Spin-Wave Spectrum in Magnetic Nanodot with Continuous Transition between Vortex, Bloch-type Skyrmion and N\'eel-type Skyrmion States

TL;DR

This paper investigates how spin-wave excitations evolve in a ferromagnetic nanodot as it transitions between vortex, Bloch-type skyrmion, and Ne9el-type skyrmion states, revealing the dynamic spectrum's complexity.

Contribution

It demonstrates continuous phase transitions between different magnetic states and maps the associated spin excitation modes, advancing understanding of spin dynamics in topologically non-trivial nanostructures.

Findings

Continuous phase transitions between magnetic states identified.

Mapping of spin-wave modes across different configurations.

Insights into the connection between various spin excitations.

Abstract

We study spin-wave excitations in a circular ferromagnetic nanodot in different inhomogeneous, topologically non-trivial magnetization states, specifically, vortex and skyrmion states. Gradual change in the strength of the out-of-plane magnetic anisotropy and the Dzyaloshinskii-Moriya exchange interaction leads to continuous phase transitions between different stable magnetic configurations and allows for mapping of dynamic spin modes in and between the vortex, Bloch-type skyrmion and N\'eel-type skyrmion states. Our study elucidates the connections between gyrotropic modes, azimuthal spin waves and breathing modes in various stable magnetization states and helps to understand the rich spin excitation spectrum on the skyrmion background.