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the results, commented on, and approved the final manuscript.”
“Background Soft magnetic ferrites have attracted Dichloromethane dehalogenase much attention in recent years because they have large saturation magnetization (M s), low electrical conductivity, and excellent chemical stabilities [1, 2] and can be used as ferrofluids [3], in magnetic resonance imaging [4], and in microwave devices [5, 6]. Furthermore, nanoscale soft magnetic ferrites exhibit special magnetic-like, magneto-resistive, and magneto-optical properties compared with bulk magnetic materials [7]. Because the surface-to-volume ratio becomes very large with the reduction of the particle size at nanoscale, they are potentially useful for a broad range of applications. Soft magnetic ferrites have a potential application in electronic devices when used in the gigahertz (GHz) range. This is because in this frequency region, magnetic metals exhibit strong eddy current loss [8] compared to soft magnetic ferrites [9, 10]. For soft magnetic ferrites, there is magnetic resonance, resulting in magnetic losses. This provides some limitations (like threshold frequency) of the application. Nakamura [11] and Tsutaoka et al. [12] reported that the resonance frequency of bulk soft magnetic ferrites is much lower than 1 GHz.

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