300‐Times‐Increased Diffusive Skyrmion Dynamics and Effective Pinning Reduction by Periodic Field Excitation

300‐Times‐Increased Diffusive Skyrmion Dynamics and Effective Pinning Reduction by Periodic Field Excitation

Thermally induced skyrmion dynamics, as well as skyrmion pinning effects, in thin films have attracted significant interest. While pinning poses challenges in deterministic skyrmion devices and slows down skyrmion diffusion, for applications in non‐conventional computing, both pinning of an appropri...

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Bibliographic Details
Published in:Advanced materials (Weinheim) Vol. 35; no. 17; pp. e2208922 - n/a
Main Authors: Gruber, Raphael, Brems, Maarten A., Rothörl, Jan, Sparmann, Tobias, Schmitt, Maurice, Kononenko, Iryna, Kammerbauer, Fabian, Syskaki, Maria‐Andromachi, Farago, Oded, Virnau, Peter, Kläui, Mathias
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 01-04-2023
Subjects:
Computation
diffusion
Diffusion rate
Dynamics
Excitation
Hypothetical particles
non‐conventional computing
Particle theory
Pinning
Reduction
skyrmions
spintronics
Thin films
skyrmions
pinning
spintronics
diffusion
non-conventional computing
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Summary:Thermally induced skyrmion dynamics, as well as skyrmion pinning effects, in thin films have attracted significant interest. While pinning poses challenges in deterministic skyrmion devices and slows down skyrmion diffusion, for applications in non‐conventional computing, both pinning of an appropriate strength and skyrmion diffusion speed are key. Here, periodic field excitations are employed to realize an increase of the skyrmion diffusion by more than two orders of magnitude. Amplifying the excitation, a drastic reduction of the effective skyrmion pinning, is reported, and a transition from pinning‐dominated diffusive hopping to dynamics approaching free diffusion is observed. By tailoring the field oscillation frequency and amplitude, a continuous tuning of the effective pinning and skyrmion dynamics is demonstrated, which is a key asset and enabler for non‐conventional computing applications. It is found that the periodic excitations additionally allow stabilization of skyrmions at different sizes for field values that are inaccessible in static systems, opening up new approaches to ultrafast skyrmion motion by transiently exciting moving skyrmions. Thermally activated Brownian motion is key for skyrmion devices in non‐conventional computing. A drastic increase in skyrmion diffusion and enhanced skyrmion stability is reported due to periodic magnetic field excitations. Adjusting the strength of the oscillations, the pinning landscape can be tailored continuously and switch from a pinning‐dominated to a free‐like motion regime.
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ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202208922