Current-driven skyrmionium in a frustrated magnetic system

Jing Xia, Xichao Zhang, Motohiko Ezawa, Oleg A. Tretiakov, Zhipeng Hou, Wenhong Wang, Guoping Zhao, Xiaoxi Liu, Hung T. Diep, Yan Zhou

Published 2020-05-04Version 1

Magnetic skyrmionium is a skyrmion-like topological spin texture that is formed by two concentric circular domain walls. It can be used as a nanometer-scale non-volatile information carrier, which shows no skyrmion Hall effect due to its special internal structure. Here, we report the static and dynamic properties of an isolated nanoscale skyrmionium in a frustrated magnetic monolayer, where the skyrmionium is stabilized by competing interactions. The nanoscale skyrmionium has a size of $\sim 10$ nm, which can be further reduced by tuning perpendicular magnetic anisotropy or magnetic field. It is also found that the nanoscale skyrmionium driven by the damping-like spin-orbit torque shows directional motion with a favored Bloch-type helicity. A small driving current can lead to the transformation of an unstable N\'eel-type skyrmionium to a metastable Bloch-type skyrmionium. A large driving current may result in the distortion and collapse of the Bloch-type skyrmionium. Our results are not only useful for the understanding of skyrmionium dynamics in frustrated magnets, but also to provide guidelines for the design of future spintronic devices based on topological spin textures.