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Nanostructured Hexagonal Ferrites
Novel Characteristics and Multifunctional Applications
- 1st Edition - June 18, 2024
- Editors: Susheel Kalia, Rohit Jasrotia, Virender Pratap Singh
- Language: English
- eBook ISBN:9 7 8 - 0 - 4 4 3 - 1 8 5 5 7 - 1
Nanostructured Hexagonal Ferrites: Novel Characteristics and Multifunctional Applications presents the latest advances in hexaferrite nanostructures, which offer reliabili… Read more
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Request a sales quoteNanostructured Hexagonal Ferrites: Novel Characteristics and Multifunctional Applications presents the latest advances in hexaferrite nanostructures, which offer reliability, stability, and efficiency in a range of advanced applications. The book begins by introducing the structure, characteristics, fabrication, processing, characterization methods, and composites of hexagonal ferrites in detail. Solid-state chemistry and magnetic, magnetoelectric, multiferroic, and dielectric properties are examined. Subsequent chapters then provide in-depth coverage of the preparation of nanohexaferrites with specific properties for target applications, in areas such as magnetic energy storage, high-frequency devices, microwave devices, stealth technologies, gyromagnetic devices, and wastewater remediation.
This is a valuable resource for researchers and advanced students across nanotechnology, polymer science, composite science, chemistry, and materials science and engineering, as well as industrial scientists, engineers, and R&D professionals with an interest in hexaferrites and advanced nanostructures for advanced applications.
- Introduces fabrication, characterization, processing, and preparation methods for hexagonal ferrites
- Analyzes structure and properties of nanohexaferrites and their suitability in a range of applications
- Opens the door to novel utilizations across electronic devices, energy storage, and wastewater remediation
Academia: Researchers and advanced students across nanotechnology, polymer science, composite science, chemistry, and materials science and engineering. Industry: Scientists, engineers, and R&D professionals with an interest in hexaferrites and advanced nanostructures for a range of advanced applications (electronics, environment, etc.)
- Cover image
- Title page
- Table of Contents
- Copyright
- Contributors
- About the editors
- Preface
- Chapter 1. Hexagonal nanoferrites: Structure, characteristics, fabrication and characterization
- 1.1. Introduction
- 1.2. Conclusions
- 1.3. Future scope
- Chapter 2. Processing and applications of hexagonal ferrite-based nanomaterials
- 2.1. Introduction
- 2.2. Properties of ferrites
- 2.3. Classification of ferrites
- 2.4. Classification and structure of hexaferrite
- 2.5. Synthesis techniques for the fabrication of hexagonal ferrite–based nanomaterials
- 2.6. Applications of hexaferrites
- 2.7. Conclusion
- 2.8. Future scope
- Chapter 3. Hexagonal nanoferrites: Preparation techniques for tailored properties and diverse applications
- 3.1. Introduction
- 3.2. Preparation techniques for hexagonal nanoferrites
- 3.3. Applications of hexagonal nanoferrites
- 3.4. Conclusion
- Chapter 4. Fabrication of hexagonal nanoferrites-based fibres for diverse applications
- 4.1. Introduction
- 4.2. Fabrication of hexagonal nanoferrites-based fibres
- 4.3. Applications of hexagonal nanoferrite fibres
- 4.4. Conclusion
- Chapter 5. Processing of hexagonal ferrite-based nanomaterials for magnetic storage device application
- 5.1. Introduction
- 5.2. Application of hexaferrites in magnetic storage devices
- 5.3. Analysis of magnetic properties of hexaferrites
- 5.4. Fabrication of hexaferrites for magnetic storage devices
- 5.5. Conclusion
- Chapter 6. Magnetoelectric, multiferroic and dielectric characteristics of nanohexaferrites
- 6.1. Introduction
- 6.2. Classification of hexagonal ferrites
- 6.3. Magnetism of hexaferrites
- 6.4. Magnetoelectric and multiferroic properties
- 6.5. Single phase ME and MF hexaferrites
- 6.6. Dielectric properties of hexaferrites
- 6.7. Conclusion
- Chapter 7. Hexagonal nanoferrites: Trends, opportunities and challenges
- 7.1. Introduction
- 7.2. Hexagonal ferrites
- 7.3. Synthesis methods for nanohexaferrites
- 7.4. Structural analysis of hexagonal nanoferrites
- 7.5. Magnetic properties of hexagonal nanoferrites
- 7.6. Applications in different field
- 7.7. Challenges and future directions
- 7.8. Conclusion
- Chapter 8. Nanohexaferrites for permanent magnet and high-density recording media applications
- 8.1. Introduction
- 8.2. Permanent magnets
- 8.3. High-density recording media
- 8.4. Fabrication method for recording media and permanent magnets
- 8.5. Microstructural and magnetic measurements of hexagonal nanohexaferrites for the permanent magnets and high-density recording media
- 8.6. Conclusion
- Chapter 9. Hexagonal nanoferrites for high-frequency applications
- 9.1. Introduction
- 9.2. Types of hexagonal ferrite
- 9.3. Fabrication methods
- 9.4. Electromagnetic properties of hexagonal ferrites
- 9.5. High-frequency applications of hexagonal ferrite
- 9.6. Conclusion
- Chapter 10. Utilization of nanohexaferrites for application in microwave devices
- 10.1. Introduction
- 10.2. Hexaferrite crystal structure
- 10.3. Techniques for the M-type hexaferrite synthesis
- 10.4. Ba-M ferrite
- 10.5. Effect of nanosize
- 10.6. Another microwave absorber
- 10.7. Conclusions
- Chapter 11. Suitability of nanohexaferrites for hyperthermia applications
- 11.1. Introduction
- 11.2. Types of ferrites
- 11.3. Hexaferrites for hyperthermia applications
- 11.4. How to perform hyperthermia study
- 11.5. Mechanism for hyperthermia applications
- 11.6. Dependance on particle size
- 11.7. Hyperthermia treatment using hexaferrites: A new technology
- 11.8. Conclusion
- Chapter 12. Hexagonal nanoferrites in gigahertz electromagnetic wave absorbers for Radar Absorbent Material (RAM) and stealth technologies
- 12.1. Introduction
- 12.2. Synthesis of hexagonal ferrites
- 12.3. Structure
- 12.4. RAM and gigahertz EM wave absorption
- 12.5. Conclusion
- Chapter 13. Suitability of nanohexaferrites for gyromagnetic device applications
- 13.1. Introduction
- 13.2. Brief overview of hexaferrites as a magnetic material
- 13.3. Overview of different types of gyromagnetic devices
- 13.4. Synthesis techniques for nanohexaferrites
- 13.5. Physical characterization techniques for nanohexaferrites (e.g. XRD, SEM, TEM, VSM)
- 13.6. Properties of nanohexaferrites relevant to gyromagnetic devices
- 13.7. Applications of gyromagnetic devices using nanohexaferrites
- 13.8. Conclusion
- Chapter 14. Hexagonal nanoferrites for application in wastewater remediation
- 14.1. Introduction
- 14.2. Chemical synthesis routes of spinel ferrites
- 14.3. Hexagonal ferrites and their properties
- 14.4. Conventional wastewater treatment methods and their limitations
- 14.5. Novel wastewater treatment methods
- 14.6. Future prospects of hexagonal ferrite nanomaterials
- 14.7. Conclusion
- Index
- No. of pages: 300
- Language: English
- Edition: 1
- Published: June 18, 2024
- Imprint: Elsevier
- eBook ISBN: 9780443185571
SK
Susheel Kalia
Susheel Kalia is Associate Professor and Head of the Department of Chemistry, at the Army Cadet College Wing of the Indian Military Academy in Dehradun, India. He was a Postdoc Researcher in 2013 and a Visiting Professor at the University of Bologna, Italy in 2020. Kalia has published over 85 research articles in international journals, as well as co-editing 20 books, authored 11 book chapters, and received more than 8,000 citations over his academic career. His research interests include polymeric bio- and nanocomposites, surface modification, conducting polymers, nanofibers, nanoparticles, nano ferrites, hybrid materials, and hydrogels. Dr. Kalia is Series Editor of a book series on polymer and composite materials, and an editorial board member of the International Journal of Plastics Technology. In addition, he is a member of several professional organizations, including the Asian Polymer Association, Indian Cryogenics Council, the Society for Polymer Science, the Indian Society of Analytical Scientists, and the International Association of Advanced Materials.
Affiliations and expertise
Associate Professor and Head, Department of Chemistry, Army Cadet College Wing of Indian Military Academy Dehradun, IndiaRJ
Rohit Jasrotia
Dr. Rohit Jasrotia received his Ph.D. degree in Materials Science (Physics) from the Shoolini University of Biotechnology and Management Sciences (Top-400 THE University Rankings), Solan, Himachal Pradesh, India.
Presently he is working as Research Fellow and Assistant Professor in the INTI International University, Malaysia and Shoolini University of Biotechnology and Management Sciences, Bajhol, Solan, Himachal Pradesh, India since 2018. He has editored two Elsevier books. He has published over 70 research articles in high-quality international peerreviewed journals, granted 6- Indian patents and 13-book chapters. He is active reviewer of more than 30-reputed internal journals and supervising doctoral and master students in research. He has received best researcher award for his achievements in research and development.
Affiliations and expertise
Research Fellow and Assistant Professor at INTI International University, MalaysiaVP
Virender Pratap Singh
Dr. Virender Pratap Singh is a researcher and emerging physicist from the Materials Research Lab, based in the Department of Physics, Sidharath Govt. Degree College Nadaun, supported by the Department of Higher Education, Government of Himachal Pradesh, in India. His research focuses on the synthesis of various ceramic and superfine materials, magnetic nanomaterials, magnetic nanowires systems, and multiferroics systems. Dr. Pratap Singh has also been involved in various research projects looking at ceramic microstructures and hard nanohexaferrites materials. His research has led to 37 publications in international journals and an international Young Scientist award, and he is an active reviewer for more than 5 journals.
Affiliations and expertise
Assistant Professor of Physics, Department of Physics, Netaji Subhash Chander Bose Memorial Government Degree College, Hamirpur, IndiaRead Nanostructured Hexagonal Ferrites on ScienceDirect