Enhancing the detonation performance of azobistriazole energetic derivatives via inducing N -oxide groups.
Nan LiXin-Bo YangXiuyuan LiZihuan PengZehong YinChongwen JiangZhihong HuangYu-Chuan LiPublished in: Physical chemistry chemical physics : PCCP (2024)
The N -oxide strategy plays a crucial role in regulating the performance and safety of energetic materials. This study mainly addresses the question of how the N -oxide group affects the properties of azobistriazole and its derivatives. Our findings indicate that the N -oxide group can increase the density of the system, and its effect on the enthalpy of formation depends on the specific situation. The N -oxide groups can effectively improve the density and energetic properties. Some of the energetic derivatives containing N -oxide groups have a density as high as 2.097 g cm -3 (D3-NO(2)) and a detonation velocity as high as 10 275 m s -1 (C6-NO(2)). The effect of N -oxide groups on the enthalpy of formation depends on the specific circumstances. The effect of N -oxide groups on the stability of azobistriazole energetic derivatives is relatively complex. Among them, the N -oxide group on the triazole ring has an opposite effect on the bond dissociation enthalpy of functional groups. When the N -oxide group is on the 1,2,3-triazole ring, it can improve C-R (R is equal to C(NO 2 ) 3 , NF 2 , NHNO 2 , NO 2 , and ONO 2 respectively) bond dissociation enthalpy, and when it is on the 1,2,4-triazole ring, it will reduce the C-R bond dissociation enthalpy. When the N -oxide group is located on the azo bond, the bond dissociation enthalpy of the azo bond will be significantly reduced. This article systematically explores the effect of N -oxide groups on the properties of azobistriazole energetic derivatives, which will help people better utilize N -oxide groups to design and synthesize new energetic materials.