Ultrafast manipulations of nanoscale skyrmioniums

TL;DR

This paper introduces a universal, high-throughput method for ultrafast manipulation of nanoscale skyrmioniums, enabling rapid switching, new textures, and stable movement, advancing magnetic nanodevice technology.

Contribution

It presents a novel approach for fast control and generation of skyrmioniums using micromagnetic simulations, revealing new textures and mechanisms for magnetic nanostructure manipulation.

Findings

Ultrafast switching between skyrmion and skyrmionium states achieved.

Discovery of new skyrmionic textures like flower-like and windmill-like structures.

Skyrmioniums can move rapidly and stably with weak currents.

Abstract

The advancement of next-generation magnetic devices depends on fast manipulating magnetic microstructures on the nanoscale. A universal method is presented for rapidly and reliably generating, controlling, and driving nano-scale skyrmioniums, through high-throughput micromagnetic simulations. Ultrafast switches are realized between skyrmionium and skyrmion states and rapidly change their polarities in monolayer magnetic nanodiscs by perpendicular magnetic fields. The transition mechanism by alternating magnetic fields differs from that under steady magnetic fields. New skyrmionic textures, such as flower-like and windmill-like skyrmions, are discovered. Moreover, this nanoscale skyrmionium can move rapidly and stably in nanoribbons using weaker spin-polarized currents. Explicit discussions are held regarding the physical mechanisms involved in ultrafast manipulations of skyrmioniums. This work provides further physical insight into the manipulation and applications of topological skyrmionic structures for developing low-power consumption and nanostorage devices.