Influence of Various Alloying Element Additions on Microstructure and Magnetic and Mechanical Properties and Corrosion Behavior of Cast Fe–Ga–Z Shape Memory Alloys
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引用次数: 0
Abstract
Abstract Fe–Ga alloys are attractive materials where high mechanical strength, toughness, ductility, and large low-field magnetostriction combine to give unique properties. Adding alloying elements is an effective method to further enhance these properties. In order to integrate these alloys into the operating environments, e.g., micro-robots and magnetic actuators, the corrosion behavior should be addressed. This work analyzed the microstructure, magnetization, hardness, and corrosion properties of Fe 81 Ga 19− x Z x ( X = 5 at.% of Ni, Mn, or Ti, and 2 at.% Al; separately) alloys. X-ray diffraction (XRD), scanning electron microscope-electron (SEM), vibrating sample magnetometer (VSM), Vickers hardness (HV), and a potentiostat were used for characterization. XRD revealed that the prominent peak belongs to the bcc disorder A2 phase and a small peak for the cubic order L1 2 phase. Fe–Ga–Al alloy got the maximum Ms value, while Fe–Ga–Mn alloy gained the lowest one. However, the Mr and Hc properties for Fe–Ga alloy were distinctly improved by adding Al but slightly affected by doping Mn. Addition of Ti achieved the highest hardness, followed by Ni, Mn, and Al. The microstructure of the different alloys significantly influenced their corrosion behavior. Fe–Ga–Mn alloy with the fine globular grain structure showed the lowest corrosion rate (C R = 0.03 mm/year), whereas Fe–Ga–Al alloy with the coarse longitudinal grains exhibited the highest corrosion rate (C R = 0.19 mm/year).
期刊介绍:
The journal Metallography, Microstructure, and Analysis publishes original, peer-reviewed research articles on engineered materials, which are defined as both processed and inorganic. The journal focuses on the art and science of preparing, interpreting, and analyzing microstructures for the purpose of understanding material behavior and performance, and serves as a forum for engineers and scientists to exchange the latest information regarding the evolution of microstructures in a variety of materials.
Topics focus on the role of microstructure in engineering processes and materials properties. Specifically, the journal publishes contributions that discuss the ways in which microstructures can influence, or arise from:
1) Mechanical and thermal processing of metals, alloys, and ceramics 2) Environmental degradation (such as oxidation and corrosion)3) Welding, casting, and solidification processes4) Additive or digital manufacturing techniques 5) Failure of engineering structures, and6) Electronic materials.
In addition to these general topics, the journal covers a wide range of more specialized materials science and metallurgy issues, such as the characterization of building materials, archaeometallurgy, high-strain-rate phenomena, tribological surfaces and interfaces, superplasticity, and radiation effects. Also of interest are new and alternative techniques for microstructural examination and analysis (including metallography, ceramography, and microscopy), computer-aided microstructural analysis, and techniques for physical and chemical analysis as they relate to microstructure.
Contributions that present a complete treatment of a microstructure, from its formation to preparation techniques to interpretation and analysis, are especially of interest to the journal.
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