Sai Vittal Battula scite author profile

Understanding the efects of interparticle interactions is a vital problem because magnetic nanoparticles showcase a variety of magnetic conigurations due to diferent contributions to their total energy. To derive reliable and robust properties from magnetic nanoparticles, it is, thus, necessary to understand the competition between particle anisotropy and interparticle interactions that deine the magnetic state of nanoparticles, where size control plays an important role. Here, we apply the random anisotropy model (RAM) that considers various magnetic interactions to selectively prepared NiCr nanostructures (NiCr dense nanoclusters, nanogranular NiCr thin ilms, and Ag(NiCr) nanocomposites) with diferent interparticle interactions. The estimated single-particle magnetic anisotropy K values (2.82 − 12.3 × 10 4 J/m 3 ) and careful analysis of magnetization behavior for these nanostructures reveal that orbital hybridization, surface segregation, and interface character govern the magnetic interactions among nanoparticles. Our study demonstrates how magnetic behaviors vary in these diferent magnetic systems consisting of superparamagnetic (SPM) and ferromagnetic (FM) contributions speciic to magnetic interactions.

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Competing Magnetic Interactions in Inverted Zn-Ferrite Thin Films

Bohra

Battula

Singh

et al. 2022

Magnetism

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Zn-ferrite is a versatile material among spinels owing to its physicochemical properties, as demonstrated in rich phase diagrams, with several conductive or magnetic behaviors dictated by its cation inversion. The strength and the type of cation inversion can be manipulated through the various thermal treatment conditions. In this study, inverted Zn-ferrite thin films prepared from radio frequency magnetron sputtering were subjected to different in situ (in vacuum) and ex situ (in air) annealing treatments. The temperature and field dependence of magnetization behaviors reveal multiple magnetic interactions compared to its bulk antiferromagnet behavior. Using the magnetic component model, the different magnetic interactions can be explained in terms of superparamagnetic (SPM), paramagnetic (PM), and ferrimagnetic (FM) contributions. At low temperatures, the SPM and FM contributions can be approximated to the hard and soft ferrimagnetic phases of Zn-ferrite, respectively, which changes with the annealing temperature and sputter power. Distinct magnetic properties emanating from in situ annealing compared to the ex situ annealing were ascribed to the nonzero Fe2+/Fe3+ ratio, leading to the different magnetic interactions. The anisotropy was found to be the key parameter that governs the behavior of annealed in situ samples.

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Sai Vittal Battula

Exploration of room-temperature magnetocaloric effect in nanogranular Ni–Cr thin films

Design of various Ni–Cr nanostructures and deducing their magnetic anisotropy

Competing Magnetic Interactions in Inverted Zn-Ferrite Thin Films

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