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Unprecedented heat resistance of Fe-based soft magnetic composites realized with tunable double insulation layer: Synergy of MgO diffusion barrier and void-filling SiO2 layer

[Display omitted] •Heat-resistant double-insulated SMCs (Fe@MgO@SiO2) has been introduced.•Fe@MgO@SiO2 SMC retains internal insulation matrix even after annealing at 900 °C.•High temperature annealing improves magnetic properties while core loss is suppressed.•Double-layered SMCs showed 280% increas...

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Published in:Journal of magnetism and magnetic materials 2023-08, Vol.580, p.170893, Article 170893
Main Authors: Jang, Min-Sun, Park, Jong-Min, Kim, Jungi, Sun, Changhyo, Koo, Bonuk, Kim, Hea‐Ran, Kwon, Young-Tae, Yang, Sangsun, Lee, Jung Woo, Kim, Yunseok, Jeong, Jae Won
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Language:English
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Summary:[Display omitted] •Heat-resistant double-insulated SMCs (Fe@MgO@SiO2) has been introduced.•Fe@MgO@SiO2 SMC retains internal insulation matrix even after annealing at 900 °C.•High temperature annealing improves magnetic properties while core loss is suppressed.•Double-layered SMCs showed 280% increased mechanical strength after high temperature annealing. Soft magnetic composites (SMCs) comprising surface-insulated Fe powders have attracted significant attention owing to their capability of producing innovative three-dimensional cores with high magnetic flux density and their potential utilization in various electrical machinery fields. The aim of this study is to fabricate SMCs with an inorganic double insulating layer, which can substantially enhance heat resistance and enable enhanced magnetic and mechanical performance through high-temperature annealing. Herein, SMCs with different inorganic coating materials (single layers of SiO2, MgO, and PO4 and double-layers of MgO and SiO2) were prepared by a sol–gel method and powder compaction. In particular, a certain double-layered SMC core (Fe@MgO@SiO2) exhibited retention of internal insulation matrix even after annealing at 900 °C and a significantly suppressed core loss owing to synergistic effects of a diffusion barrier in the primary layer and an electrical insulator in the secondary layer. As anticipated, high-temperature heat treatment at > 700 °C reduced coercivity, which enhances permeability and hysteresis loss of SMCs. The double-layered SMCs also showed an increase in flexural strength of 280% when the annealing temperature was increased from 600 to 900 °C.
ISSN:0304-8853
DOI:10.1016/j.jmmm.2023.170893