Magnetic Nanostructured Materials: From Lab to Fab presents a complete overview of the translation of nanostructured materials into realistic applications, drawing on the most recent research in the field to discuss the fundamentals, synthesis and characterization of nanomagnetics. A wide spectrum of nanomagnetic applications is included, covering industrial, environmental and biomedical fields, and using chemical, physical and biological methods. Materials such as Fe, Co, CoxC, MnGa, GdSi, ferrite nanoparticles and thin films are highlighted, with their potential applications discussed, such as magnetic refrigeration, energy harvesting, magnetic sensors, hyperthermia, MRI, drug delivery, permanent magnets, and data storage devices.
Offering interdisciplinary knowledge on the materials science of nanostructured materials and magnetics, this book will be of interest to researchers in materials science, engineering, physics and chemistry with interest in magnetic nanomaterials, as well as postgraduate students and professionals in industry and government.
- Provides interdisciplinary knowledge on the materials science of nanostructured materials and magnetics
- Aids in the understanding of complex fundamentals and synthesis methods for magnetic nanomaterials
- Includes examples of real applications
- Shows how laboratory work on magnetic nanoparticles connects to industrial implementation and applications
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1. Magnetic nanoparticles, synthesis, properties and applications 2. Core/Shell Magnetic Nanoparticles for Biomedical Applications 3. Multifunctional Ferrite Nanoparticles: From Current Trends Towards the Future 4. Gd Based Magnetic Nanoparticles for Biomedical Applications 5. Recent developments in permanent magnetic nanostructured materials and their processing methods 6. Nanomagnets for rare earth free permanent magnets 7. Magnetoelectric coupling in Ferromagnetic Manganite/ferroelectric PZT hetrostructure 8. Magnetic nanoparticles-Piezoelectric Polymer Nanocomposites for the Enhancement of Energy Density of Energy Harvesting Polymers 9. Magnetocaloric effect of Microstructured Materials for Magnetic Refrigeration 10. Large Magnetocaloric Effect in Microstructured Rare earth Manganese Aluminum Compounds 11. Rare-Earth Magnetocaloric Thin Films 12. Magnetically doped topological insulators thin films 13. Structural and Magnetic properties of Ni nanoferrites doped with rare earth and transition metals 14. Microbial Fabrication of Magnetic Nanoparticles and their Applications 15. Summary, Conclusion and Future Outlook
Dr. EL-Gendy received his Ph.D. degree in physics from Heidelberg University, Germany 2011. From 2012-2017, He worked in various research positions on both levels academic and industry, as a postdoctoral researcher and senior scientist at Virginia Commonwealth University (VCU), Virginia (2012-2013, 2015-2017), Nanofoundary LLC., and University of Delaware (UD), Delaware (2013-2015), USA. In fall 2017, he joined department of physics at UTEP as tenure track assistant professor to establish his group in nanomagnetics and biomaterials. Dr. El-Gendy has been working in the field of magnetic nanoparticles for 16 years. His research expertise includes synthesis, characterization and applications of functionalized magnetic nanoparticles. He focuses on synthesis and optimization of soft and hard magnetic nanomaterials using chemical and physical methods to be used for various types of applications such as hyperthermia treatment for cancer, drug delivery, contrast agent for MRI, rare-earth free permanent magnets, data storage, and magneto-caloric for refrigeration technology. He has published more than 40 (11 in 2017) high impact scientific papers in peer-review journals and book chapters. He is a reviewer for numerous high ranked scientific journals. He is editing a book of magnetic nanostructured materials published by ELSEVIER in 2018-2019. He is Editor of Journal of Research in Pharmaceutics and Drug Development. He has participated in more than 20 international conferences and been invited for many talks. During 2015-2016, scientific newspapers such as phys.org, nanowerk, AAAS, science daily, Azo nano, I'Science, Space daily DOE-news,etc. highlighted his work on novel rare-earth free permanent magnet material. In addition, he holds one US-patent (US2016/0159653A1) and five US-provisional patents (US 62/546, 810), (US 62/278, 228), (US 62/278, 176), (US 62/278, 169), and (US 62/278, 164). In 2017, he has been awarded a highly competitive international young scientist award by national science foundation in China (NSFC). Based on his career achievements, his biography was approved to be listed in Marques who's who in America in 2018.
Barandiaran, Jose Manuel
Prof. José Manuel Barandiaran is an internationally recognized expert in the field of magnetism and magnetic materials. He was deeply involved in the development of the theory and experimental application of magnetoelastic effects in amorphous materials during the 80's, and has thereafter continued researching their properties and use in different kind of sensors. As head of the Group of Magnetism and Magnetic Materials, he started and led the research in Magnetism in the Universidad del País Vasco UPV/EHU. He is currently the scientific director of BCMaterials, an excellence research centre sponsored by the Basque Science Foundation and the University. He has published over 400 articles in scientific journals, receiving more than 4700 citations (h-index=34). He is author of 5 patents, and has supervised 14 PhD Thesis. He was the founder and first president of International Committee of the European Magnetic Sensors & Actuators (EMSA) Conferences, Chairman of International Committee of the Soft Magnetic Materials (SMM) Conference, and founder and first President of the Spanish Club of Magnetism.
Hadimani, Ravi L.
Ravi L. Hadimani is Assistant Professor in the Department of Mechanical and Nuclear Engineering, Virginia Commonwealth University, Richmond, VA, USA. His research specializations are non-invasive brain stimulation, biomagnetics and energy harvesting research. He developed a hybrid piezoelectric and photovoltaic energy harvester to produce electrical energy from solar, wind and rain energy, for which he was awarded the UK Energy Innovation Award in 2011.