含能材料
含能材料
함능재료
ENERGETIC MATERIALS
2013年
5期
557-562
,共6页
朱卫华%黄辉%黄亨建%肖鹤鸣
硃衛華%黃輝%黃亨建%肖鶴鳴
주위화%황휘%황형건%초학명
物理化学%炸药晶体%冲击加载%引发机理%从头算分子动力学%多尺度冲击方法
物理化學%炸藥晶體%遲擊加載%引髮機理%從頭算分子動力學%多呎度遲擊方法
물이화학%작약정체%충격가재%인발궤리%종두산분자동역학%다척도충격방법
physical chemistry%explosive crystals%shock loading%initiation mechanisms%Ab initio molecular dynamics%multi-scale shock technique
运用从头算分子动力学和多尺度冲击相结合的方法,对三类典型炸药晶体奥克托今( HMX)、1,3,5-三氨基2,4,6-三硝基苯( TATB)和太安( PETN)实施冲击加载下的模拟研究。结果表明,HMX中的N-O键、TATB中的N-O键以及PETN中的C-O键优先断裂。随着时间推移,他们体系中电子离域性增加;价带和导带间的带隙逐渐减小;接着开始出现金属态并不断变多。在冲击加载下,TATB、HMX和PETN晶体引发断裂化学键所需时间依次减小的顺序,恰与它们冲击波感度依次增大的实验顺序相一致。这表明,它们的结构和引发分解机理与冲击波感度之间有规律性联系。
運用從頭算分子動力學和多呎度遲擊相結閤的方法,對三類典型炸藥晶體奧剋託今( HMX)、1,3,5-三氨基2,4,6-三硝基苯( TATB)和太安( PETN)實施遲擊加載下的模擬研究。結果錶明,HMX中的N-O鍵、TATB中的N-O鍵以及PETN中的C-O鍵優先斷裂。隨著時間推移,他們體繫中電子離域性增加;價帶和導帶間的帶隙逐漸減小;接著開始齣現金屬態併不斷變多。在遲擊加載下,TATB、HMX和PETN晶體引髮斷裂化學鍵所需時間依次減小的順序,恰與它們遲擊波感度依次增大的實驗順序相一緻。這錶明,它們的結構和引髮分解機理與遲擊波感度之間有規律性聯繫。
운용종두산분자동역학화다척도충격상결합적방법,대삼류전형작약정체오극탁금( HMX)、1,3,5-삼안기2,4,6-삼초기분( TATB)화태안( PETN)실시충격가재하적모의연구。결과표명,HMX중적N-O건、TATB중적N-O건이급PETN중적C-O건우선단렬。수착시간추이,타문체계중전자리역성증가;개대화도대간적대극축점감소;접착개시출현금속태병불단변다。재충격가재하,TATB、HMX화PETN정체인발단열화학건소수시간의차감소적순서,흡여타문충격파감도의차증대적실험순서상일치。저표명,타문적결구화인발분해궤리여충격파감도지간유규률성련계。
Ab initio molecular dynamics in conjunction with multiscale shock technique was used to study the initial decomposition of HMX, TATB, and PETN crystals under shock wave loading.Results indicate that the decompositions of HMX, TATB, and PETN under shock loading are triggered by the N-O bond, N-O bond and C-O bond breaking, respectively.As the simulation contin-ues, the electronic delocalization in their systems increases and the band gap between conduction and valence bands decreases grad-ually.Then,metallic states in the systems begin to appear and increase.Under shock loading, the decreasing order of the time for the trigger bond cleavage for TATB, HMX and PETN is in agreement with the increasing sequence of their experimental shock sensitivity. This suggests that there is a relationship between structure or initiation decomposition mechanisms and sensitivity to shock wave.