Nature Communications (Sep 2023)

Enhanced thermally-activated skyrmion diffusion with tunable effective gyrotropic force

  • Takaaki Dohi,
  • Markus Weißenhofer,
  • Nico Kerber,
  • Fabian Kammerbauer,
  • Yuqing Ge,
  • Klaus Raab,
  • Jakub Zázvorka,
  • Maria-Andromachi Syskaki,
  • Aga Shahee,
  • Moritz Ruhwedel,
  • Tobias Böttcher,
  • Philipp Pirro,
  • Gerhard Jakob,
  • Ulrich Nowak,
  • Mathias Kläui

DOI
https://doi.org/10.1038/s41467-023-40720-0
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 10

Abstract

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Abstract Magnetic skyrmions, topologically-stabilized spin textures that emerge in magnetic systems, have garnered considerable interest due to a variety of electromagnetic responses that are governed by the topology. The topology that creates a microscopic gyrotropic force also causes detrimental effects, such as the skyrmion Hall effect, which is a well-studied phenomenon highlighting the influence of topology on the deterministic dynamics and drift motion. Furthermore, the gyrotropic force is anticipated to have a substantial impact on stochastic diffusive motion; however, the predicted repercussions have yet to be demonstrated, even qualitatively. Here we demonstrate enhanced thermally-activated diffusive motion of skyrmions in a specifically designed synthetic antiferromagnet. Suppressing the effective gyrotropic force by tuning the angular momentum compensation leads to a more than 10 times enhanced diffusion coefficient compared to that of ferromagnetic skyrmions. Consequently, our findings not only demonstrate the gyro-force dependence of the diffusion coefficient but also enable ultimately energy-efficient unconventional stochastic computing.