Microstructure and thermal properties of an Al–Mg alloy solidified at high temperature in the argon atmosphere
DOI:
https://doi.org/10.18321/cpc406Keywords:
Al-Mg alloy, High-temperature diffusion bonding method, Microstructure, Rapid-solidification, Phase transformations.Abstract
In this study, phase formation, the microstructure and the thermal properties of an Al-Mg alloy solidified at high temperature in the argon atmosphere were investigated. The maximum formation of a single-phase Al Mg alloy was determined by the ratio of the primary aluminum and magnesium components Al – 50 at.% Mg and argon gas flow at a temperature of 750 oC. After solidification at pressures of 1 MPa and 2 MPa, the main phases are the β and γ phases of Al-Mg alloy, in equilibrium condition. The thermal properties of the Al-Mg alloy were studied using DTA-TG (Tmelting = 458.4 oC, Тoxidation = 568.4 and 616.9 oC oxidation of pure Mg and pure Al, respectively).
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