Abstract:By CASTEP and DMol program based on the density functional theory, the heat of formation, the cohesive energy, the thermodynamic properties and the electronic structure of the alloying system were investigated to study the structural stability of Sn alloying MgZn₂ phase and Mg₂Sn phase and explain the mechanism of the influence of Sn alloying on improving the creep resistance properties of ZA62 magnesium alloy. The results show that the structure of these phases can exist and be stable when the Zn atoms at the I positions of the MgZn₂ phase are substituted with Sn and Al, whereas, it is also found that Sn is little solved in MgZn₂ phase. By comparing with the stable MgZn₂ phase, it is found that the stability of MgZn₂ phase is reduced with Sn addition, and the structure of intermetallic compound Mg₂Sn is more stable than that of MgZn₂ phase. By calculating the thermodynamic properties of different phases, it is found that the improved creep resistance properties of ZA62 magnesium alloy are caused by forming intermetallic compound Mg₂Sn with higher structural stability which is not changed with the elevated temperature in the range of 373−473 K. The
calculations of the density of states (DOS) and Mulliken electronic populations of the alloying system show that the form of Mg₂Sn with the highest structural stability in ZA62 magnesium alloy with Sn addition attributes to the ionic bond and covalent bond in the bonding electron numbers compared with those of MgZn₂ phase, Mg₂AlZn₃ and Mg₂SnZn₃ solid solutions.

Key words: ZA62 alloy; MgZn₂ phase; Mg₂Sn phase; structural stability; thermodynamic property; first-principle; Sn alloying