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Spin Disorder and Particle Size Effects in Cobalt Ferrite Nanoparticles with Unidirectional Anisotropy and Permanent Magnet-like Characteristics

Bharati Debnath, H. G. Salunke, Sayan Bhattacharyya

2020The Journal of Physical Chemistry C21 citationsDOI

Abstract

Spinel ferrites, especially cobalt ferrite, have the capability of preserving sufficient magnetization (Ms) and coercive field (Hc). However, precise nanostructuring is needed to sustain the steady ferrimagnetic (FiM) response with high Hc and remnant magnetization (Mr). By a two-step process involving co-precipitation and inert calcination, CoFe2O4 nanoparticles (NPs) with inherent lattice strain were achieved with appreciable magnetic anisotropy. The disordered spins on the NP surface are found to be the key for maintaining the anisotropy and squareness (Mr/Ms) of hysteresis loops, the extent of which is a function of the processing temperature and NP size. The freezing of surface spins results in 2.8 and 1.2 nm thick spin glass (SG) layers for the as-prepared and 350 °C-calcined CoFe2O4 NPs, respectively, analyzed at 5 K. The frozen surface spins pin the core FiM spins, resulting in the exchange bias (Heb) coupling. At room temperature, 20 nm NPs exhibit permanent magnet-like features with a maximum energy product, BHmax, of 2.4 MGOe, which is quite promising considering CoFe2O4 as an environmentally friendly alternative to the hazardous rare-earth-based permanent magnets. Our CoF2O4 NP ensemble delivers both intriguing low-temperature magnetic properties having academic and technological interests and worthwhile room-temperature features that have direct translational relevance.

Topics & Concepts

FerrimagnetismMaterials scienceSpinsCoercivityCondensed matter physicsSuperparamagnetismMagnetMagnetizationAnisotropyMagnetic anisotropyFerrite (magnet)Nuclear magnetic resonanceMagnetic fieldComposite materialOpticsPhysicsQuantum mechanicsMagnetic Properties and Synthesis of FerritesMagnetic properties of thin filmsIron oxide chemistry and applications