Revealing the effects of cooling rate on soft magnetic properties of (Fe0·9Co0·1)86Ni1B13 amorphous alloy

Cooling rate is the key factor affecting soft magnetic properties of amorphous ribbons. So, is the faster the cooling rate conducive to better soft magnetic performance as theoretical hypotheses? The uncertainty of the debate on this issue in practical application motivates the present work. (Fe0.9C...

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Bibliographic Details
Published in:Intermetallics 2022-07, Vol.146, p.107583, Article 107583
Main Authors: Miao, Jiakai, Fan, Yanzhou, Li, Hailong, Li, Xitao, Chen, Chen, Wei, Ran, Wang, Tan, Wu, Shaojie, Li, Fushan
Format: Article
Language:English
Subjects:
Amorphous alloys
Amorphous structure
Cooling
Cooling effects
Cooling rate
Electric devices
Fe-based amorphous alloy
Heat treating
Magnetic domain
Magnetic properties
Magnetic structure
Metallic glasses
Residual stress
Ribbons
Soft magnetic materials
Surface properties
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Summary:Cooling rate is the key factor affecting soft magnetic properties of amorphous ribbons. So, is the faster the cooling rate conducive to better soft magnetic performance as theoretical hypotheses? The uncertainty of the debate on this issue in practical application motivates the present work. (Fe0.9Co0.1)86Ni1B13 amorphous ribbons with different thicknesses were prepared by deliberately varying the cooling rate. It was found that the amorphous ribbon prepared at a lower cooling rate exhibits better soft magnetic properties than the one prepared at a higher cooling rate. The reasons behind the improvement of the soft magnetic properties of amorphous ribbons were investigated in this work. The results prove that cooling rate strongly affect the surface morphology and residual stress of amorphous ribbons and thus the magnetic structure and properties of amorphous ribbons. On the premise of ensuring the formation of amorphous structure, high surface quality and low defects density of the ribbon prepared at low cooling rate promise candidates for the potential application in electric devices rather than the ribbons prepared at a high cooling rate. •The pinned field (Hp) of the ribbons gradually decreases with decreasing the cooling rate.•Ribbons synthesized at slow cooling rate shows smooth surface and better soft magnetic properties.•The variation in the coercivity is interpreted based on magnetic domain structure.
ISSN:0966-9795
1879-0216
DOI:10.1016/j.intermet.2022.107583