高强度激光泵浦探针实验研究高能炸药动力学过程的最新进展

IF 3.3 Q2 CHEMISTRY, MULTIDISCIPLINARY
Gen-bai Chu , Tao Xi , Shao-yi Wang , Min Shui , Yong-hong Yan , Guo-qing Lv , Yao Wang , Ming-hai Yu , Xiao-hui Zhang , Fang Tan , Jian-ting Xin , Liang Wang , Yu-chi Wu , Jing-qin Su , Wei-min Zhou
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引用次数: 0

摘要

为了准确预测高能炸药的爆轰和安全性能,需要在不同尺度上研究其反应机理,但由于炸药的反应动力学复杂,且目前缺乏实验方法,这给研究带来了挑战。本文介绍了基于大型激光设备的高能炸药的时间分辨泵探实验能力,并介绍了炸药动态过程的最新研究进展,得到以下认识:(1)首先,微米级单晶1,3,5-三氨基-2,4,6-三硝基苯(TATB)在激光设备中可被压缩到超驱动爆轰状态,然后对TATB进行激波Hugoniot测量;(2)其次,高分辨率瞬态x射线成像技术使高能炸药在动载作用下的内部变形、损伤和反应动力学的动态成像成为可能;(3)第三,可以利用动态x射线衍射或散射光谱研究激波压缩炸药的相变和化学反应产物;(4)最后,利用超快激光光谱技术研究炸药在超快抽运作用下的结构变化、分子反应、分子键裂解和中间产物成分。大型激光设备可以提供各种灵活的泵浦探测方法,包括激光冲击加载,瞬态x射线成像,动态x射线衍射和超快光谱,允许进行一系列实验来评估从低压到超驱动爆炸的不同水平的点火。此外,这些设施还可以在高空间和时间分辨率下对动态载荷下爆炸物的内部变形、相变和超快动力学进行现场实时调查。在细观-介观尺度上对高能炸药的反应动力学和机理进行研究,是揭示爆炸反应奥秘的有效手段。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Recent progress in research on the dynamic process of high-energy explosives through pump-probe experiments at high-intensity laser facilities

Recent progress in research on the dynamic process of high-energy explosives through pump-probe experiments at high-intensity laser facilities

To accurately predict the detonation and safety performances of high-energy explosives, it is necessary to investigate their reaction mechanisms on different scales, which, however, presents a challenge due to the complex reaction kinetics of the explosives and a lack of experimental methods presently. This work introduces the time-resolved pump-probe experiments capabilities aiming at high-energy explosives based on large-scale laser facilities and presents the recent progress in research on the dynamic process of the explosives, obtaining the following understandings: (1) First, the micron-sized single-crystal 1,3,5-triamino-2,4,6-trinitrobenzene (TATB) can be compressed to an overdriven detonation state at a laser facility, followed by the shock Hugoniot measurements of TATB; (2) Second, high resolution transient X-ray radiography makes it possible to achieve the dynamic imaging of the internal deformation, damage, and reaction dynamics of high-energy explosive under dynamic loading; (3) Third, the phase transformation and chemical reaction products of the shock-compressed explosives can be investigated using dynamic X-ray diffraction or scattering spectra; (4) Finally, the structural changes, molecular reactions, molecular bond cleavage, and intermediate product components of explosives under ultrafast pumping can be explored using ultrafast laser spectroscopy. Large-scale laser facilities can provide various flexible pump-probe methods, including laser shock loading, transient X-ray imaging, dynamic X-ray diffraction, and ultrafast spectroscopy, allowing a series of experiments to be carried out to evaluate different levels of ignitions from low-pressure to overdriven detonations. Furthermore, the facilities also enable in situ, real-time investigations of the internal deformation, phase transition, and ultrafast dynamics of explosives under dynamic loading at high spatial and temporal resolutions. The study of the reaction kinetics and mechanisms of high-energy explosives on microscopic-mesoscopic scales provides an efficient means to unravel the mystery of explosive reactions.

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来源期刊
Energetic Materials Frontiers
Energetic Materials Frontiers Materials Science-Materials Science (miscellaneous)
CiteScore
6.90
自引率
0.00%
发文量
42
审稿时长
12 weeks
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