TY - JOUR
T1 - The application of porous organic cage as highly efficient desensitizer of RDX
AU - Fang, Hua
AU - Liu, Xiaodong
AU - Li, Hao
AU - Li, Junying
AU - Song, Jiajie
AU - Yang, Fanzhi
AU - Liu, Ruibin
AU - Xia, Min
AU - Zhang, Zhaobo
AU - Luo, Yunjun
N1 - Publisher Copyright:
© 2025 China Ordnance Society
PY - 2025
Y1 - 2025
N2 - The desensitization of nitramine explosives while maintaining energetic performance is challenging. A highly efficient desensitizer is the key to solving the antinomy. This study focuses on using porous organic cages (POCs), specifically CC3 and RCC3, to desensitize RDX. By coating 0.1 wt%–5 wt% of POCs on RDX particles, a series of composite energetic materials were prepared. Characterization results show that POCs change the surface morphology of RDX, and there are interfacial interactions between them. The RDX@POCs composites exhibit enhanced stabilities in terms of heat, impact, friction, and electrostatic spark. For the RDX@RCC3-5% composite, the impact sensitivity (EIS), friction sensitivity (EFS), and electrostatic sensitivity (EES) were significantly reduced by 66.7%, 68.8%, and 56.5%, respectively, while the detonation velocity decreased by merely 3.1%. These findings indicate that POCs, especially RCC3, are promising desensitizers for nitramine explosives, and their desensitization mechanisms likely involve barrier and buffering effects. The distinct desensitization behavior of RDX@RCC3 highlights the effectiveness of POCs in reducing the sensitivity of RDX without significantly compromising its energetic properties.
AB - The desensitization of nitramine explosives while maintaining energetic performance is challenging. A highly efficient desensitizer is the key to solving the antinomy. This study focuses on using porous organic cages (POCs), specifically CC3 and RCC3, to desensitize RDX. By coating 0.1 wt%–5 wt% of POCs on RDX particles, a series of composite energetic materials were prepared. Characterization results show that POCs change the surface morphology of RDX, and there are interfacial interactions between them. The RDX@POCs composites exhibit enhanced stabilities in terms of heat, impact, friction, and electrostatic spark. For the RDX@RCC3-5% composite, the impact sensitivity (EIS), friction sensitivity (EFS), and electrostatic sensitivity (EES) were significantly reduced by 66.7%, 68.8%, and 56.5%, respectively, while the detonation velocity decreased by merely 3.1%. These findings indicate that POCs, especially RCC3, are promising desensitizers for nitramine explosives, and their desensitization mechanisms likely involve barrier and buffering effects. The distinct desensitization behavior of RDX@RCC3 highlights the effectiveness of POCs in reducing the sensitivity of RDX without significantly compromising its energetic properties.
KW - Desensitization
KW - Nitramine explosives
KW - Porous organic cage
KW - RDX
UR - http://www.scopus.com/pages/publications/105008352868
U2 - 10.1016/j.dt.2025.06.002
DO - 10.1016/j.dt.2025.06.002
M3 - Article
AN - SCOPUS:105008352868
SN - 2096-3459
JO - Defence Technology
JF - Defence Technology
ER -