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Journal Article

Coarse-graining collective skyrmion dynamics in confined geometries

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Fangohr,  H.
Faculty of Engineering and Physical Sciences, University of Southampton;
Computational Science, Scientific Service Units, Max Planck Institute for the Structure and Dynamics of Matter, Max Planck Society;

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022403_1_5.0187446.pdf
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022403_1_5_0187446_suppl_material.zip
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Citation

Winkler, T. B., Rothörl, J., Brems, M. A., Beneke, G., Fangohr, H., & Kläui, M. (2024). Coarse-graining collective skyrmion dynamics in confined geometries. Applied Physics Letters, 124(2): 022403. doi:10.1063/5.0187446.


Cite as: https://hdl.handle.net/21.11116/0000-000C-DD19-0
Abstract
Magnetic skyrmions are magnetic quasi-particles with enhanced stability and different manipulation mechanisms using external fields and currents, making them promising candidates for future applications such as neuromorphic computing. Recently, several measurements and simulations have shown that thermally activated skyrmions in confined geometries, as they are necessary for device applications, arrange themselves predominantly based on commensurability effects. In this simulational study, based on the Thiele model, we investigate the enhanced dynamics and degenerate non-equilibrium steady state of a system in which the intrinsic skyrmion–skyrmion and skyrmion–boundary interaction compete with thermal fluctuations as well as current-induced spin–orbit torques. The investigated system is a triangular-shaped confinement geometry hosting four skyrmions, where we inject spin-polarized currents between two corners of the structure. We coarse grain the skyrmion states in the system to analyze the intricacies of arrangements of the skyrmion ensemble. In the context of neuromorphic computing, such methods address the key challenge of optimizing readout positions in confined geometries and form the basis for understanding collective skyrmion dynamics in systems with competing interactions on different scales. The findings are corroborated by experimental measurements.