Optical Manipulation of Magnetic Vortex Visualized in situ by 4D Electron Microscopy

TL;DR

This study visualizes and analyzes the complex magnetic vortex dynamics in ferromagnetic disks induced by femtosecond laser quenching, revealing new topological structures and proposing a novel optical control method for spintronic applications.

Contribution

It introduces in situ 4D electron microscopy to observe laser-induced magnetic vortex changes and uncovers previously unseen topological magnetic structures in ferromagnetic disks.

Findings

Observation of complex magnetic structures with vortex and antivortex defects

Identification of topological invariants influencing magnetization dynamics

Proposal of optical-quenching-assisted vortex switching for data storage

Abstract

Understanding the fundamental dynamics of topological vortex and antivortex naturally formed in micro/nanoscale ferromagnetic building blocks under external perturbations is crucial to magnetic vortex based information processing and spintronic devices. All previous studies have focused on magnetic vortex-core switching via external magnetic fields, spin-polarized currents, or spin waves, which have largely prohibited the investigation of novel spin configurations that could emerge from the ground states in ferromagnetic disks and their underlying dynamics. Here, we report in situ visualization of femtosecond laser quenching induced magnetic vortex change in various symmetric ferromagnetic Permalloy disks by Lorentz phase imaging using 4D electron microscopy. Besides the switching of magnetic vortex chirality and polarity, we observed with distinct occurrence frequencies a plenitude of complex magnetic structures that have never been observed by magnetic field or current assisted switching. These complex magnetic structures consist of a number of newly created topological magnetic defects (vortex and antivortex) strictly conserving the topological winding number, demonstrating the direct impact of topological invariant on the magnetization dynamics in ferromagnetic disks. Their spin configurations show mirror or rotation symmetry due to the geometrical confinement of the disks. Combined micromagnetic simulations with the experimental observations reveal the underlying magnetization dynamics and formation mechanism of the optical quenching induced complex magnetic structures. Their distinct occurrence rates are pertinent to their formation-growth energetics and pinning effects at the disk edge. Based on these findings, we propose a paradigm of optical-quenching-assisted fast switching of vortex cores for the control of magnetic vortex based information recording and spintronic devices.