Theoretical study on N‐oxide pentazolate high‐energy‐density materials: Toward excellent energetic performance and good stability

Density functional theory studies on N4 and N8 species: Focusing on various structures and excellent energetic properties

All-nitrogen materials, as a unique branch of energetic materials, have gained huge attentions, of which cyclo-N₅⁻ derivatives are the representative synthetically reported materials. However, the energetic performance of cyclo-N₅⁻ compounds has certain limitations and cannot go beyond that of CL-20. In order to reach the higher energy, in this work, we presented two kinds of polynitrogen species, N₄ and N₈. Two isomers of N₄ and four isomers of N₈ were fully calculated by using density functional theory (DFT). Theoretical results show that all these polynitrogen materials exhibit excellent heats of formation (7.92–16.60 kJ g⁻¹), desirable detonation performance (D: 9766–11620 m s⁻¹; p: 36.8–61.1 GPa), as well as the remarkable specific impulses (330.1–436.2 s), which are much superior to CL-20. Among them, N₄-2 (tetraazahedrane) (D: 10037 m s⁻¹; p: 40.1 GPa; I_sp: 409.7 s) and cube N₈-4 (D: 11620 m s⁻¹; p: 61.1 GPa; I_sp: 436.2 s) have the highest energetic properties, which are expected to become promising high-energy-density-materials. Moreover, electrostatic surface potentials, Frontier molecular orbitals, infrared spectra, natural bond orbital charges, and weak interactions were also investigated to further understand their relationship between structure and performance.