Controlling Dipolar Interaction Effect in Two-Dimensional Magnetic Nanostructures

Abstract

We investigate the dependence of magnetic properties on the out-of-plane disorder strength , dipolar interaction strength hd in two-dimensional (lx× ly) ensembles of nanoparticles using numerical simulations. Such positional defects are redundantly observed in experiments. The superparamagnetic character is dominant with negligible and weak interaction strength hd, irrespective of and aspect ratio of the system Ar=ly/lx. The double-loop hysteresis curve, characteristics of antiferromagnetic coupling dominance, emerges with large hd and (\%)≤5 in the square-like nanoparticles' assays. Remarkably, the dipolar interaction of sufficient strength drives the magnetic order from antiferromagnetic to ferromagnetic with large and Ar≤4.0, resulting in an enhancement in the hysteresis loop area. On the other hand, the ferromagnetic coupling gets increased with hd in systems with huge Ar. Consequently, the hysteresis loop is enormous, even with moderate hd. The variation of the coercive field μoHc, remanence Mr, and amount of heat released EH (due to the hysteresis) with these parameters also suggests the transformation of nature dipolar interaction. They are significant even with large hd and smaller Ar, indicating the antiferromagnetic coupling dominance. Interestingly, there is an enhancement in these with and large hd due to ferromagnetic interaction. Notably, they are very significant even with moderate hd in the highly anisotropic system and external field along the long axis of the sample. These results could help the experimentalist in explaining the unusual hysteresis characteristics observed in such systems and should also be beneficial in diverse applications such as data storage, magnetic hyperthermia, etc.