Microstructure and compressive properties of chill-cast Mg–Al–Ca alloys

Abstract

Mg82Al8Ca10 was determined to be a pseudo-binary eutectic composition [liquid solidifying into α–Mg and (Mg,Al)2Ca in the Mg–Al–Ca ternary system with a eutectic melting temperature of 789 K]. A series of Mgx(Al0.44Ca0.56)100−x alloys, where 75 ≤ x ≤ 95, were cast into Φ4 mm rods using copper mold casting. The eutectic alloy exhibits the highest fracture strength, σf = 609 MPa. For 75 ≤ x ≥ 79, the alloys have hypereutectic microstructures with Mg2Ca as the primary phase, and σf is reduced together with diminishing plasticity. For hypoeutectic alloys with 86 ≤ x ≥ 95, the volume fraction of the primary α–Mg dendrites dispersed in the eutectic matrix increases with increasing x, resulting in a gradual decrease of the yield and fracture strengths but improved plastic strain to as large as 9%. The refined microstructures created in bulk samples via chill casting can lead to a good combination of strength and plasticity, with specific strength superior to commercial Mg alloys.