Abstract:
The use of nanosized metal powders is a promising direction in the development of modern energy compositions due to their high reactivity and intense heat release upon contact with an oxidizer and during combustion. The results of a combined TG-DSC analysis of Alex aluminum nanopowders and a $\mathrm{Al}$–$\mathrm{Cu}$ compound, obtained via electrical explosion of conductors, are presented at constant heating rates of $2$, $4$, and $20^{\circ}$Ñ/min in air in a temperature range of $30-1300^{\circ}$Ñ. It is revealed that Alex and $\mathrm{Al}$–$\mathrm{Cu}$ nanopowders are intensely oxidized when heated in air to a temperature of $600^{\circ}$Ñ due to the oxidizer diffusion through the porous oxide layer $\mathrm{Al}_2\mathrm{O}_3$ and the possible formation of open surfaces of an active metal during a phase change in the crystal lattice of the metal oxide. The Friedman and Kissinger–Akahira–Sunose (KAS) methods were used to obtain dependences between the activation oxidation energy on the degree of conversion (oxidation) of nanosized metal powders. It is shown that the activation energy of Alex and $\mathrm{Al}$–$\mathrm{Cu}$ nanopowders depends on the degree of conversion (oxidation stages) and lies in ranges of $78-307$ and $99-430$ kJ/mol, respectively.