Abstract EN:

We have investigated the effects of dipole-dipole interactions (DDI) on the static and dynamic properties of an assembly of magnetic nanoparticles taking account of the volume and anisotropy axes distributions and the applied magnetic field. We have obtain (approximate) analytical expressions of the magnetization as a function of the applied field, the anisotropy and the intensity of DDI. We have shown that, because of the anisotropy and the interactions, the magnetization can not be described by the Langevin function commonly used in the literature. We have also used the numerical Monte Carlo method to validate these results. The dynamical behaviour of the assembly has been studied by investigating the effect of DDI on the longitudinal relaxation time and thereby on the zero-field-cooled (ZFC) magnetization. We have shown that the effect of DDI is to lower the critical volume of the assembly which separates the dominating populations of blocked and superparamagnetic particles. It has been shown that the maximum of Tmax(H) shifts towards low values of the applied field as the intensity of DDI increases. Our results explain the corresponding experimental observations. In particular, the temperature at the maximum of the ZFC magnetization, as a function of the applied field, changes from a bell-like to a monotonically decreasing curve when the intensity of DDI increases. We emphasized the important role played by damping in the presence of a transverse field provided here by the DDI. In addition, comparing the results for textured and random anisotropy distributions, we have shown that the anisotropy texture play an important role in the variation of the critical volume of an interacting assembly. Finally, using recent works modeling surface within a effective approach, we investigate the competition between the later and DDI and provide a plausible explanation of the observed phenomena.