Ultra-fast response behavior of aluminum hydride (AlH3) in a quasi- detonation environment

YJ Chen and YR Li and JB Fu and M Zhang and H Ren and QJ Jiao, JOURNAL OF MATERIALS SCIENCE, 59, 1537-1549 (2024).

DOI: 10.1007/s10853-023-09318-1

Aluminum hydride (AlH3), as a potential new metal fuel, has attracted extensive attention in the field of hydrogen storage materials, propellants and energetic materials due to its excellent properties. In this paper, a new organic liquid phase reduction method was used to prepare AlH3, and the microstructure and composition of the prepared samples were characterized by SEM-EDS, XRD, FT-IR, XPS, etc. The main crystal phase of the prepared AlH3 was alpha-AlH3, with high quality and no other impurities. The thermal decomposition behavior and non- isothermal reaction kinetics of AlH3 were investigated by TG-DSC. The results show that there are three exothermic stages in the heating process of AlH3: dehydrogenation of AlH3, first oxidation of Al, and second oxidation of Al. The activation energy of the dehydrogenation of AlH3 is 77.8675 kJ/mol (Kissinger method) and 81.4862 kJ/mol (Ozawa method), respectively. The morphology evolution of AlH3 particles during the heating process (300-3000 K) was simulated using a reaction kinetics method based on the ReaxFF force field. The response behavior of AlH3 in the instantaneous high-temperature detonation environment was investigated using the high-energy laser-induced shock wave technique. Under the impact of a high-energy laser (1006 mJ), the AlH3 sample undergoes an ultra-fast reaction and generates a large amount of plasma. The expansion of the plasma pushes the surrounding air to form a supersonic shock wave and propagates forward. The shock wave propagation velocity of AlH3 is 690.99 m/s in the range of 2.1-12.35 mu s, and the higher the laser energy, the faster the shock wave propagation velocity. This study provides the basis for the application of AlH3.

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