Molecular and Crystal Features of Thermostable Energetic Materials: Guidelines for Architecture of “Bridged” Compounds

Li, Hui; Zhang, Lei; Petrutik, Natan; Wang, Kangcai; Ma, Qing; Shem‐Tov, Daniel; Zhao, Fengqi; Gozin, Michael

doi:10.1021/acscentsci.9b01096

Cited by 104 publications

(76 citation statements)

References 101 publications

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“…Covalent bond energies were calculated by the integrated value of crystal orbital Hamilton population (COHP) at the band energy using the HASEM package. [ 40,41 ]…”

Section: Methodsmentioning

confidence: 99%

Novel All‐Nitrogen Molecular Crystals of Aromatic N₁₀

et al. 2020

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Nitrogen has unique bonding ability to form single, double, and triple bonds, similar to that of carbon. However, a molecular crystal formed by an aromatic polynitrogen similar to a carbon system has not been found yet. Herein, a new form of stable all‐nitrogen molecular crystals consisting of only bispentazole N10 molecules with exceedingly high energy density is predicted. The crystal structures and the conformation of N10 molecules are strongly correlated, both depending on the applied external pressure. These molecular crystals can be recovered upon the release of the pressure. The first‐principles molecular dynamics simulations reveal that these all‐nitrogen materials decompose at temperatures much higher than room temperature. The decompositions always start from breaking off N2 molecules from the nitrogen ring and can release a large amount of energy. These new polynitrogens are aromatic and are more stable than all the other polynitrogen crystals reported previously, providing a new green strategy to get all‐nitrogen, nonpolluting high energy density materials without introducing any metal or other guest stabilizer.

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“…Covalent bond energies were calculated by the integrated value of crystal orbital Hamilton population (COHP) at the band energy using the HASEM package. [ 40,41 ]…”

Section: Methodsmentioning

confidence: 99%

Novel All‐Nitrogen Molecular Crystals of Aromatic N₁₀

et al. 2020

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“…Here, Kissinger and Ozawa‐Doyle's methods are conducted based on the first exothermic peak temperatures ( T p ) measured at different heating rates of 5, 10, 15, 20 °C min −1 . As shown in Figure 4(d)‐4(f), under the heating rate of 5 °C min −1 , the decomposition of compound 6‐a commenced at 334.13 °C, and reached the peak at 347.91 °C incredibly, which is superior to most of heat‐resistant explosives such as TNT ( T d : 295 °C) [9], HNS ( T d : 318 °C) [6], bis(2,4,6‐trinitrophenyl) ether (BTNPE) ( T d : 256 °C) [1] and bis(2,4,6‐trinitrophenyl) (BTNPTE) ( T d : 310 °C) [1], but slightly lower than that of BPTAP ( T d : 366 °C). Compound 6‐b started to decompose at 324.5 °C, and arrived at 330.53 °C as its peak, which also surpasses those of TNT and HNS.…”

Section: Resultsmentioning

confidence: 96%

“…Additionally, the correlation between N‐heterocyclic skeleton and thermal stability as well as energy density has not been thoroughly referred [3–5]. Over the past few years, a series of thermally‐stable heterocyclic organic explosives emerged in large numbers, such as 1,3,4‐oxadiazole bridged trinitrophenyl derivatives [6], fused triazolo‐tetrazine [7], furazano[3,4‐b]pyrazine [8], bridging nitropyrazole derivatives with 1,3,4‐oxadiazole [9], 1,2,4‐oxadiazole [10], 1,2,5‐oxadiazole [11], 5,6‐fused bicycles [12], combination of 1,2,4‐oxadiazole derivatives with 1,2,5‐oxadiazole [13], polyaminotriazole derivatives and energetic salts [14–16], fused heterocyclic derivatives [17], etc. Heat‐resistant energetic materials for practical application that express significant features and properties including but not limited to: (1) their thermal stability should not be lower than 300 °C; (2) low cost and facile synthetic methods; (3) a lack of hypertoxic procedure or chemicals being utilized in its synthesis; (4) adequate solubility in most of solvents or at least high‐polar solvents for crystal modification and nano‐energetic materials for MEMS or detonator devices.…”

Section: Introductionmentioning

confidence: 99%

Heat‐Resistant Energetic Materials Deriving from Benzopyridotetraazapentalene: Halogen Bonding Effects on the Outcome of Crystal Structure, Thermal Stability and Sensitivity

Zhang

Geng

Yang

et al. 2021

Propellants Explo Pyrotec

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Heat‐resistant energetic material (HREM) has shown its broad applications in petroleum and natural gas exploration, aerospace vehicle as well as solid rocket formulations. Benzopyridotetraazapentalene (BPTAP) (d: 1.84 g cm−3, D: 7670 m s−1, IS: 9 J, Td: 366 °C) is a heat‐resistant energetic material, which is more dense and energetic than those of commercial HREM hexanitrosilbene (HNS) (d: 1.74 g cm−3, D: 7612 m s−1, IS: 5 J, Td: 318 °C). However, low solubility in most of commonly‐used solvents has restricted its applications in detonators as nano‐energetic materials. Meanwhile, recognition on this fused organic backbone is still limited. Herein, we report a chlorine‐inclusion strategy and facile approaches to yield three new derivatives of BPTAP. It is notable that compound 6‐a exhibits its high density (1.92 g cm−3), superior thermal stability (Td: 334 °C), high detonation performance (D: 8084 m s−1), comparable sensitivity (IS: 3 J) to that of HNS, surpassing those of commercially‐used highly‐sensitive primary energetic material lead azide (LA). It is interesting that the chlorine‐inclusion in different position of fused benzopyridotetraazapentalene framework has greatly affected their physical properties such as crystal structure, thermal stability and sensitivity. This investigation offers a unique perspective for deeply exploring the relationship between structure and performance of energetic materials.

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“…The properties of these compounds are showed in Table 14. Moreover, Li et al [124] synthesized the compound 106 with the procedure shown in Figure 34. This compound exhibited an excellent decomposition temperature (341 • C), high calculated detonation velocity of 8.52 km•s −1 , and detonation pressure of 30.6 GPa.…”

Section: Ring-bridged Bis(nitropyrazoles)mentioning

confidence: 99%

“…Afterwards, their group used a similar route to prepare bis(3,4-dinitro-1 H -pyrazol-1-yl)methane ( 89 ) and bis(3,5-dinitro-1 H -pyrazol-1-yl)methane ( 90 ) with high decomposition temperature and low sensitivities having capability as future energetic materials ( Table 13 ) [ 94 ]. Gozin et al [ 124 ] explored the possible influence factor of the thermostable property of explosives, and under the guidelines they proposed, they synthesized the compounds 91 and 92 with excellent thermal stability and moderate sensitivities shown in Figure 31 and Table 13 .…”

Section: Nitrated-bispyrazoles Based Compoundsmentioning

confidence: 99%

Recent Advances in Synthesis and Properties of Nitrated-Pyrazoles Based Energetic Compounds

et al. 2020

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Nitrated-pyrazole-based energetic compounds have attracted wide publicity in the field of energetic materials (EMs) due to their high heat of formation, high density, tailored thermal stability, and detonation performance. Many nitrated-pyrazole-based energetic compounds have been developed to meet the increasing demands of high power, low sensitivity, and eco-friendly environment, and they have good applications in explosives, propellants, and pyrotechnics. Continuous and growing efforts have been committed to promote the rapid development of nitrated-pyrazole-based EMs in the last decade, especially through large amounts of Chinese research. Some of the ultimate aims of nitrated-pyrazole-based materials are to develop potential candidates of castable explosives, explore novel insensitive high energy materials, search for low cost synthesis strategies, high efficiency, and green environmental protection, and further widen the applications of EMs. This review article aims to present the recent processes in the synthesis and physical and explosive performances of the nitrated-pyrazole-based Ems, including monopyrazoles with nitro, bispyrazoles with nitro, nitropyrazolo[4,3-c]pyrazoles, and their derivatives, and to comb the development trend of these compounds. This review intends to prompt fresh concepts for designing prominent high-performance nitropyrazole-based EMs.

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Molecular and Crystal Features of Thermostable Energetic Materials: Guidelines for Architecture of “Bridged” Compounds

Cited by 104 publications

References 101 publications

Novel All‐Nitrogen Molecular Crystals of Aromatic N₁₀

Novel All‐Nitrogen Molecular Crystals of Aromatic N₁₀

Heat‐Resistant Energetic Materials Deriving from Benzopyridotetraazapentalene: Halogen Bonding Effects on the Outcome of Crystal Structure, Thermal Stability and Sensitivity

Recent Advances in Synthesis and Properties of Nitrated-Pyrazoles Based Energetic Compounds

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Molecular and Crystal Features of Thermostable Energetic Materials: Guidelines for Architecture of “Bridged” Compounds

Cited by 104 publications

References 101 publications

Novel All‐Nitrogen Molecular Crystals of Aromatic N10

Novel All‐Nitrogen Molecular Crystals of Aromatic N10

Heat‐Resistant Energetic Materials Deriving from Benzopyridotetraazapentalene: Halogen Bonding Effects on the Outcome of Crystal Structure, Thermal Stability and Sensitivity

Recent Advances in Synthesis and Properties of Nitrated-Pyrazoles Based Energetic Compounds

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Novel All‐Nitrogen Molecular Crystals of Aromatic N₁₀

Novel All‐Nitrogen Molecular Crystals of Aromatic N₁₀