Abstract
Metallic materials with micron grains, submicron grains, or amorphous structures have attracted great interest in recent decades owing to their excellent mechanical properties and corrosion resistance. Compared with traditional forming processes, rapid solidification technology has shown great superiority and potential in the preparation of materials in such structures. In this study, fine-grained quasiamorphous Mg-based alloy strips fabricated by a twin-roll strip casting process were explored using simulation and experimental methods. The concept of critical casting speed was proposed to reflect the optimum casting conditions. The product of critical casting speed and strip thickness was used to evaluate the cooling capacity of the casting system. Based on simulation results, a twin-roll strip-casting experiment was performed on a Mg-rare earth alloy. A novel puddle-like microstructure of the as-cast alloy strip was obtained. Tensile testing results showed that the novel strip exhibited improved ductility.
Highlights
Ultrafine-grained, nanocrystalline, and amorphous materials are topics of significant current research interest in modern materials science [1,2,3]
And thickness δ are the main casters and determined the effects of strip-casting parameters on microstructure transformation. It parameters that influence temperature distribution at the casting zone and the final microstructure wasof found that pouring temperature
5, the shapes of isotherms were like a flat bow under low casting speed but resembled the letter V in appearance at high casting were a flat bow under low casting speed but resembled the letter
Summary
Ultrafine-grained, nanocrystalline, and amorphous materials are topics of significant current research interest in modern materials science [1,2,3]. The preparation of these materials is complex and their high processing cost is a major challenge
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