Large enhancements of magnetic anisotropy in oxide-free iron nanoparticles

Magnetic characterization of spherical, oxide-free, bcc iron nanoparticles synthesized with β-diketone surfactants has been performed. The results of this characterization, which included particles with diameters ranging between 2 and 5 nm show that the nanoparticles have an average anisotropy of 1.9×106±0.3×106 J/m3, which is more than an order of magnitude greater than the magnetocrystalline anisotropy of bulk iron. Despite their unusually large anisotropy, these particles can have saturation magnetizations of up to 210 A m2/kg (slightly lower than bulk iron). High-energy X-ray diffraction data indicates that the Fe particles have a distorted bcc lattice, which could, at least in part, explain the magnetic behavior of these nanoparticles. Dipolar coupling between particles, while present, is weak and cannot account for the high anisotropy of these nanoparticles.

► Oxide-free, iron nanoparticles with β-diketone surfactants were synthesized.
► Nanoparticles have anisotropy (K1) two orders of magnitude greater than bulk.
► Particles have weak dipolar coupling that does not explain enhanced anisotropy.
► Structure studied by X-ray diffraction and pair distribution function analysis.
► Particles have expanded lattice that may explain high anisotropy.