부산대학교 도서관

According to the laws of magnetism, the shape of magnetically soft objects limits the effective susceptibility. For example, spherical soft magnets cannot display an effective susceptibility larger than 3. Although true for macroscopic multi-domain magnetic materials, we show that magnetic nanoparticles in a single-domain state do not suffer from this limitation. This is a consequence of the particle moment being forced to saturation by the predominance of exchange forces, and only allowed to rotate coherently in response to thermal and/or applied fields. We apply statistical mechanics to determine the static and dynamic susceptibility of single-domain particles as a function of size, temperature and material parameters. Our calculations reveal that spherical single-domain particles with large saturation magnetisation and small magneto-crystalline anisotropy, e.g. FeNi particles, can have very a large susceptibility of 200 or more. We further show that susceptibility and losses can be tuned by particle easy axis alignment with the applied field in case of uniaxial anisotropy, but not for particles with cubic anisotropy. Our model is validated experimentally by comparison with measurements on nanocomposites containing spherical 11$\pm$3 nm $\gamma$-Fe$_2$O$_3$ particles up to 45 vol% finely dispersed in a polymer matrix. In agreement with the calculations for this specific material, the measured susceptibility of the composites is up to 17 ($\gg$3) and depends linearly on the volume fraction of particles. Based on these results, we predict that nanocomposites of 30 vol% of superparamagnetic FeNi particles in an insulating non-magnetic matrix can have a sufficiently large susceptibility to be used as micro-inductor core materials in the MHz frequency range, while maintaining losses below state-of-the-art ferrites.
Comment: 10 pages, 5 figures, 1 table, 20 numbered equations