Deformation-Thermal Co-Induced Ferromagnetism of Austenite Nanocrystalline FeCoCr Powders for Strong Microwave Absorption

Nanocrystalline soft magnetic alloy powders are promising microwave absorbents since they can work at diverse frequencies and are stable in harsh environments. However, when the alloy powders are in austenite phase, they are out of the screen for microwave absorbents due to their paramagnetic nature...

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Bibliographic Details
Published in:Nanomaterials (Basel, Switzerland) Switzerland), 2022-06, Vol.12 (13), p.2263
Main Authors: Fu, Ziwen, Chen, Zhihong, Wang, Rui, Xiao, Hanyan, Wang, Jun, Yang, Hao, Shi, Yueting, Li, Wei, Guan, Jianguo
Format: Article
Language:English
Subjects:
Absorbents
Absorption
Alloy powders
Anisotropy
Austenite
Ball milling
Complex permittivity
Deformation
Ferromagnetism
Grain size
Harsh environments
Heat
Heat treatment
Heat treatments
High temperature
induced ferromagnetism
Industrial products
Iron alloys
Magnetic alloys
Magnetic permeability
magnetic properties
Magnetic saturation
Martensite
Martensitic transformations
Materials selection
Microwave absorption
nanocrystalline alloy absorbents
Nanocrystals
Permeability
Process controls
Stainless steel
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Summary:Nanocrystalline soft magnetic alloy powders are promising microwave absorbents since they can work at diverse frequencies and are stable in harsh environments. However, when the alloy powders are in austenite phase, they are out of the screen for microwave absorbents due to their paramagnetic nature. In this work, we reported a strategy to enable strong microwave absorption in nanocrystalline austenite FeCoCr powders by deformation-thermal co-induced ferromagnetism via attritor ball milling and subsequent heat treatment. Results showed that significant austenite-to-martensite transformation in the FeCoCr powders was achieved during ball milling, along with the increase in shape anisotropy from spherical to flaky. The saturation magnetization followed parabolic kinetics during ball milling and rose from 1.43 to 109.92 emu/g after milling for 4 h, while it exhibited a rapid increase to 181.58 emu/g after subsequent heat treatment at 500 °C. A considerable increase in complex permeability and hence magnetic loss capability was obtained. With appropriate modulation of complex permittivity, the resultant absorbents showed a reflection loss of below −6 dB over 8~18 GHz at thickness of 1 mm and superior stability at 300 °C. Our strategy can broaden the material selection for microwave absorbents by involving Fe-based austenite alloys and simply recover the ferromagnetism of industrial products made without proper control of the crystalline phase.
ISSN:2079-4991
2079-4991
DOI:10.3390/nano12132263