Journal
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING
Volume 840, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.msea.2022.142964
Keywords
Fe-Cr-Al alloys; Zr -addition; Laves phase; Particle stimulated nucleation; Recrystallization
Categories
Funding
- National Natural Science Foundation of China [U1867201]
- Key Project of Nuclear Safety and Advanced Nuclear Technology [2019YFB1901002]
- State Key Laboratory of Powder Metallurgy, Central South University, Changsha, China
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This study investigates the effects of coarse Laves phase on the recrystallization behavior of Fe-Cr-Al alloys. The results show that the presence of coarse Laves phases in the matrix leads to finer grains due to particle stimulated nucleation (PSN). Zr addition increases the proportion of coarse Laves phase, promoting PSN and resulting in a fine grain size in the Fe-Cr-Al alloys. The Zr-modified Fe-Cr-Al sample with coarse Laves phases exhibits a high ultimate tensile strength of 600 MPa and an elongation of 28%, indicating improved formability. The superior combination of strength and ductility in this sample is attributed to grain refinement and discontinuous deformation. This study provides insights into the behavior and effects of coarse Laves phase, and offers potential for further design and microstructure control of Fe-Cr-Al alloys.
This study investigates the coarse Laves phase stimulated nucleation of recrystallization behavior in iron--chromium-aluminum (Fe-Cr-Al) alloys. The results reveal that the samples with coarse Laves phases in the matrix have finer grains because of the occurrence of particle stimulated nucleation (PSN). Due to the lower diffusion coefficient and lower solubilities of Zr in the bcc matrix, Zr addition increases the proportion of the coarse Laves phase, which promotes the PSN, resulting in a fine grain size in the Fe-Cr-Al alloys. The ultimate tensile strength of the Zr-modified Fe-Cr-Al sample with coarse Laves phases in the matrix reaches-600 MPa, and the elongation is up to-28%. Additionally, the high elongation of this sample could greatly improve its formability. The superior combination of strength and ductility is attributed to grain refinement and discon-tinuous deformation. This study could be expected to provide a better understanding of the coarse Laves phase, such as accelerated recrystallization behavior and beneficial effects on the mechanical properties, and provides potential freedom for further design and microstructure control of Fe-Cr-Al alloys.
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