The influence of annealing temperature on hyperfine magnetic field and saturation magnetization of Fe–Si–Al–Cr flake-shaped particles

Fe75Si13Al10Cr2 flake-shaped particles were prepared from crushing ingots with ball milling method. In order to explore the relationship between microstructure and saturation magnetization (Ms), the particles were annealed under nitrogen atmosphere at different temperature. The XRD results show that...

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Bibliographic Details
Published in:Journal of alloys and compounds 2016-07, Vol.672, p.176-181
Main Authors: Zhang, Nan, Li, Gang, Wang, Xin, Liu, Tao, Xie, Jianliang
Format: Article
Language:English
Subjects:
Alloys
Aluminum
Annealing
Fe–Si–Al–Cr particles
Magnetic fields
Microstructure
Mossbauer spectroscopy
Mössbauer spectra
Saturation (magnetic)
Saturation magnetization
Temperature
Transformations
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Summary:Fe75Si13Al10Cr2 flake-shaped particles were prepared from crushing ingots with ball milling method. In order to explore the relationship between microstructure and saturation magnetization (Ms), the particles were annealed under nitrogen atmosphere at different temperature. The XRD results show that the DO3 ordered phase coexists with α-Fe (Si, Al, Cr) matrix phase by annealing above 500 °C. Mössbauer spectroscopy measurements show that the hyperfine magnetic field (HMF) of the original particles has wide distribution. On the contrary, the HMF of the annealed powders can be easily distinguishable with each other, indicating that the crystal structure of the material has a disorder-order change. The Mössbauer spectra can be fitted with 4 sextets representing 4 different Fe-site environments, and there is a significant change on the ratios of Fe-site environments with annealing temperature. The change leads to an obviously increase of the average hyperfine magnetic field ( ) with increasing annealing temperature. For this alloy, Ms has linear relationship with Fe atomic magnetic moment (μFe) and  has an approximate linear relationship with μFe. So the Ms of the particles also has an obviously increase with annealing temperature. Ms and  have an obvious turning point at 600 °C, because of the HMF values decrease of 8Fe-site and 6Fe-site, which comes from a DO3-B2 ordered transformation. [Display omitted] •Ms of the powders has an obvious increase with increasing annealing temperature.•Two major phases exist in the powders after annealing: DO3 and A2.•There are 4 different Fe-site environments in the annealed particles.•The change of Fe-sites ratios is the main factor for the improvement of and Ms.•A DO3-B2 phase transformation leads to an obvious turning point of Ms and .
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2016.02.154