Effective macrospin model for CoxFe3-xO4 nanoparticles: decreasing the anisotropy by Co-doping?

Abstract

Co-doping of Fe3O4 magnetic nanoparticles is an effective way to tailor their magnetic properties. When considering the two extreme cases of the CoxFe3-xO4 series, i.e. the x=0 and x=1 values, one finds that the system evolves from a negative cubic-anisotropy energy constant, KC-<0, to a positive one, KC+>0. Thus, what happens for intermediate x-compositions? In this work we present a very simple phenomenological model for the anisotropy, under the macrospin approximation, in which the resultant anisotropy is just directly proportional to the amount of Co. First, we perform a detailed analysis on a rather ideal system in which the extreme values have the same magnitude (i.e. |KC-|=|KC+|) and then we focus on the real CoxFe3-xO4 system, for which |KC+| 18|KC-|. Remarkably, the approach reproduces rather well the experimental values of the heating performance of CoxFe3-xO4 nanoparticles, suggesting that our simple approach may in fact be a good representation of the real situation. This gives rise to an intriguing related possibility arises: a Co-doping composition should exist for which the effective anisotropy tends to zero, estimated here as 0.05.