Scientists experimentally observe current-driven antiskyrmion sliding

Editors' notes This article has been reviewed according to Science X's editorial process and policies. Editors have highlighted the following attributes while ensuring the content's credibility: fact-checked peer-reviewed publication trusted source proofread by Chen Na, Chinese Academy of Sciences Mechanism of antiskyrmion sliding along stripe domains in comparison with ferromagnetic background. Credit: Institute of Physics Prof.

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Editors’ notes

This article has been reviewed according to Science X’s
editorial process
and policies.
Editors have highlighted
the following attributes while ensuring the content’s credibility:

fact-checked

peer-reviewed publication

trusted source

proofread

by Chen Na, Chinese Academy of Sciences

Mechanism of antiskyrmion sliding along stripe domains in comparison with ferromagnetic background. Credit: Institute of Physics

Prof. Zhang Ying’s group from the Institute of Physics of the Chinese Academy of Sciences (CAS), in collaboration with domestic universities and the Los Alamos National Laboratory in the United States, has experimentally observed current-driven antiskyrmion sliding.

Their work was published in Nature Materials on April 11.

Magnetic (anti)skyrmions with topologically protected spin structures are promising as next-generation information units in spintronic devices. The ability to transport (anti)skyrmions using is particularly interesting for highly efficient data storage and processing. However, the major challenges are unwanted lateral deflection toward the sample edge and eventual annihilation due to the Magnus force from (anti) Hall effects.

Under the consistent support of CAS Member Shen Baogen, Prof. Zhang’s research team established a dedicated magnetization characterization platform with focused ion beam microscopy, Lorentz Transmission Electron Microscopy (L-TEM), and multiple in-situ holders, etc.

The platform is a powerful means of directly studying topological domains with ultra-high spatial resolution under different external fields. The researchers have used this platform to systematically study the generation and manipulation of skyrmions in many kinds of materials, thus accumulating rich experience.

Realization of room-temperature antiskyrmions with different magnetization states and their straight current-driven behaviour along the naturally helical stripes at zero field. Credit: Institute of Physics

In this study, the researchers successfully demonstrated the straight-sliding dynamics of electric current-driven antiskyrmions at room temperature and without the presence of an external in a Mn1.4PtSn chiral magnet.

This achievement was realized by embedding antiskyrmions in strongly correlated helical stripe domains, in contrast to the usual manipulation of topological skyrmions in the ferromagnetic background. These stripe domains naturally provide one-dimensional linear tracks, along which antiskyrmion sliding is initiated at low current densities and without transverse deflection by the antiskyrmion Hall effect.

According to the researchers, the higher mobility of the antiskyrmions in the helical stripe background can be well understood through micromagnetic simulations and collective pinning theory, allowing random pinning potentials to be easily faded out.

In addition, this method can be extended to the sliding motion of merons or skyrmions in stripe domains, further demonstrating its general applicability.

Thus, the demonstration and comprehensive understanding of antiskyrmion movement along naturally straight tracks at low current densities, while overcoming deflection under a wide temperature range and zero magnetic field, offers a new perspective for (anti)skyrmion applications in spintronics.

More information:
Zhidong He et al, Experimental observation of current-driven antiskyrmion sliding in stripe domains, Nature Materials (2024). DOI: 10.1038/s41563-024-01870-8

Citation:
Scientists experimentally observe current-driven antiskyrmion sliding (2024, April 18)
retrieved 18 April 2024
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