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Coupling Effect of Non-Ignition Impact and Heat on the Decay of FOX-7.

Authors :
She, Chongchong
Chen, Kun
Chen, Minglei
Lu, Zhiyan
Wu, Nana
Li, Lijie
Wang, Junfeng
Jin, Shaohua
Source :
Molecules. Dec2022, Vol. 27 Issue 23, p8255. 15p.
Publication Year :
2022

Abstract

Non-ignition impact and heat stimuli are the most common external stimuli loaded on energetic materials. Nevertheless, there is thereby an urgent need, but it is still a significant challenge to comprehend their coupling effects on the decay and safety mechanisms of energetic materials. Then, reactive molecular dynamics simulation was employed to mimic practical situations and reveal the impact heat coupling effect on the decay mechanism of FOX-7. The temperature and the degree of compression of the crystal caused by the impact are considered variables in the simulation. Both increasing the degree of compression and elevating the temperature promotes the decay of FOX-7. However, their underlying response mechanism is not the same. The acceleration of decomposition is due to the elevated potential energy of the FOX-7 molecules because of elevating the temperature. In addition to the elevated potential energy of the molecule, the main contribution to the decomposition from the compression is to change the decomposition path. The results of the analysis show that compression reduces the stability of the C=C bond, so that chemical reactions related to the double bond occur. In addition, interestingly, the compression along the c direction has an almost equal effect on the final product as the compression along the b direction. Finally, the decay reaction networks are proposed to provide insights into the decomposition mechanism on atomic level. All these findings are expected to pave a way to understand the underlying response mechanism for the FOX-7 against external stimuli. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
14203049
Volume :
27
Issue :
23
Database :
Academic Search Index
Journal :
Molecules
Publication Type :
Academic Journal
Accession number :
160739775
Full Text :
https://doi.org/10.3390/molecules27238255