Weakly pinned skyrmion liquid in a magnetic heterostructure

Rhodri Mansell; Yifan Zhou; Kassius Kohvakka; See Chen Ying; Ken R. Elder; Enzo Granato; Tapio Ala-Nissila; Sebastiaan Van Dijken

doi:10.1103/PhysRevB.106.054413

Weakly pinned skyrmion liquid in a magnetic heterostructure

Rhodri Mansell^*, Yifan Zhou, Kassius Kohvakka, See Chen Ying, Ken R. Elder, Enzo Granato, Tapio Ala-Nissila, Sebastiaan Van Dijken

^*Corresponding author for this work

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Abstract

Magnetic skyrmions are topologically distinct particles whose thermally activated motion could be used to implement probabilistic computing paradigms. While solid-liquid phase transitions in skyrmion lattices have been demonstrated, the behavior of a skyrmion liquid and the effects of pinning are largely unknown. Here we demonstrate the formation of a weakly pinned skyrmion liquid in a magnetic heterostructure. By inserting a Ru wedge layer at the ferromagnet/heavy metal interface we evaluate the dependence of skyrmion dynamics on the skyrmion size and density. Our experiments demonstrate that the diffusion of skyrmions is largest in dense liquids with small skyrmions. The thermal motion of skyrmions at room temperature easily overcomes the narrow distribution of pinning site energies in the granular film structure, satisfying a key requirement of probabilistic device architectures. Micromagnetic simulations support the findings and also reveal the existence of a thermally activated high-frequency collective oscillation.

Original language	English
Article number	054413
Pages (from-to)	1-11
Number of pages	11
Journal	Physical Review B
Volume	106
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevB.106.054413
Publication status	Published - 10 Aug 2022
MoE publication type	A1 Journal article-refereed

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Weakly pinned skyrmion liquid in a magnetic heterostructureFinal published version, 4.83 MB

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title = "Weakly pinned skyrmion liquid in a magnetic heterostructure",

abstract = "Magnetic skyrmions are topologically distinct particles whose thermally activated motion could be used to implement probabilistic computing paradigms. While solid-liquid phase transitions in skyrmion lattices have been demonstrated, the behavior of a skyrmion liquid and the effects of pinning are largely unknown. Here we demonstrate the formation of a weakly pinned skyrmion liquid in a magnetic heterostructure. By inserting a Ru wedge layer at the ferromagnet/heavy metal interface we evaluate the dependence of skyrmion dynamics on the skyrmion size and density. Our experiments demonstrate that the diffusion of skyrmions is largest in dense liquids with small skyrmions. The thermal motion of skyrmions at room temperature easily overcomes the narrow distribution of pinning site energies in the granular film structure, satisfying a key requirement of probabilistic device architectures. Micromagnetic simulations support the findings and also reveal the existence of a thermally activated high-frequency collective oscillation.",

author = "Rhodri Mansell and Yifan Zhou and Kassius Kohvakka and Ying, {See Chen} and Elder, {Ken R.} and Enzo Granato and Tapio Ala-Nissila and {Van Dijken}, Sebastiaan",

note = "Funding Information: This work was supported by the Academy of Finland (Grants No. 295269, No. 306978, and No. 327804). K.R.E. acknowledges funding from the NSF (Grant No. NSF-MPS-2006456). E.G. was supported by Funda{\c c}{\~a}o de Amparo {\`a} Pesquisa do Estado de S{\~a}o Paulo -FAPESP (Grant No. 18/19586-9). T.A.-N. has been supported in part by the Academy of Finland QTF CoE Grant No. 312298. Publisher Copyright: {\textcopyright} 2022 American Physical Society.",

year = "2022",

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doi = "10.1103/PhysRevB.106.054413",

language = "English",

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AU - Mansell, Rhodri

AU - Zhou, Yifan

AU - Kohvakka, Kassius

AU - Ying, See Chen

AU - Elder, Ken R.

AU - Granato, Enzo

AU - Ala-Nissila, Tapio

AU - Van Dijken, Sebastiaan

N1 - Funding Information: This work was supported by the Academy of Finland (Grants No. 295269, No. 306978, and No. 327804). K.R.E. acknowledges funding from the NSF (Grant No. NSF-MPS-2006456). E.G. was supported by Fundação de Amparo à Pesquisa do Estado de São Paulo -FAPESP (Grant No. 18/19586-9). T.A.-N. has been supported in part by the Academy of Finland QTF CoE Grant No. 312298. Publisher Copyright: © 2022 American Physical Society.

PY - 2022/8/10

Y1 - 2022/8/10

N2 - Magnetic skyrmions are topologically distinct particles whose thermally activated motion could be used to implement probabilistic computing paradigms. While solid-liquid phase transitions in skyrmion lattices have been demonstrated, the behavior of a skyrmion liquid and the effects of pinning are largely unknown. Here we demonstrate the formation of a weakly pinned skyrmion liquid in a magnetic heterostructure. By inserting a Ru wedge layer at the ferromagnet/heavy metal interface we evaluate the dependence of skyrmion dynamics on the skyrmion size and density. Our experiments demonstrate that the diffusion of skyrmions is largest in dense liquids with small skyrmions. The thermal motion of skyrmions at room temperature easily overcomes the narrow distribution of pinning site energies in the granular film structure, satisfying a key requirement of probabilistic device architectures. Micromagnetic simulations support the findings and also reveal the existence of a thermally activated high-frequency collective oscillation.

AB - Magnetic skyrmions are topologically distinct particles whose thermally activated motion could be used to implement probabilistic computing paradigms. While solid-liquid phase transitions in skyrmion lattices have been demonstrated, the behavior of a skyrmion liquid and the effects of pinning are largely unknown. Here we demonstrate the formation of a weakly pinned skyrmion liquid in a magnetic heterostructure. By inserting a Ru wedge layer at the ferromagnet/heavy metal interface we evaluate the dependence of skyrmion dynamics on the skyrmion size and density. Our experiments demonstrate that the diffusion of skyrmions is largest in dense liquids with small skyrmions. The thermal motion of skyrmions at room temperature easily overcomes the narrow distribution of pinning site energies in the granular film structure, satisfying a key requirement of probabilistic device architectures. Micromagnetic simulations support the findings and also reveal the existence of a thermally activated high-frequency collective oscillation.

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Weakly pinned skyrmion liquid in a magnetic heterostructure

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Weakly pinned skyrmion liquid in a magnetic heterostructure

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