Magnetic anisotropies in nanostructured matter

One of the Top Selling Physics Books according to YBP Library Services Magnetic Anisotropies in Nanostructured Matter presents a compact summary of all the theoretical means to describe magnetic anisotropies and interlayer exchange coupling in nanosystems. The applications include free and capped magnetic surfaces, magnetic atoms on metallic substrates, nanowires, nanocontacts, and domain walls. Some applications also deal with temperature-dependent effects and ab initio magnetization dynamics. The author clarifies parallel and antiparallel, the distinction between classical spin vectors and spinors, and the actual form of spin-orbit interactions, before showing how symmetry can provide the formal tools to properly define magnetic structures. After these introductory chapters, the book presents methods to describe anisotropic physical properties of magnetic nanostructures. It then focuses on magnetic anisotropy energies, exchange and Dzyaloshinskii-Moriya interactions, temperature-dependent effects, spin dynamics, and related properties of systems nanostructured in one and two dimensions. The book also discusses how methods of describing electric and magneto-optical properties are applied to magnetic nanostructured matter. It concludes with an outlook on emerging magnetic anisotrophic effects. Written by a leading researcher with over 35 years of experience in the field, this book examines the theory and modeling of magnetic anisotropies in nanostructured materials. It shows how these materials are used in a range of applications.

Introduction. Preliminary Considerations. Symmetry Considerations. Green's Functions and Multiple Scattering. The Coherent Potential Approximation. Calculating Magnetic Anisotropy Energies. Exchange and Dzyaloshinskii-Moriya Interactions. The Disordered Local Moment Method (DLM). Spin Dynamics. The Multiple Scattering Scheme. Nanostructured in One Dimension: Free and Capped Magnetic Surfaces. Nanostructured in One Dimension: Spin Valves. Nanostructured in Two Dimensions: Single Atoms, Finite Clusters, and Wires. Nanostructured in Two Dimensions: Nanocontacts, Local Alloys. A Mesoscopic Excursion: Domain Walls. Theory of Electric and Magneto-Optical Properties. Electric Properties of Magnetic Nanostructured Matter. Magneto-Optical Properties of Magnetic Nanostructured Matter. Time Dependence. Afterword. Index.