Molecular Dynamics Simulations of the Thermal Decomposition of 3,4-Bis(3-nitrofurazan-4-yl)furoxan
When stimulated, for example, by a high temperature, the physical and chemical properties of energetic materials (EMs) may change, and, in turn, their overall performance is affected. Therefore, thermal stability is crucial for EMs, especially the thermal dynamic behavior. In the past decade, signif...
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| Published in | ACS omega Vol. 6; no. 49; pp. 33470 - 33481 |
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| Main Authors | , , , , , , |
| Format | Journal Article |
| Language | English |
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American Chemical Society
14.12.2021
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| Abstract | When stimulated, for example, by a high temperature, the physical and chemical properties of energetic materials (EMs) may change, and, in turn, their overall performance is affected. Therefore, thermal stability is crucial for EMs, especially the thermal dynamic behavior. In the past decade, significant efforts have been made to study the thermal dynamic behavior of 3,4-bis(3-nitrofurazan-4-yl)furoxan (DNTF), one of the new high-energy-density materials (HEDMs). However, the thermal decomposition mechanism of DNTF is still not specific or comprehensive. In this study, the self-consistent-charge density-functional tight-binding method was combined with molecular dynamics (MD) simulations to reveal the differences in the thermal decomposition of DNTF under four heating conditions. The O–N (O) bond would fracture first during DNTF initial thermal decomposition at medium and low temperatures, thus triggering the cracking of the whole structure. At 2000 and 2500 K, NO2 loss on outer ring I is the fastest initial thermal decomposition pathway, and it determines that the decomposition mechanism is different from that of a medium-low temperature. NO2 is found to be the most active intermediate product; large molecular fragments, such as C2N2O, are found for the first time. Hopefully, these results could provide some insights into the decomposition mechanism of new HEDMs. |
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| AbstractList | When stimulated, for example, by a high temperature, the physical and chemical properties of energetic materials (EMs) may change, and, in turn, their overall performance is affected. Therefore, thermal stability is crucial for EMs, especially the thermal dynamic behavior. In the past decade, significant efforts have been made to study the thermal dynamic behavior of 3,4-bis(3-nitrofurazan-4-yl)furoxan (DNTF), one of the new high-energy-density materials (HEDMs). However, the thermal decomposition mechanism of DNTF is still not specific or comprehensive. In this study, the self-consistent-charge density-functional tight-binding method was combined with molecular dynamics (MD) simulations to reveal the differences in the thermal decomposition of DNTF under four heating conditions. The O–N (O) bond would fracture first during DNTF initial thermal decomposition at medium and low temperatures, thus triggering the cracking of the whole structure. At 2000 and 2500 K, NO2 loss on outer ring I is the fastest initial thermal decomposition pathway, and it determines that the decomposition mechanism is different from that of a medium-low temperature. NO2 is found to be the most active intermediate product; large molecular fragments, such as C2N2O, are found for the first time. Hopefully, these results could provide some insights into the decomposition mechanism of new HEDMs. When stimulated, for example, by a high temperature, the physical and chemical properties of energetic materials (EMs) may change, and, in turn, their overall performance is affected. Therefore, thermal stability is crucial for EMs, especially the thermal dynamic behavior. In the past decade, significant efforts have been made to study the thermal dynamic behavior of 3,4-bis(3-nitrofurazan-4-yl)furoxan (DNTF), one of the new high-energy-density materials (HEDMs). However, the thermal decomposition mechanism of DNTF is still not specific or comprehensive. In this study, the self-consistent-charge density-functional tight-binding method was combined with molecular dynamics (MD) simulations to reveal the differences in the thermal decomposition of DNTF under four heating conditions. The O-N (O) bond would fracture first during DNTF initial thermal decomposition at medium and low temperatures, thus triggering the cracking of the whole structure. At 2000 and 2500 K, NO loss on outer ring I is the fastest initial thermal decomposition pathway, and it determines that the decomposition mechanism is different from that of a medium-low temperature. NO is found to be the most active intermediate product; large molecular fragments, such as C N O, are found for the first time. Hopefully, these results could provide some insights into the decomposition mechanism of new HEDMs. When stimulated, for example, by a high temperature, the physical and chemical properties of energetic materials (EMs) may change, and, in turn, their overall performance is affected. Therefore, thermal stability is crucial for EMs, especially the thermal dynamic behavior. In the past decade, significant efforts have been made to study the thermal dynamic behavior of 3,4-bis(3-nitrofurazan-4-yl)furoxan (DNTF), one of the new high-energy-density materials (HEDMs). However, the thermal decomposition mechanism of DNTF is still not specific or comprehensive. In this study, the self-consistent-charge density-functional tight-binding method was combined with molecular dynamics (MD) simulations to reveal the differences in the thermal decomposition of DNTF under four heating conditions. The O–N (O) bond would fracture first during DNTF initial thermal decomposition at medium and low temperatures, thus triggering the cracking of the whole structure. At 2000 and 2500 K, NO 2 loss on outer ring I is the fastest initial thermal decomposition pathway, and it determines that the decomposition mechanism is different from that of a medium-low temperature. NO 2 is found to be the most active intermediate product; large molecular fragments, such as C 2 N 2 O, are found for the first time. Hopefully, these results could provide some insights into the decomposition mechanism of new HEDMs. |
| Author | Wang, Fanfan Jiang, Qiuli Liu, Yucun Luo, Yiming Yuan, Junming Li, Yang Meng, Jingwei |
| AuthorAffiliation | China Academy of Engineering Physics (CAEP) Xi’an Modern Chemistry Research Institute School of Environment and Safety Engineering Institute of Chemical Materials |
| AuthorAffiliation_xml | – name: China Academy of Engineering Physics (CAEP) – name: School of Environment and Safety Engineering – name: Institute of Chemical Materials – name: Xi’an Modern Chemistry Research Institute |
| Author_xml | – sequence: 1 givenname: Yang orcidid: 0000-0002-9063-1994 surname: Li fullname: Li, Yang organization: School of Environment and Safety Engineering – sequence: 2 givenname: Yucun surname: Liu fullname: Liu, Yucun email: lyc2ct@vip.sina.com organization: School of Environment and Safety Engineering – sequence: 3 givenname: Junming surname: Yuan fullname: Yuan, Junming organization: School of Environment and Safety Engineering – sequence: 4 givenname: Yiming surname: Luo fullname: Luo, Yiming organization: Xi’an Modern Chemistry Research Institute – sequence: 5 givenname: Qiuli surname: Jiang fullname: Jiang, Qiuli organization: Xi’an Modern Chemistry Research Institute – sequence: 6 givenname: Fanfan surname: Wang fullname: Wang, Fanfan organization: China Academy of Engineering Physics (CAEP) – sequence: 7 givenname: Jingwei surname: Meng fullname: Meng, Jingwei organization: School of Environment and Safety Engineering |
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| Title | Molecular Dynamics Simulations of the Thermal Decomposition of 3,4-Bis(3-nitrofurazan-4-yl)furoxan |
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