| Titre : | Compendium on Electromagnetic Analysis : Vol.1 electrostatic and magnetic phenomena : from electrostatics to photonics: fundamentals and applications for physicists and engineers |
| Auteurs : | Michael Donahue, Editeur scientifique |
| Type de document : | document électronique |
| Editeur : | New Jersey : World Scientific, 2020 |
| ISBN/ISSN/EAN : | 978-981-327-026-8 |
| Format : | 1 vol. (XVII-356 p.) / ill. couv. ill. en coul. / 25 cm |
| Note générale : | References. Index |
| Langues: | Français |
| Index. décimale : | 537.2 (Electrostatique) |
| Catégories : |
Ouvrages > Sciences naturelles > Physique (Mécanique - Optique - Magnétisme ...) |
| Mots-clés: | Electromagnetic Analysis |
| Résumé : |
The five-volume set may serve as a comprehensive reference on electromagnetic analysis and its applications at all frequencies, from static fields to optics and photonics. The material includes micro- and nanomagnetics, the new generation of electric machines, renewable energy, hybrid vehicles, low-noise motors; antennas and microwave devices, plasmonics, metamaterials, lasers, and more. Written at a level accessible to both graduate students and engineers, Electromagnetic Analysis is a comprehensive reference, covering methods and applications at all frequencies (from statics to optical). Each volume contains pedagogical/tutorial material of high archival value as well as chapters on state-of-the-art developments. Volume 1 of the Compendium is devoted to electrostatic and magnetic phenomena, which play an important role in many areas of science, technology, and in biological processes. The first chapter of this volume deals with electrostatic interactions between colloidal particles; similar electrostatic effects are critical in many biomolecular processes. The second chapter looks at probing materials with electromagnetic waves to extract key material parameters, which can be used to characterize bulk samples and metamaterials. Chapter 3 explains how, while magnetic resonance imaging (MRI), which is widely used in medicine for diagnoses, has historically required its the results to be qualitatively interpretated by human specialists, this has begun change as accurate models and sophisticated phantoms are bringing about quantitative MRI. The next three chapters are devoted to magnetic devices. Chapter 4 looks at the pinning of magnetic domain walls pertinent for magnetic logic and memory devices. Chapter 5 provides an overview of nanostructured magnetic field sensors used in automotive, aerospace, communication, and medical fields. Chapter 6 details the physics of spin transfer torque and its application to high-speed, non-volatile magnetic random access memory (MRAM). The THz frequency electromagnetic response and properties of canted antiferromagnetic (AFM) materials are studied in Chapter 7. In Chapter 8, modeling helps interpret Brillouin light scattering (BLS) experiments for the investigation of magnetic eigenmodes of nanopatterned magnetic elements. Micromagnetic modeling is also the focus of the final two chapters of this volume. Chapter 9 details the development of a suite of test problems, the μMAG standard problems, used by the global micromagnetic community to verify and improve micromagnetic modeling programs. The final chapter is devoted to the modeling of hard magnetic materials, such as Nd-Fe-B, widely used in powerful permanent magnets for applications such as computer hard disks, audio speakers, headphones, electric motors, and wind turbines. |
| Côte titre : |
F8/12809 |
Exemplaires (1)
| Cote | Support | Localisation | Disponibilité |
|---|---|---|---|
| F8/12809 | Livre | Bibliothèque Fac. de Technologie | Disponible |
Accueil
