Review of Surface Treatment Technology for Improving Wear Resistance
of Magnesium Alloys

Chengyi      Pan; Jingren      Zhang; Shuhao      Li
doi:10.2174/1872212118666230915103755
Abstract

Background: As the lightest metal structural material in engineering, magnesium alloy has excellent mechanical properties, such as high specific strength, high specific stiffness, good damping performance, and good machinability. It is widely used in the fields of precision parts, automobiles, aerospace, and military. However, poor friction and wear performance are significant magnesium defects of the alloys, which make its use limited in some areas with high working conditions, so it is essential to improve the wear resistance of the magnesium alloy surface.
Objective: The aim of this study was to summarize the technology of improving the wear resistance of magnesium alloy in recent year. The influence of different surface treatment technology for enhancing friction and wear properties was also analyzed, which could provide a reference for related scholars and researchers.
Method: In this paper, the literature and patents related to friction and wear properties of magnesium alloys in recent years were reviewed, the principles of various surface treatment technology of magnesium alloys were explained, and the advantages and disadvantages of each technology were analyzed.
Results: Based on the literature and patents analyses related to the wear resistance of magnesium alloys, the problems existing in the surface treatment technology for improving the wear resistance of magnesium alloys are summarized, and future development directions are put forward.
Conclusion: Among the technologies and patents to improve the wear resistance of magnesium alloys, the combination of various techniques can better meet the working demands. The environmentally friendly and efficient manner has a good prospect for development.
Graphical Abstract

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DOI https://dx.doi.org/10.2174/1872212118666230915103755	Print ISSN 1872-2121
Publisher Name Bentham Science Publisher	Online ISSN 2212-4047
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