Ab initio molecular dynamics simulations were performed to investigate the thermal decomposition mechanisms of the energetic benzotrifuroxan (BTF):1,3,3‐trinitroazetidine (TNAZ) cocrystal at high temperature. It is found that there are four initial ...
Ab initio molecular dynamics simulations were performed to investigate the thermal decomposition mechanisms of the energetic benzotrifuroxan (BTF):1,3,3‐trinitroazetidine (TNAZ) cocrystal at high temperature. It is found that there are four initial reaction mechanisms involved in the decomposition of the cocrystal. Subsequent decomposition channels can be divided into three types: BTF‐chain isomerization, C─NO2 bond homolysis, and ring opening. After that, one main path is that long chains decomposed into small radicals gradually after the ring opening. The other is that a new ring was formed after the ring opening and then it will break by degrees. Releasing of the H radicals and oxygen‐containing groups plays an important role in the whole decomposition process. We also studied the release mechanisms of nitrogen gas and carbon dioxide in the later decomposition stage. Our study may provide new insights into the initiation mechanisms and subsequent decomposition of cocrystal explosives at high temperature.
There are four initial reaction mechanisms involved in the decomposition of the benzotrifuroxan (BTF):1,3,3‐trinitroazetidine cocrystal at high temperature. And subsequent decomposition channels can be divided into three types: BTF‐chain isomerization, C─NO2 bond homolysis, and ring opening. We also found that releasing of the H radicals and oxygen‐containing groups plays an important role in the whole decomposition process.