First-Principles Investigations on Structural Stability, Elastic Properties and Electronic Structure of Mg32(Al,Zn)49 Phase and MgZn2 Phase

Abstract: Al–Mg–Zn alloys reinforced by T–Mg32(Al,Zn)49 phase had higher structure stability and strength than Al–Zn–Mg–(Cu) alloys reinforced by MgZn2 phase, but the reasons for these two kind of alloys was not well-known. To reveal the discrepancy between T phase and MgZn2 phase, the lattice parameters, cohesive energy, and electronic structure as well as the elastic properties were investigated based on density functional theory. Four types of T phase unit cell were employed according to symmetry of space group. The … Show more

“…Conversely, T-phase shows that both atomic displacements and stoichiometry changes can take place without major changes in its bulk crystal structure (Fig. 4D) (46). Evidence herein presented may indicate that the origins of high radiation tolerance of T-phase precipitates resort -and can be tailoredto its unique thermodynamic state as an essential factor of stability.…”

Radiation-resistant aluminium alloy for space missions in the extreme environment of the solar system

“…Conversely, T-phase shows that both atomic displacements and stoichiometry changes can take place without major changes in its bulk crystal structure (Fig. 4D) (46). Evidence herein presented may indicate that the origins of high radiation tolerance of T-phase precipitates resort -and can be tailoredto its unique thermodynamic state as an essential factor of stability.…”

Radiation-resistant aluminium alloy for space missions in the extreme environment of the solar system

Fine-grained aluminium crossover alloy for high-temperature sheet forming

The role of Mg content in regulating microstructures and mechanical properties of Al–Mg–ZnO composites fabricated via in-situ reaction sintering