Journal
JOURNAL OF ALLOYS AND COMPOUNDS
Volume 859, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.jallcom.2020.157850
Keywords
Fe-based amorphous alloys; Microalloying; Crystallization behavior; Saturation magnetization; Bending ductility
Categories
Funding
- Talent Introduction Funding Special Project of Guangdong Academy of Sciences [202101030066]
- Guangdong Basic and Applied Basic Research Foundation [2019A1515010886]
- Key Technology Project of Foshan [1920001001392]
- National Natural Science Foundation of China [52071089]
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In this study, the effects of adding different ferromagnetic elements, metallic elements with strong non-metallic properties, and transition metal elements with large atomic radius on the crystallization behavior, magnetic properties, and ductility of Fe85Si0.5B9P4Cu0.5C0.1M0.9 alloys were systematically investigated. Through optimal heat treatments, nanocrystalline alloys exhibited excellent soft magnetic properties but further understanding of the microscopic mechanism of plastic deformation and achieving high toughness in amorphous alloys is crucial.
Effects of the minor addition of similar ferromagnetic elements (Fe, Co, Ni, and Gd), metal element with strong non-metallic properties (Al), and transition metal elements with large atomic radius (V, Hf, Ti, and Cr) on crystallization behavior, magnetic properties and bending ductility of Fe85Si0.5B9P4Cu0.5C0.1M0.9 alloys were systematically investigated. The addition of Al, Ni, and Co improves the thermal stability and inhibits the growth of the a-Fe grains. Besides, Gd addition causes a large temperature interval, which suppresses the precipitation of secondary phase. Through the optimum heat treatments, the nanocrystalline alloys exhibit excellent soft magnetic properties, such as higher Ms of 191.7-208.7 emu/g and lower Hc of 6.7-12.1 A/m. Due to the nature of brittleness, the shear morphology induced by elemental microalloying is critical for understanding microscopic mechanism of plastic deformation and achieving high toughness amorphous alloys. We demonstrate that the formation of shear bands are related to the degree of amorphization, shear transformation zones and Poisson's ratio. (C) 2021 Elsevier B.V. All rights reserved.
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