Abstract
The real-time dynamics of a classical spin in an external magnetic field and local exchange coupled to an extended one-dimensional system of non-interacting conduction electrons is studied numerically. Retardation effects in the coupled electron-spin dynamics are shown to be the source for the relaxation of the spin in the magnetic field. Total energy and spin is conserved in the non-adiabatic process. Approaching the new local ground state is therefore accompanied by the emission of dispersive wave packets of excitations carrying energy and spin and propagating through the lattice with Fermi velocity. While the spin dynamics in the regime of strong exchange coupling J is rather complex and governed by an emergent new time scale, the motion of the spin for weak J is regular and qualitatively well described by the Landau–Lifschitz–Gilbert (LLG) equation. Quantitatively, however, the full quantum–classical hybrid dynamics differs from the LLG approach. This is understood as a breakdown of weak-coupling perturbation theory in J in the course of time. Furthermore, it is shown that the concept of the Gilbert damping parameter is ill-defined for the case of a one-dimensional system.
Highlights
The Landau-Lifshitz-Gilbert (LLG) equation[1,2,3] has originally been considered to describe the dynamics of the magnetization of a macroscopic sample
Hybrid systems consisting of classical spins coupled to a bath of non-interacting conduction electrons represent a class of model systems with a non-trivial realtime dynamics which is numerically accessible on long time scales
We have considered the simplest variant of this class, the Kondo-impurity model with a classical spin, and studied the relaxation dynamics of the spin in an external magnetic field
Summary
The Landau-Lifshitz-Gilbert (LLG) equation[1,2,3] has originally been considered to describe the dynamics of the magnetization of a macroscopic sample. An advantage of a full theory of spin and electron dynamics is that a precise microscopic picture of the electron dynamics is available and can be used to discuss the precession and relaxation dynamics of the spin from another, namely from the electronic perspective This information is in principle experimentally accessible to spin-resolved scanning-tunnelling microscope techniques[33,34,35,36] and important for an atomistic understanding of nano-spintronics devices.[37,38] We are interested in the physics of the system in the strong-J regime or for a strong field B where the time scales of the spin and the electron dynamics become comparable.
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