Research on formability, microstructure and mechanical properties of selective laser melted Mg-Y-Sm-Zn-Zr magnesium alloy

Abstract

Selective laser melting (SLM) refers to a laser additive manufacturing technology. It shows its advantages of high efficiency and is capable of processing arbitrary complex structural parts. However, the SLM of magnesium alloy is highly challenging and should be studied in depth due to the low melting and boiling point of magnesium alloy. In this study, selective laser melting (SLM) technology was used to manufacture the Mg-Y-Sm-Zn-Zr alloy. Microstructure characteristics and performance mechanism of the SLMed samples were investigated. As revealed by the results, samples characterized by relatively high densities and low surface roughness could be produced when the energy density was 83.3–166.7 J/mm 3 . The highest density of 97.8% could be obtained when the energy density was 125.7 J/mm 3 . The molten pool was found to consist of slender columnar grains at the edge and a small amount of equiaxed grains at the top, while the grains below the molten pool were coarsened under the action of the thermal influence. The role played by Y 2 O 3 in the solidification of SLM was characterized using the degree of lattice mismatch. Impacted by the high lattice mismatch between Y 2 O 3 and Mg, Y 2 O 3 could not serve as an effective heterogeneous nucleation particle. The highest comperssive performance was obtained at energy density of 125.7 J/mm 3 (YS = 304 ± 5 Mpa, UTS = 394 ± 5 Mpa). The main strengthening mechanism was fine-grain strengthening, followed by precipitation strengthening and the effect of solid solution strengthening was not obvious. This work provides a certain guiding significance for the follow-up research of SLMed rare earth magnesium alloy. • SLM process parameters of Mg-Y-Sm-Zn-Zr which can obtain ideal relative density and surface roughness were determined. • The influence of Y and Zr elements on the solidification behavior of SLMed Mg-Y-Sm-Zn-Zr was determined. • The orientation relationship between precipitated particles and the magnesium matrix was studied. • The improvement of the compressive properties of the SLMed sample was analyzed.