Soft magnetic composites based on Fe fibres and powders prepared by cold sintering process

The manuscript provides a new strategy for preparation of soft magnetic composites that involves the consolidation of the ferromagnetic phase (fibres or powders), which is first covered with an insulating layer, via the cold sintering process. The manuscript reports on the preparation and characterisation of cold sintered compacts based on Fe fibres and Fe powders coated with ZnO and sintered at the temperature of 200 degrees C for 60 min under the pressure of 600 MPa. The amount of ZnO used as dielectric phase was 10 and 20 wt%. The absence of any reaction between phases that compose the compacts (Fe fibres or powders and ZnO) during the cold sintering process was proved by X-ray diffraction (XRD). Electron microscopy and Xray micro-analysis (SEM-EDX) were used for morphology and chemical analysis of the cold sintered compacts. The influence of the type of ferromagnetic phase (fibres or particles), as well as the influence of the amount of dielectric phase on the saturation induction (Bs), the coercive field (Hc), and the maximum relative permeability (mu rmax) of the cold sintered magnetic cores, was investigated and discussed. The effect of the same factors on the total core power losses (P) and the initial relative permeability (mu ri) of the cold sintered compacts, upon increasing the frequency of the magnetising field up to 10 kHz, was analysed. The feasibility of applying a heat treatment at the temperature of 450 degrees C for 1 h was investigated, leading to the enhancement of both DC and AC magnetic properties of the cold sintered compacts. (c) 2022 Elsevier B.V. All rights reserved.

Automated summary

The manuscript proposes a new strategy for preparing soft magnetic composites through the cold sintering process. It investigates the consolidation of ferromagnetic phase with an insulating layer and explores the influence of dielectric phase content on the magnetic properties. The feasibility of heat treatment for improving the magnetic properties of the cold sintered compacts is also examined.