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of the ferromagnetic Fe single crystal, K1 = 4.8 × 104 J m−3 and K2 = 5 × 103 J m−3 were found, where K1 is in this case with approximately one order of magnitude larger than K2.

      Source: Caizer (2016). Reprinted by permission from Springer Nature.

      Also, in this case, the first two terms are used (in K1 and K2) in the energy expression of uniaxial magnetocrystalline anisotropy.

      In this case, the main axis of symmetry is the easy magnetization axis (e.m.a), and the direction perpendicular to it is the hard magnetization axis (h.m.a).

      In the case of bulk magnetic material, there is another important form of magnetic anisotropy, which should not be neglected as it can become dominant in some cases. This is the anisotropy of the shape (Kneller 1962; Caizer 2004a), which shows that the magnetization of a sample depends on its shape.

      where Na and Nb are the demagnetization factors along the a and b directions of the ellipsoid, and θ is the angle that the spontaneous magnetization vector Ms makes with the main axis (a) of the ellipsoid.

Schematic illustration of the crystal approximated by an ellipsoid.

      Source: Caizer (2019). Reprinted by permission of Taylor & Francis Ltd.

      (1.18)equation

      in the approximation of the first order.

      When the magnetic material is reduced to the nanoscale, these forms of magnetic anisotropy remain valid. In addition, in the case of magnetic nanoparticles, the shape anisotropy becomes very important, reaching in some cases even larger, or much larger than the magnetocrystalline anisotropy. Thus, the neglect of this first aspect leads to important errors from a magnetic point of view, incompatible with the physical reality. For example, if the nanoparticle is spherical in shape (Figure 1.5), the semiaxes a, b, c become equal (Figure 1.10), and equal to the radius of the sphere. According to Eqs. the shape anisotropy constant in this case is zero, as is the energy. So there is no shape anisotropy in the case of spherical nanoparticles. In contrast, in the case of elongated nanoparticles, when ab = c, and when they are soft magnetic (magnetocrystalline anisotropy is reduced), the shape anisotropy exceeds the magnetocrystalline anisotropy, or even becomes dominant. This is an important aspect in the case of magnetic nanoparticles that must be taken into account not only in practical applications, including biomedical ones, but also in theoretical calculations and models/experiments.

      (1.19)equation

Schematic illustration of the orientation of spontaneous magnetization M right arrow s relative to normal n right arrow on the surface (a) (100) for the monocrystal with cubic symmetry.
relative to normal images on the surface (a) (100) for the monocrystal with cubic symmetry.

      Source: Caizer (2019). Reprinted by permission of Taylor & Francis Ltd.

      For example (Caizer 2004a), in the case of spherical nanoparticles with a diameter D of 10 nm, the value of ~6 × 103 expressed in J m−3 is obtained for the surface anisotropy constant. This value is five times higher than the magnetocrystalline anisotropy of the Ni–Zn ferrite, which is 1.5 × 103 J m−3 (Broese Van Groenou et al. 1967). Therefore, this form of magnetic anisotropy must be considered in the case of magnetic nanoparticles.

      Moreover,

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