1. Applying multi-pass friction stir processing to refine the microstructure and enhance the strength, ductility and corrosion resistance of WE43 magnesium alloy
- Author
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Jie Zhou, Maryam Mehdizade, Ali Reza Eivani, and S. Chabok
- Subjects
Materials science ,Friction stir processing ,Mechanical properties ,02 engineering and technology ,01 natural sciences ,Corrosion ,Biomaterials ,0103 physical sciences ,Pitting corrosion ,Magnesium ,Magnesium alloy ,Ductility ,Microstructure ,010302 applied physics ,Mining engineering. Metallurgy ,Metallurgy ,TN1-997 ,Metals and Alloys ,021001 nanoscience & nanotechnology ,Grain size ,Surfaces, Coatings and Films ,Ceramics and Composites ,Grain boundary ,0210 nano-technology - Abstract
Magnesium alloys have many unique properties, mostly benefitting from the low density of magnesium. However, they are not competitive, when compared with other lightweight materials, such as aluminum alloys, particularly in ductility and corrosion resistance. There is a strong need to improve the mechanical properties and corrosion resistance of magnesium alloys. In the present research, friction stir processing (FSP) as a severe plastic deformation process was applied to the WE43 magnesium alloy. The effect of FSP up to 6 passes on the grain structure, second-phase particle distribution, mechanical properties and corrosion resistance of the alloy was investigated. It was found that a continuous network of second-phase particles was present at the grain boundaries, which was considered to be one of the main causes for the poor ductility of the alloy in the as-annealed state. By applying two passes of FSP, the grain structure was significantly refined, changing from an average grain size of 12.4 to 2.5 μm. By further FSP, the grain structure continued to refine to an average grain size of 1.4 μm after 4 passes and remained unchanged after 6 passes. However, the fragmentation and redistribution of second-phase particles continued to occur during the 4th and 6th passes of FSP. Because of these microstructural changes, the uniform strain to maximum stress and the strength of specimens gradually improved with increasing number of FSP passes. The corrosion resistance of the alloy was found to be improved by applying 6 passes of FSP, compared to that of the alloy in the initial as-annealed state, which was attributed to the fragmentation and redistribution of second-phase particles. By applying FSP, the uniformity of the protective passive layer was improved and, in the meantime, the intensity of micro-galvanic coupling leading to pitting corrosion was decreased.
- Published
- 2021