior, we stabilized the c-N5 – anion by forming its triaminoguanidinium (1) and 4-nitro-(3,4-diamino-1,2,4-triazolium-5-yl)-1H-pyrazolium (2) salts and its cocrystal (3) of a 1:1 ratio of 3,3-dinitroazetidinium pentazolate to 3,3-dinitroazetidine. X-ray single-crystal analysis confirmed that the c-N5 – anion combined with a sterically hindered cation exhibits a highly active π-system. This is characterized by the intermolecular p−π, intramolecular π–π, and intermolecular nitro−π interactions, arising from the binding of the π-face of c-N5 – to the amino group, electron-rich aromatic ring, and nitro group, respectively. In combination with hydrogen bonds, these interactions synergistically sustain the stability of the c-N5 – derivatives. Electronic structure calculations provided additional information on the physicochemical properties of these compounds. Remarkably, the predicted detonation velocity of 1 is higher than that of RDX among the new materials. This study broadens the understanding of the bonding of c-N5 – with its counterions and sheds more light on the structure–property relationships of pentazolate compounds.

“…18−26 Energetic cocrystals can alter the solubility and hygroscopicity of their components and can possess better thermal and mechanical stability in comparison to their more energetic pure components. 25,27,28 A defect of most energetic cocrystals is that the detonation performance of the high-energetic components is dragged down by the lessenergetic or nonenergetic coformers. 25,29 compounds with positive and negative oxygen balances (OBs), respectively, may have higher detonation performance in comparison to their components (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

“…Cocrystallizing energetic compounds with heterogeneous solid components to form cocrystals has been an emerging method of improving the performance of energetic materials in the past 10 years. − Energetic cocrystals can alter the solubility and hygroscopicity of their components and can possess better thermal and mechanical stability in comparison to their more energetic pure components. ,, A defect of most energetic cocrystals is that the detonation performance of the high-energetic components is dragged down by the less-energetic or nonenergetic coformers. , Recently Bennion and Matzger proposed that cocrystals composed of energetic compounds with positive and negative oxygen balances (OBs), respectively, may have higher detonation performance in comparison to their components (Figure ). However, to date existing energetic cocrystals whose composition fits the above description are very scarce, ,, and only one of them (composed of ammonium dinitramide and pyrazine 1,4-dioxide) achieved the detonation performance improvement noted above.…”

Section: Introductionmentioning

confidence: 99%

Amphoteric Ionization and Cocrystallization Synergistically Applied to Two Melamine-Based N-Oxides: Achieving Regulation for the Comprehensive Performance of Energetic Materials

Feng

Chen

et al. 2021

The development of new energetic materials with good comprehensive performance often occurs at a glacial pace because of the contradiction between energy and safety. Herein, the synergy between amphoteric ionization and cocrystallization is found to be an effective strategy for regulating the comprehensive performance of energetic materials. The strategy was successfully applied to two amphoteric melamine-based N-oxides, namely 2,4,6-triamino-1,3,5-triazine 1,3-dioxide (TTDO) and 4,6-diamino-3-hydroxy-2-oxo-2,3-dihydro-1,3,5-triazine 1-oxide (DDTO). Pairing protonated and deprotonated TTDO and DDTO with different anions and cations allowed us to obtain many new energetic compounds with various properties. Among them, the perchlorate salts TTDO+PCL– and DDTO+PCL– composed of the oxidant component ClO4 – and oxidant-deficient TTDO or DDTO exhibit satisfying detonation performance but poor safety as for many high-energetic compounds. Hence, a cocrystallization strategy of cocrystallizing energetic compounds with positive and negative oxygen balances (OBs) was successfully used for DDTO+PCL– and DDTO, resulting in the formation of the energetic cocrystal (DDTO+PCL–)·DDTO with outstanding comprehensive performance. (DDTO+PCL–)·DDTO overcomes the general detonation performance tradeoff disadvantage of cocrystals, and its safety, especially the thermal safety, is superior to that of DDTO+PCL–. The crystal structure cohesion and the reason for the increasing stability of the cocrystal (DDTO+PCL–)·DDTO were analyzed. Our study provides an inspiration for regulating the comprehensive performance of energetic materials.