Exchange bias and surface effects in bimagneticCoO−core/Co0.5Ni0.5Fe2O4-shell nanoparticles

Bimagnetic nanoparticles have been proposed for the design of new materials with controlled properties, which requires a comprehensive investigation of their magnetic behavior due to multiple effects arising from their complex structure. In this work we fabricated bimagnetic core/shell nanoparticles formed by an $\ensuremath{\sim}3$-nm antiferromagnetic (AFM) CoO core encapsulated within an $\ensuremath{\sim}1.5$-nm ferrimagnetic (FiM) ${\mathrm{Co}}_{0.5}{\mathrm{Ni}}_{0.5}{\mathrm{Fe}}_{2}{\mathrm{O}}_{4}$ shell, aiming at studying the enhancement of the magnetic anisotropy and the surface effects of a ferrimagnetic oxide shell. The magnetic properties of as-synthesized and annealed samples were analyzed by ac and dc magnetization measurements. The results indicate that the magnetic response of the as-synthesized particles is governed by the superparamagnetic behavior of the interacting nanoaggregates of spins that constitute the disordered ferrimagnetic shell, whose total moments block at $\ensuremath{\langle}{T}_{B}\ensuremath{\rangle}=49$ K and collectively freeze in a superspin-glass-type state at $\ensuremath{\langle}{T}_{g}\ensuremath{\rangle}=3$ K. On the other hand, annealed nanoparticles are superparamagnetic at room temperature and behave as an exchange-coupled system below the blocking temperature $\ensuremath{\langle}{T}_{B}\ensuremath{\rangle}=70$ K, with enhanced coercivity ${H}_{C}(10\phantom{\rule{4.pt}{0ex}}\text{K})\ensuremath{\sim}14.6$ kOe and exchange bias field ${H}_{EB}(10\phantom{\rule{4.pt}{0ex}}\text{K})\ensuremath{\sim}2.3$ kOe, compared with the as-synthesized system where ${H}_{C}(10\phantom{\rule{4.pt}{0ex}}\text{K})\ensuremath{\sim}5.5$ kOe and ${H}_{EB}(10\phantom{\rule{4.pt}{0ex}}\text{K})\ensuremath{\sim}0.8$ kOe. Our results, interpreted using different models for thermally activated and surface relaxation processes, can help clarify the complex magnetic behavior of many core/shell and hollow nanoparticle systems.