Studies on the Mechanical Alloying of Ni-Fe-Co Powders and Its Explosive Compaction

A bulk nanocrystalline 80Ni-15Fe-5Co (wt pct) soft magnetic material was successfully produced via “mechanical alloying-explosive compaction” route. A rapid grain refining was observed during initial 12 hours of milling in high-energy planetary ball mill, followed by a level-off trend. A comparison...

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Bibliographic Details
Published in:Metallurgical and materials transactions. A, Physical metallurgy and materials science Physical metallurgy and materials science, 2008-11, Vol.39 (11), p.2725-2735
Main Authors: Vajpai, S.K., Dube, R.K., Tewari, A.
Format: Article
Language:English
Subjects:
Alloys
Applied sciences
Atoms & subatomic particles
Characterization and Evaluation of Materials
Chemistry and Materials Science
Exact sciences and technology
Grain boundaries
Grain growth
Grain size
Magnetic fields
Materials Science
Metal powders
Metallic Materials
Metals. Metallurgy
Nanotechnology
Permeability
Plastic deformation
Powder metallurgy
Powder metallurgy. Composite materials
Production techniques
Scanning electron microscopy
Structural Materials
Surfaces and Interfaces
Temperature
Thin Films
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Summary:A bulk nanocrystalline 80Ni-15Fe-5Co (wt pct) soft magnetic material was successfully produced via “mechanical alloying-explosive compaction” route. A rapid grain refining was observed during initial 12 hours of milling in high-energy planetary ball mill, followed by a level-off trend. A comparison of crystallite size of 125-hour-milled mechanically-alloyed (MAed) powder (10 nm) and explosively-compacted material (15 nm) showed negligible grain growth during explosive compaction. It has been shown that no phase change was brought about by the explosive compaction of the milled powder, and Ni 3 Fe remained the predominant phase in both MAed and explosively-compacted material. A possible mechanism of densification of flaky MAed powder during explosive compaction has been proposed, which consisted of the plastic deformation of powder particles into elongated shape followed by joining and folding of elongated particles. This process produced a continuous network of elongated and folded particles in the compact. The bulk nanocrystalline material showed improved magnetic properties, such as high Curie temperature and negligible core loss, making it a promising soft magnetic material for applications involving high temperatures and changing magnetic environment.
ISSN:1073-5623
1543-1940
DOI:10.1007/s11661-008-9617-z