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一组同分异构体含能化合物热稳定性差异的机理研究OACSTPCD

Mechanism Study on the Thermal Stability Difference of a Group of Isomeric Energetic Compounds

中文摘要英文摘要

同分异构现象在含能化合物中普遍存在,同分异构体在能量和安全性能上可存在差异,研究其机制有助于深化含能化合物结构-性能关系.本研究基于电荷自洽的密度泛函紧束缚方法探究了2,6-二氨基-3,5-二硝基-1-氧化吡嗪(LLM-105)、3,5-二氨基-4,6-二硝基-1-氧化哒嗪和1,4-二硝基呋咱并[3,4-b]哌嗪(DNFP)3种同分异构体含能化合物在程序升温和恒温加热条件下的热分解机理.结果表明,LLM-105晶体中存在较强的氢键网络,在分解初期能够发生占比达68.75%的分子间氢转移反应,对其高热稳定性起到了重要作用;3,5-二氨基-4,6-二硝基-1-氧化哒嗪的骨架结构在加热下容易通过N—N键断裂发生开环,其热稳定性比LLM-105更低;DNFP发生硝基断裂的键解离能为172.3 kJ·mol-1,显著低于其它两种同分异构体,同时其并环骨架也容易通过C—C键和N—O键断裂发生开环,其热稳定性最低.可见,分子最弱键的解离能、环骨架结构的稳定性、晶体的氢键网络都是决定含能化合物热稳定性的重要结构因素.

Isomerism is common in energetic compounds.Isomers may have differences in energy and safety performance.Inves-tigating the mechanisms in these differences contributes to a deeper understanding of the structure-performance relationship of energetic compounds.The thermal decomposition mechanisms of three isomeric energetic compounds,2,6-diamino-3,5-dini-tro-1-oxide pyrimidine(LLM-105),3,5-diamino-4,6-dinitro-1-oxide diazine,and 1,4-dinitrofurazan[3,4-b]pyrazine(DN-FP),were studied using the self-consistent-charge density-functional tight-binding method(SCC-DFTB)under program heating and isothermal heating conditions.The results show that there is a strong hydrogen bond network in the LLM-105 crystal,en-abling a molecular hydrogen transfer reaction accounting for 68.75%in the early stage of decomposition,which plays an impor-tant role in its high thermal stability;The skeleton structure of 3,5-diamino-4,6-dinitro-1-oxide diazine was prone to ring-opening through N—N bond cleavage under heating,resulting in lower thermal stability compared to LLM-105;The bond dissociation energy of DNFP for nitro group cleavage is 172.3 kJ·mol-1,which is significantly lower than the other two isomers.Additionally,its fused-ring skeleton was also susceptible to ring-opening through C—C and N—O bond cleavage,resulting in the lowest thermal stability.In summary,the bond dissociation energy of the weakest bond in the molecule,the stability of the ring skeleton structure,and the hydrogen bond network of the crystal are important structural factors that determine the thermal stability of energetic compounds.

王榕;令狐遥遥;张朝阳;钟凯

中国工程物理研究院化工材料研究所,四川 绵阳 621999中国工程物理研究院化工材料研究所,四川 绵阳 621999||中北大学材料科学与工程学院,山西 太原 030051

武器工业

含能化合物同分异构体热分解稳定性

energetic compoundsisomersthermal decompositionthermostability

《含能材料》 2024 (001)

含能化合物本征热稳定性的预测方法与应用研究

38-48 / 11

国家自然科学基金(22173086,21875227) National Natural Science Foundation of China(Nos.22173086,21875227)

10.11943/CJEM2023194

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