Nanomagnetic Materials
Fabrication, Characterization and Application
- 1st Edition - June 28, 2021
- Imprint: Elsevier
- Editors: Akinobu Yamaguchi, Atsufumi Hirohata, Bethanie Stadler
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 2 2 3 4 9 - 9
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 2 2 3 5 4 - 3
Nanomagnetic Materials: Fabrication, Characterization and Application explores recent studies of conventional nanomagnetic materials in spintronics, data storage, magnetic… Read more
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Request a sales quoteNanomagnetic Materials: Fabrication, Characterization and Application explores recent studies of conventional nanomagnetic materials in spintronics, data storage, magnetic sensors and biomedical applications. In addition, the book also reviews novel magnetic characteristics induced in two-dimensional materials, diamonds, and those induced by the artificial formation of lattice defect and heterojunction as novel nanomagnetic materials. Nanomagnetic materials are usually based on d- and f-electron systems. They are an important solution to the demand for higher density of information storage, arising from the emergence of novel technologies required for non-volatile memory systems.
Advances in the understanding of magnetization dynamics and in the characteristics of nanoparticles or surface of nanomagnetic materials is resulting in greater expansion of applications of nanomagnetic materials, including in biotechnology, sensor devices, energy harvesting, and power generating systems. This book provides a cogent overview of the latest research on novel nanomagnetic materials, including spintronic nanomagnets, molecular nanomagnets, self-assembling magnetic nanomaterials, nanoparticles, multifunctional materials, and heterojunction-induced novel magnetism.
- Explains manufacturing principles and process for nanomagnetic materials
- Discusses physical and chemical properties and potential industrial applications, such as magnetic data storage, sensors, oscillator, permanent magnets, power generations, and biomedical applications
- Assesses the major challenges of using magnetic nanomaterials on a broad scale
Materials Scientists and Engineers
- Cover image
- Title page
- Table of Contents
- Copyright
- List of contributors
- Preface
- Chapter 1: Nano/micro-structured magnetism
- Abstract
- Subchapter 1.1. Fabrication of nano- and micro-structured materials
- Subchapter 1.2. Applications to nano- and micro-systems
- Subchapter 1.3. Fundamental properties
- Subchapter 1.4. Introduction of synthesis and processing
- Subchapter 1.5. Structural and electromagnetic characterization
- Chapter 2: Synthesis and processing
- Abstract
- Subchapter 2.1. Overview
- Subchapter 2.2. Multilayers
- Subchapter 2.3. Nano/micro-fabrication and control of magnetic domain structures
- Subchapter 2.4. Oxides: fabrication techniques of magnetic oxide thin films and nanoparticles
- Subchapter 2.5. Nanoparticles
- Subchapter 2.6. Encapsulated nanoparticles
- Subchapter 2.7. Radiolysis and modification
- Chapter 3: Atomic/nanoscale characterization
- Abstract
- Subchapter 3.1. Imaging tools for nanomagnetism
- Subchapter 3.2. Static and dynamic imaging by magneto-optical Kerr microscopy
- Subchapter 3.3. Nuclear magnetic resonance in nanomagnetic systems
- Subchapter 3.4. Ferromagnetic resonance and electron spin resonance
- Subchapter 3.5. Summary
- Chapter 4: X-ray techniques to characterize nanomagnetism
- Abstract
- Subchapter 4.1. Introduction
- Subchapter 4.2. Generation of X-rays at large scale facilities
- Subchapter 4.3. X-ray absorption spectroscopy
- Subchapter 4.4. X-ray magnetic circular dichroism
- Subchapter 4.5. X-ray magnetic linear dichroism
- Subchapter 4.6. Imaging nanomagnetic structures and their dynamics with polarized X-rays
- Subchapter 4.7. Scanning X-ray fluorescence analysis
- Subchapter 4.8. Summary and conclusions
- Chapter 5: Spintronics
- Abstract
- Subchapter 5.1. Overview
- Subchapter 5.2. Spin dynamics
- Subchapter 5.3. Spin texture and topological structure
- Subchapter 5.4. Spin current
- Subchapter 5.5. Spin-transfer torque and related phenomena
- Subchapter 5.6. Spin Hall and related effects
- Subchapter 5.7. Spin orbital effect
- Subchapter 5.8. Recent development of magnonics
- Subchapter 5.9. Spin caloritronics
- Subchapter 5.10. Magnetic point contact
- Chapter 6: Promising prospects of novel magnetism
- Abstract
- Subchapter 6.1. Magnetic nanowire-based nanobarcodes
- Subchapter 6.2. Magnetism associated with SAW devices
- Subchapter 6.3. Heterojunctions
- Chapter 7: Computer and network applications
- Abstract
- Subchapter 7.1. Spintronic devices for computer and network applications
- Subchapter 7.2. Hard disk drives
- Subchapter 7.3. Magnetic random access memory
- Subchapter 7.4. Spin-dice: random number generator using stochastic switching of nanomagnets
- Subchapter 7.5. Spin torque oscillator
- Subchapter 7.6. Non-reciprocal metamaterials based on magnetism
- Subchapter 7.7. Stochastic skyrmion dynamics and applications to non-conventional logic
- Chapter 8: Sensor and system
- Abstract
- Subchapter 8.1. Introduction and overview
- Subchapter 8.2. Magnetic tunnel junction-based sensors for biomagnetic applications
- Subchapter 8.3. Diamond quantum sensors based on NV centers
- Subchapter 8.4. Microelectromechanical systems
- Chapter 9: Systems and application biopsy
- Abstract
- Subchapter 9.1. Magnetic biosensors
- Subchapter 9.2. Concepts for clinical applications
- Subchapter 9.3. Cytometric systems
- Subchapter 9.4. Lab-on-a-chip and lab-on-a-CD
- Subchapter 9.5. Sentinel lymph node mapping and biopsy
- Subchapter 9.6. Surgical magnetic sensors
- Subchapter 9.7. Magnetic fluid hyperthermia; a guide for design of thermal seeds within the limits of conventional theory
- Chapter 10: Energy harvesting and generation system
- Abstract
- Subchapter 10.1. Overview
- Subchapter 10.2. Magnetic energy harvesting
- Subchapter 10.3. Energy harvesting – microelectromechanical systems
- Subchapter 10.4. Power generation by the magnetoelastic effect
- Subchapter 10.5. Magnetic nanostructures for energy harvesting using magnetothermoelectric effects
- Index
- Edition: 1
- Published: June 28, 2021
- No. of pages (Paperback): 812
- No. of pages (eBook): 812
- Imprint: Elsevier
- Language: English
- Paperback ISBN: 9780128223499
- eBook ISBN: 9780128223543
AY
Akinobu Yamaguchi
Akinobu Yamaguchi is Associate Professor, Laboratory of Advanced Science and Technology for Industry, University of Hyogo, Japan. His research focuses on the fabrication of of artificial materials with modulated and/or periodic magnetic structure composed of nanoscale magnets, which are intentionally added topologic designs.
Affiliations and expertise
Associate Professor, Laboratory of Advanced Science and Technology for Industry, University of Hyogo, JapanAH
Atsufumi Hirohata
Atsufumi Hirohata is a Professor in Nanoelectronics at the University of York, United Kingdom. His area of research covers spintronics and quantum nanoelectronics, with recent focus on the fabrication of a spin operator and nano-spin motor as well as growth of a half-metallic film.
Affiliations and expertise
Professor, Department of Electronic Engineering, University of York, UKBS
Bethanie Stadler
Bethanie Stadler is Professor, Electrical and Computer Engineering at the University of Minnesota, USA. Her research lies in the areas of nanomagnetic and photonic materials and devices
Affiliations and expertise
Professor, Electrical and Computer Engineering, University of Minnesota, USARead Nanomagnetic Materials on ScienceDirect