Exploring the Influence of Zinc Doping on Nano Ferrites: A Review of Structural, Dielectric, and Magnetic Studies

IF 0.5 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
R. C. Bharamagoudar, A. S. Patil, S. N. Mathad, L. B. Kankanawadi
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Abstract

Ferrites, known for their unique magnetic, structural, and electrical properties, have garnered significant attention across various scientific and industrial domains. This review provides a comprehensive analysis of the effects of zinc doping on three prominent ferrite materials: MnFe2O4, CuFe2O4, and CaFe2O4. Zinc doping, as a strategic method for tailoring these properties, has emerged as a promising avenue for enhancing their functionality and versatility. In the introduction part to the significance of ferrites, their wide-ranging applications are discussed. This review provides a basic overview of the many synthesis methods, such as co-precipitation, sol–gel, hydrothermal, solid-state etc., and a detailed investigating some nano ferrites. It then delves into the distinct characteristics of each ferrite, highlighting their magnetic behaviors, structural features, and electrical properties. The different methods to study the structural, magnetic, and dielectric properties are also discussed. The effects of zinc doping on MnFe2O4, CuFe2O4, and CaFe2O4 ferrites are discussed comprehensively. This study extensively concentrates on recent industrial applications like photoluminescence, biomedical, and sensors using spinel ferrites.

Abstract Image

Abstract Image

探索锌掺杂对纳米铁氧体的影响:结构、介电和磁性研究综述
摘要铁氧体以其独特的磁性、结构和电学特性而闻名,在各个科学和工业领域都引起了极大的关注。本综述全面分析了锌掺杂对三种主要铁氧体材料的影响:MnFe2O4、CuFe2O4 和 CaFe2O4。掺锌作为调整这些特性的一种策略性方法,已成为增强其功能性和通用性的一条大有可为的途径。在介绍铁氧体重要性的部分,讨论了铁氧体的广泛应用。本综述概述了共沉淀、溶胶-凝胶、水热、固态等多种合成方法,并详细研究了一些纳米铁氧体。然后深入探讨了每种铁氧体的不同特性,重点介绍了它们的磁性行为、结构特征和电学特性。此外,还讨论了研究结构、磁性和介电性质的不同方法。还全面讨论了锌掺杂对 MnFe2O4、CuFe2O4 和 CaFe2O4 铁氧体的影响。本研究广泛集中于使用尖晶铁氧体的光致发光、生物医学和传感器等最新工业应用。
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来源期刊
CiteScore
1.00
自引率
33.30%
发文量
27
期刊介绍: International Journal of Self-Propagating High-Temperature Synthesis  is an international journal covering a wide range of topics concerned with self-propagating high-temperature synthesis (SHS), the process for the production of advanced materials based on solid-state combustion utilizing internally generated chemical energy. Subjects range from the fundamentals of SHS processes, chemistry and technology of SHS products and advanced materials to problems concerned with related fields, such as the kinetics and thermodynamics of high-temperature chemical reactions, combustion theory, macroscopic kinetics of nonisothermic processes, etc. The journal is intended to provide a wide-ranging exchange of research results and a better understanding of developmental and innovative trends in SHS science and applications.
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