1. Thermal reactivity of metastable metal-based fuel Al/Co/AP: Mutual interaction mechanisms of the components.
- Author
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Yang, Su-Lan, Meng, Ke-Juan, Xie, Wuxi, Nie, Hongqi, and Yan, Qi-Long
- Subjects
- *
HEAT release rates , *DISCONTINUOUS precipitation , *CHAIN scission , *CHEMICAL decomposition , *ACTIVATION energy - Abstract
Preparation of highly reactive core-shell Al/Co@AP composite and their physical models for the thermal decomposition of AP and the intermetallic reactions under the mutual interaction. [Display omitted] • Core-shell structured Al/Co@AP composite has been prepared. • Al/Co improved the heat release of the thermal decomposition of AP by 52.6%. • AP enhanced the heat release of the intermetallic reaction between Al and Co by 67.7%. • The physical models for the AP thermal decomposition reaction and Al/Co intermetallic reaction have been proposed. In this paper, a group of novel intermetallic metastable composites Al/Co@AP has been designed, and three methods including ultrasonic dispersion, mechanical grinding and spray-drying have been attempted for their preparation. The latter one has demonstrated to be the most appropriate means, by which the core–shell structured Al/Co@AP with desired properties could be successfully obtained. The thermal reactivity of Al/Co/AP composites prepared differently has been investigated and compared by TG/DSC technique. It has been shown that the heat release rate of AP in DSC curve was largely increased in the presence of Al/Co when spray-drying technique was used, which may be attributed to the increased nuclear site by the intimate contact. The initial reaction temperature of AP in Al/Co@AP was decreased by 7.8 °C and the heat releases by the thermal decomposition of AP and the intermetallic reaction between Al and Co were enhanced by 52.6 % and 67.7% in comparison with that of pure AP and Al/Co. The types of major gaseous products of Al/Co@AP are almost identical to that of pure AP, which include HCl, H 2 O, N 2 O and NO 2. However, the concentrations of NO 2 and N 2 O in gaseous products for Al/Co@AP are lower than that observed for pure AP, which may be due to the partial consumption of N element by the reaction of Al with acidic substance (HNO 3) decomposed from AP. In addition, the AP in Al/Co@AP composite decomposes in one-step with the apparent activation energy (E a) of 98.8 kJ·cm−3. The decomposition process of the AP in Al/Co@AP composite follows two-dimensional nucleation and growth model(A2), whereas the pure AP follows different physical models, which are close to three-dimensional nucleation and growth, chain scission and phase boundary-controlled reaction (contracting area) models. The intermetallic reaction between Al and Co in Al/Co@AP is merged into one-step following the A2 physical model. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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