“Electronic Structure and Magnetism of 3d Transition Metal Pnictides” by Motizuki, Ido, Itoh, and Morifuji provides a comprehensive analysis of the electronic structure and magnetic properties of 3d transition metal pnictides, a class of compounds comprising elements from group 15 of the periodic table (nitrogen, phosphorus, arsenic, antimony, and bismuth) combined with transition metals. Here’s a summary:
The book begins by introducing readers to the fundamental concepts of electronic structure and magnetism, laying the groundwork for understanding the behavior of 3d transition metal pnictides. Motizuki, Ido, Itoh, and Morifuji cover topics such as band theory, electronic band structures, and magnetic ordering phenomena, providing readers with a solid foundation in the theoretical framework underlying the electronic and magnetic properties of materials.
Readers are then guided through a detailed examination of the electronic structure of 3d transition metal pnictides, including their crystal structures, electronic band dispersions, and Fermi surface topologies. Motizuki et al. elucidate how the interplay between the electronic states of transition metal ions and pnictide ligands gives rise to diverse electronic and magnetic behaviors, such as metallicity, superconductivity, and magnetic ordering.
A significant portion of the book is dedicated to exploring the magnetic properties of 3d transition metal pnictides, including their magnetic structures, magnetic phase transitions, and magnetic excitations. Motizuki et al. discuss experimental techniques for probing magnetic properties, such as neutron scattering, magnetic susceptibility measurements, and magnetization studies, providing insights into the experimental methods used to investigate the magnetic behavior of these materials.
Furthermore, the book addresses theoretical modeling and computational approaches for studying the electronic structure and magnetism of 3d transition metal pnictides. Motizuki et al. discuss density functional theory (DFT) calculations, dynamical mean-field theory (DMFT) simulations, and other theoretical methods used to elucidate the electronic and magnetic properties of these materials, highlighting the synergistic relationship between theory and experiment in advancing our understanding of complex materials.
Throughout the text, Motizuki, Ido, Itoh, and Morifuji emphasize the interdisciplinary nature of research in electronic structure and magnetism, highlighting the contributions of both experimental and theoretical approaches to unraveling the mysteries of 3d transition metal pnictides. The book also includes discussions on the potential technological applications of these materials, such as spintronics, magnetic storage, and quantum computing, underscoring their importance in advancing next-generation electronic and magnetic devices.
With its comprehensive coverage, theoretical insights, and experimental methodologies, “Electronic Structure and Magnetism of 3d Transition Metal Pnictides” serves as an invaluable resource for researchers, graduate students, and professionals working in the fields of condensed matter physics, materials science, and solid-state chemistry. Whether used as a reference for academic study or as a guide for experimental and theoretical research, this book provides a comprehensive overview of the electronic structure and magnetism of 3d transition metal pnictides.