期刊
OPTICS EXPRESS
卷 30, 期 4, 页码 4718-4736出版社
OPTICAL SOC AMER
DOI: 10.1364/OE.449382
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资金
- National Key Research and Development Program of China [2018YFC2001100]
- Open Research Fund of State Key Laboratory of Explosion Science and Technology [YBKT21-04]
In this study, a micro-scale approach based on radiation spectra and dynamic analysis during the interaction between laser and energetic materials (EMs) was proposed for high-precision diagnosis of explosion parameters. The results revealed a tight correlation between micro-detonation and macroscopic detonation, allowing for the estimation of macroscale detonation performance in a high-speed and high-accuracy manner. This method provides a small-dose, low-cost, and multi-parameter approach to diagnose the performance of EMs in the macroscale domain from the microscale domain.
Determination of macroscale detonation parameters of energetic materials (EMs) in a safe and rapid way is highly desirable. However, traditional experimental methods suffer from tedious operation, safety hazards and high cost. Herein, we present a micro-scale approach for high-precision diagnosis of explosion parameters based on radiation spectra and dynamic analysis during the interaction between laser and EMs. The intrinsic natures of micro-explosion dynamics covering nanosecond to millisecond and chemical reactions in laser-induced plasma are revealed, which reveal a tight correlation between micro-detonation and macroscopic detonation based on laser-induced plasma spectra and dynamics combined with statistic ways. As hundreds to thousands of laser pulses ablate on seven typical tetrazole-based high-nitrogen compounds and ten single-compound explosives, macroscale detonation performance can be well estimated with a high-speed and high-accuracy way. Thereby, the detonation pressure and enthalpies of formation can be quantitatively determined by the laser ablation processes for the first time to our knowledge. These results enable us to diagnose the performance of EMs in macroscale domain from microscale domain with small-dose, low-cost and multiple parameters. (C) 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement
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