A Study on the Influence of Titanium Addition on the Phase Transformations and Magnetic Properties of FeCrCoNiMn High-Entropy Alloy Powder Prepared by Mechanical Alloying

A Study on the Influence of Titanium Addition on the Phase Transformations and Magnetic Properties of FeCrCoNiMn High-Entropy Alloy Powder Prepared by Mechanical Alloying

Introduction and Objectives: Some novel alloys, including high-entropy alloys, have gained increasing attention due to their diverse properties and applications. This study aims to investigate the relationship between the magnetic properties and phase transformations of the FeCrCoNiMn high-entropy a...

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Bibliographic Details
Main Authors: Mohsen Alizadeh, Saeed-Reza Bakhshi, Mohammad-Reza Dehnavi, Gholam-Hossein Borhani
Format: Article
Language:fas
Published: Isfahan University of Technology 2025-04-01
Series:Journal of Advanced Materials in Engineering
Subjects:
high entropy alloy
fecrconimn
titanium
magnetic properties
mechanical alloying
Online Access:https://jame.iut.ac.ir/article_3612_d21ae58a27a5f70750b60ed9fb0c5b53.pdf
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Summary:Introduction and Objectives: Some novel alloys, including high-entropy alloys, have gained increasing attention due to their diverse properties and applications. This study aims to investigate the relationship between the magnetic properties and phase transformations of the FeCrCoNiMn high-entropy alloy with the addition of titanium.Materials and Methods: The high entropy alloy powder was synthesized by mechanically alloying pure constituent elements in a planetary mill. The synthesized high entropy alloy powder was phase-analyzed using the X-ray diffraction method. Furthermore, phase structure formation was predicted by thermodynamic functions via JMatPro software. The magnetic behavior was analyzed using a vibrating sample magnetometer, and particle morphology was examined using field emission scanning electron microscopy.Results: The FeCrCoNiMn alloy milled includes a single-phase FCC structure after 40 hours. The presence of Ti in the composition of the alloy created BCC and Laves phase structures. Concurrently, the addition of titanium increased both the coercivity force and saturation magnetization. Conclusion: The increase in saturation magnetization is due to the formation of the BCC phase in the FeCrCoNiMnTi alloy, while the BCC phase has a strong exchange interaction between ferromagnetic elements. However, the presence of both the non-magnetic Laves intermetallic phase and interphase boundaries has increased the coercivity force.
ISSN:2251-600X
2423-5733

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