Abstract:By using Dmol 4.1 program based on the density functional theory, heat of formation, cohesive energy, thermodynamic properties and density of states (DOS) of the alloying system were investigated to explain the mechanism of the influence of Sb, Bi alloying on improving heat resistance properties of Mg-Al alloy. The results show that the structure of these phases can exist and be stable when the Mg atoms at the positions Ⅰ, Ⅱ of the Mg17Al12 phase are substituted with Sb, the Mg atoms at the positions Ⅰ are substituted with Bi, which shows that Sb and Bi are little soluted in Mg17Al12 phase. By comparing the stable Mg17Al12 phase with Sb or Bi addition, it is found that Mg17Al12 phase stability is improved, and Mg17Al12 solid solutions substituting Mg atoms at positions Ⅱ with Sb has the highest structural stability, next substituting Mg atoms at positions Ⅰ with Sb, finally substituting Mg atoms at positions Ⅰ with Bi, whereas the structures of Mg3Sb2 and Mg3Bi2 are more stable than that of Mg17Al12 solid solutions with Sb, Biadditions. By calculating the thermodynamic properties of Mg-Al alloy, it is found that the improved heat resistance properties of the alloying system are caused by forming the Mg17Al12 phase and intermetallic Mg3Sb2 and Mg3Bi2 with higher structural stability, which is not changed with the elevated temperature. Compared with the density of states (DOS) of the alloying system, the increase of the structural stability of Mg-Al alloy with Sb or Bi additions attributes to an increase in the bonding electron numbers at lower energy level below Fermi level, which mainly originates from the contribution of the valence electron numbers of Mg(s), Mg(p), Al(p), Bi(d) and Sb(d) orbits.

Key words: Mg17Al12 phases; structural stability; thermodynamic properties