Magnetization Dynamics

TL;DR

This review discusses the complex dynamics of magnetization across multiple scales, highlighting recent experimental observations and their implications for understanding magnetic phenomena.

Contribution

It provides an overview of recent advances in magnetization dynamics, connecting macroscopic electromagnetic interactions with microscopic quantum behaviors.

Findings

Observation of spin-torque induced antidamping dynamics

Ultrafast laser-induced femtosecond electron dynamics involving spin currents

New insights into angular momentum conservation in magnetic systems

Abstract

Magnetism primarily describes the physics and materials science of systems presenting a magnetization -- a macroscopic order parameter characterizing electron angular momentum. The order parameter is associated with the electronic exchange interactions, which is fundamentally quantum mechanical. Its dynamic behavior bridges the macroscopic and the microscopic worlds. On macroscopic length and time-scales, it interacts with electromagnetic fields dictated by the Maxwells equations. On a microscopic scale, it involves the quantum-mechanical electronic states both in spin-space and momentum space, thus giving rise to a wide range of behavior that extend down to femtoseconds. Thanks to the development of modern metrology, there have been many new and noteworthy observations of magnetism-related phenomena across the entire range -- from spin-torque induced antidamping dynamics, to ultrafast laser induced femtosecond electron dynamics that involve spin current and angular momentum conservation. In this review we introduce some observations on magnetodynamics, and the scientific subjects these new results give rise to.