Improved mechanical properties of a near-eutectic high-entropy alloy via laser melting deposition

•Al0.71CoCrFeNi near-eutectic high-entropy alloy was fabricated using LMD.•Al0.71 mainly comprises FCC dendrites and lamellar FCC-BCC eutectic microstructure.•Both FCC phase and BCC phase in Al0.71 alloy presented chaotic grain orientations.•The LMD Al0.71 alloy can achieve a desirable balance of st...

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Bibliographic Details
Published in:Materials letters 2024-04, Vol.361, p.136084, Article 136084
Main Authors: Xin, Dongqun, Wang, Cong, Guo, Jian, Wu, Chu
Format: Article
Language:English
Subjects:
High-entropy alloy
Laser melting deposition
Mechanical properties
Microstructure
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Summary:•Al0.71CoCrFeNi near-eutectic high-entropy alloy was fabricated using LMD.•Al0.71 mainly comprises FCC dendrites and lamellar FCC-BCC eutectic microstructure.•Both FCC phase and BCC phase in Al0.71 alloy presented chaotic grain orientations.•The LMD Al0.71 alloy can achieve a desirable balance of strength and plasticity. The microstructure and mechanical properties of a dual-phase near-eutectic high-entropy alloy Al0.71CoCrFeNi (Al0.71) prepared by laser melting deposition (LMD) were investigated and compared with those of a single-phase FCC high-entropy alloy Al0.38CoCrFeNi (Al0.38). The Al0.71 consists of 65% FCC and 35% BCC phases, forming a near-eutectic microstructure that includes primary FCC dendrites with minor BCC precipitates, as well as a lamellar FCC-BCC eutectic microstructure. For Al0.71, the aluminum loss induced by evaporation during LMD process leads to a deviation from the intended eutectic composition. Both FCC and BCC phases in Al0.71 display chaotic grain orientations, which can be attributed to the microstructural heterogeneity of the alloy and the complex temperature field generated by the reciprocating scanning during LMD process. The Al0.71 achieved a desirable balance of strength and plasticity due to the synergetic strengthening effects of soft FCC phases and hard BCC phases.
ISSN:0167-577X
1873-4979
DOI:10.1016/j.matlet.2024.136084