HIGH ENTROPY ALLOYS |
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Research Progress on Solid Solution Strengthening of High Entropy Alloys |
WEN Cheng1,2, MO Wanwan1, TIAN Yuwan1,2, WANG Gui3, HU Jiezhen3
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1 School of Mechanical and Power Engineering, Guangdong Ocean University, Zhanjiang 524088, China 2 Corrosion and Protection Center, University of Science and Technology Beijing, Beijing 100083, China 3 Guangdong Provincial Ocean Equipment and Manufacturing Engineering Technology Research Center, Zhanjiang 524088, China |
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Abstract There is no identification of solute and solvent in high entropy alloys, compared to traditional alloy materials. The lattice distortion and size mismatch caused by the special composition of high entropy alloys make it possess significant solid solution strengthening effect, and hence lead to excellent mechanical strength. However, classical strengthening theories based on diluted solute assumption cannot be used to describe the strengthening effect of high entropy alloys, so it is hard to accurately predict the strength of high entropy alloys, which hinders the rational design and application research of such alloys. In recent years, some researchers explore the solid solution strengthening origin and try to develop reliable strengthening models to realize the high-throughput prediction of strength/hardness, and ultimately guide the rapid composition design for performance requirement, to promote the scientific research and engineering application of high entropy alloys. In this review, we summarized the research progress on solid solution strengthening of high entropy alloys, introduced three typical strengthening models at present, compared and analyzed the model construction, prediction effect, remaining problems and the specific application in the design of high entropy alloys. Finally, we prospected the exploration of solid solution strengthening mechanism of high entropy alloys, the development and application of strengthening model.
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Published: 26 September 2021
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Fund:National Natural Science Foundation of China (51801033) and the Project of Innovation and Entrepreneurship Training of Guangdong Ocean University (CXXL20200210) |
About author:: Cheng Wenreceived his M.S. degree in materials science and engineering from University of Science and Technology Beijing in 2014. He is now a lecturer of Guangdong Ocean University. His research has focused on machine learning accelerated material design, strengthening mechanism and corrosion behavior of high entropy alloy. Yuwan Tianreceived her Ph.D in materials science and engineering at Corrosion and Protection Center of University of Science and Technology Beijing. She is now a lecturer of Guangdong Ocean University. Her research has focused on protection of marine equipment and corrosion behavior of metal materials like high entropy alloy. |
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