Theoretical studies on the spin-charge dynamics in Kondo-lattice models

TL;DR

This paper reviews theoretical studies on the spin-charge dynamics in Kondo-lattice models, highlighting recent discoveries of topological magnetic phases and nonequilibrium phenomena through large-scale simulations.

Contribution

It introduces new insights into nonequilibrium topological phenomena and excitation dynamics in Kondo-lattice systems, emphasizing recent simulation results.

Findings

Discovery of dynamical magnetic topology switching

Identification of peculiar spin-wave modes in skyrmion crystals

Observation of topological phase phenomena under electromagnetic irradiation

Abstract

The Kondo-lattice model describes a typical spin-charge coupled system in which localized spins and itinerant electrons are strongly coupled via exchange interactions and exhibits a variety of long-wavelength magnetic orders originating from the nesting of Fermi surfaces. Recently, several magnetic materials that realize this model have been discovered experimentally, and they have turned out to exhibit rich topological magnetic phases including skyrmion crystals and hedgehog lattices. Our recent theoretical studies based on the large-scale spin-dynamics simulations have revealed several interesting nonequilibrium phenomena and excitation dynamics in the Kondo-lattice model, e.g., dynamical magnetic topology switching and peculiar spin-wave modes of the skyrmion crystals and the hedgehog lattices under irradiation with electromagnetic waves such as microwaves and light. These achievements are expected to open a new research field to explore novel nonequilibrium topological phenomena and related material functions of the spin-charge coupled magnets.