Spin Ice, 1st ed. 2021
Springer Series in Solid-State Sciences Series, Vol. 197

This book deals with a new class of magnetic materials, spin ice. Spin ice has become the canonical example of modern frustrated magnetism where competing interactions between spins set the rules for an emergent magnetostatic gauge field theory. Excitations take the form of magnetic monopoles or can condense via a Higgs mechanism. Beyond classical spin ice, the book describes the new physics emerging when quantum coherence (spin liquids, photon-like excitations) and itinerant electrons (anomalous Hall effect) are included in artificial systems. This first book dedicated to spin ice is a review of the current understanding of the field, both on the theoretical and experimental levels, written by leading experts. The book is written in a linear way with very few prerequisites. It also contains textbook-like descriptions of theoretical methods to help advanced students and researchers to enter the field.

Preface.- Spin Ice. Single-Ion Physics: A Material Perspective.- Emergent Gauge Field in Pyrochlores.- How to Measure Monopoles?.- Dynamics.- Topological Phases.- Theoretical Methods.- Beyond Classical Spin Ice.- Quantum Coherence.- Novel Electronic Phases of Matter: Coupling to Itinerant Electrons.- Beyond Pyrochlores.- Artificial Spin Ice.- Perspectives, The Future.

Masafumi Udagawa is a professor of Gakushuin University in Tokyo. He started his scientific career at the physics department of Tokyo University. He then moved to the applied physics department of Tokyo University as an assistant professor and worked on strongly correlated electron systems. In 2011, he stayed in Max Planck Institute for the Physics of Complex Systems and worked in the intersection of frustrated magnetism and correlated electron systems. In 2015, he received Young Scientist Award of the Physical Society of Japan and in the same year, he obtained a tenured position in Gakushuin University. His main interest is the fractional excitations of quantum spin liquid phase in frustrated magnetic systems. He applies the technique of electron systems to clarify their mystic character.