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Multiferroic properties of SBN–LSMO, SBN–NZCFO and SBN–LSMO–NZCFO particulate composites

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Abstract

Recent studies on nanocrystalline magnetodielectric (MD) composites have shown interesting results. Further, the Sr0.5Ba0.5Nb2O6 (0.5SBN) has proved to be a promising lead free ferroelectric phase to form the magnetoelectric (ME) composites. However, no detailed report on the investigations of MD properties of these composites is available in the literature. Therefore, the present paper reports synthesis and characterization of Sr0.5Ba0.5Nb2O6 (0.5SBN) based ME and MD composites. The ferromagnetic phases La0.67Sr0.33MnO3 (0.33LSMO) and Ni0.85Zn0.1Co0.05Fe2O4 (0.1NZCFO) are so synthesized that both the compositions possess crystallites of nearly 80 nm. 0.5SBN is synthesized using conventional ceramic sintering process, while 0.33LSMO and 0.1NZCFO are synthesized via hydroxide co-precipitation route followed by annealing at higher temperatures. The crystal structure is determined to confirm correct phases of individual compositions. The composites are investigated for the crystal structure, microstructure, dielectric properties, ME coefficients and MD properties. Further, the magnetoelectric coefficient α is sufficiently large. Here, the magnetodielectric properties show presence of stress induced and interfacial polarization induced contributions to the magnetocapacitance (Mc).

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Authors and Affiliations

  1. School of Physical Sciences, Solapur University, Solapur, Maharashtra, India

    S. H. Kshirsagar, A. N. Tarale, D. J. Salunkhe & P. B. Joshi

  2. Walchand Institute of Technology, Solapur, India

    S. R. Jigajeni

  3. Department of Physics, Institute of Science, Mumbai, Maharashtra, India

    S. B. Kulkarni

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  1. S. H. Kshirsagar
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  2. A. N. Tarale
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  3. S. R. Jigajeni
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  4. D. J. Salunkhe
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  6. P. B. Joshi
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Correspondence to P. B. Joshi.

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Kshirsagar, S.H., Tarale, A.N., Jigajeni, S.R. et al. Multiferroic properties of SBN–LSMO, SBN–NZCFO and SBN–LSMO–NZCFO particulate composites. J Mater Sci: Mater Electron 27, 375–385 (2016). https://doi.org/10.1007/s10854-015-3764-y

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