Novel Hexagonal Structure of Ultra-High Strength Magnesium-Based Alloys

Abstract

A magnesium (Mg) solid solution with a novel long periodic hexagonal structure was formed for a Mg₉₇Zn₁Y₂ (at%) alloy in a rod form prepared by extrusion of atomized powders at 573 K as well as in a melt-spun ribbon form. The novel structure of the rod alloy had an ABACAB-type six layered packing with lattice parameters of a=0.322 nm and c=3×0.521 nm. The Mg phase in the extruded rod alloy had fine grain sizes of 100 to 150 nm and included cubic Mg₂₄Y₅ particles with a size of about 10 nm at volume fractions below 10%. The density (ρ) was 1.84Mg/m³. The tensile yield strength (σ_y) and elongation of the rod alloy were 610 MPa and 5%, respectively, and the specific strength defined by the ratio of σ_y to ρ was 330 MPa/(Mg/m³), being the highest among all metallic alloys. The σ_y is 2.7 to 8 times higher than those for conventional high-strength Mg-based alloys. The excellent mechanical properties are due to the combination of fine grain size, new long periodic hexagonal solid solution, homogeneous dispersion of fine Mg₂₄Y₅ particles inside the nano-grains and the absence of the second precipitates along the grain boundary. The new Mg-based alloy is promising for future uses in many fields.