Gradient soft magnetic materials produced by additive manufacturing from non-magnetic powders

[Display omitted] •Additive manufacturing of gradient soft-magnets.•In-situ melting during the direct energy deposition.•3D printing of magnetic materials from paramagnetic powders.•The saturated magnetization value of alloys is 49 emu g−1. Additive manufacturing (AM) allows printing parts of comple...

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Bibliographic Details
Published in:Journal of materials processing technology 2022-02, Vol.300, p.117393, Article 117393
Main Authors: Dubinin, O.N., Chernodubov, D.A., Kuzminova, Y.O., Shaysultanov, D.G., Akhatov, I.S., Stepanov, N.D., Evlashin, S.A.
Format: Article
Language:English
Subjects:
Additive manufacturing
Aluminum bronzes
Body centered cubic lattice
Copper
Direct Energy Deposition (DED)
Face centered cubic lattice
Gradient structure
In-situ alloying
Magnetic alloys
Magnetic materials
Magnetic properties
Magnetism
Manufacturing
Optimization
Phase composition
Physical properties
Printing
Soft magnets
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Summary:[Display omitted] •Additive manufacturing of gradient soft-magnets.•In-situ melting during the direct energy deposition.•3D printing of magnetic materials from paramagnetic powders.•The saturated magnetization value of alloys is 49 emu g−1. Additive manufacturing (AM) allows printing parts of complex geometries that cannot be produced by standard technologies. Besides, AM provides the possibility to create gradient materials with different structural and physical properties. We, for the first time, printed gradient soft magnetic materials from paramagnetic powders (316L steel and Cu-12Al-2Fe (in wt.%) aluminium bronze)). The magnetic properties can be adjusted during the in-situ printing process. The saturated magnetization value of alloys reaches 49 emu g−1. The changes in the magnetic properties have been attributed to the formation of the BCC phase after mixing two FCC-dominated powders. Moreover, the phase composition of the obtained gradient materials can be predicted with reasonable accuracy by the CALPHAD approach, thus providing efficient optimization of the performance. The obtained results provide new prospects for printing gradient magnetic alloys.
ISSN:0924-0136
1873-4774
DOI:10.1016/j.jmatprotec.2021.117393