We found a match
Your institution may have access to this item. Find your institution then sign in to continue.
- Title
Nonvolatile magnetization switching in a single-layer magnetic topological insulator.
- Authors
Sun, Huimin; Liu, Yizhou; Huang, Daiqiang; Fu, Yu; Huang, Yu; He, Mengyun; Luo, Xuming; Song, Wenjie; Liu, Yang; Yu, Guoqiang; He, Qing Lin
- Abstract
Magnetization in a ferromagnetic layer could be manipulated by the spin-orbit torque whose generation commonly relies on the spin-orbit coupling from the adjacent heavy-metal layer within the bilayer. The fact that the magnetic topological insulator possesses both the ferromagnetic order with perpendicular anisotropy and inherent spin-orbit coupling inspires to realize such a torque-induced magnetization switching without forming any heterostructure with other materials. Here, only using a single layer of magnetically-doped topological insulator Cr:(Bi,Sb)2Te3, we realize a magnetization switching only by applying a large dc current. Assisted by the magnetic history, such a switching behaves nonvolatile under zero field but becomes volatile otherwise, as consistently shown by magnetoelectric transports and magneto-optical Kerr effect measurements. Static and quasistatic current are found to be equivalent for the switching. We propose that this switching may associate with the torque resulted from the spin-orbit coupling and the compositional asymmetry in the Cr-profile of the single layer. Topological insulators (TIs), as a powerful reservoir of spin-orbit coupling, became popular to replace the heavy metals in bilayers to achieve magnetization switching with high efficiencies and low threshold current densities. By magnetically doping a single layer TI, the authors observe a zero-field magnetization of the TI that can be switched by dc current.
- Subjects
MAGNETIC insulators; TOPOLOGICAL insulators; MAGNETIC control; KERR magneto-optical effect; SPIN-orbit interactions; MAGNETIZATION
- Publication
Communications Physics, 2023, Vol 6, Issue 1, p1
- ISSN
2399-3650
- Publication type
Article
- DOI
10.1038/s42005-023-01349-z