Journal
IEEE MAGNETICS LETTERS
Volume 11, Issue -, Pages -Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/LMAG.2020.2974144
Keywords
Milling; Powders; Annealing; Soft magnetic materials; Permeability; Amorphous magnetic materials; Magnetic flux; Soft magnetic materials; flakes; amorphous; magnetodielectric inductors
Funding
- Rogers Corporation
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Flake-shaped FeSi-based metallic amorphous alloy particles, having an aspect ratio as high as 175:1, were prepared by ball-milling gas-atomized amorphous powders of an effective diameter of 20 mu m. The starting powder has a saturation magnetic flux density B-s of 1.5 T and a coercivity H-c of 94 A/m. The aspect ratio of the flakes, as well as their magnetic properties, were controlled by milling process parameters, such as duration, speed, and the type, mass, and diameter of the milling balls. To minimize the oxidation of the charge, the powders were handled in an argon gas-purged glove box, milled in toluene, and subsequently dried in vacuo. Subsequently, soft magnetodielectric composites were prepared by suspending and aligning the FeSi-based powders in paraffin wax or epoxy resin. The composites were then pressed into toroids for measurements of their high-frequency complex permeability by a vector network analyzer. The influence of the flakes' aspect ratio and volume loading fraction on the permeability of the composites were investigated. Results indicate that the composite permeability increases with the flakes' aspect ratio. For example, for a given loading factor of 30 vol.%, the composite permeability at 0.1 GHz nearly tripled and approached the value of 10 by increasing the aspect ratio of the FeSi-based inclusions from 1 (spheres) to greater than 175:1 (flakes).
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