Discrete Hall resistivity contribution from Néel skyrmions in multilayer nanodiscs

Katharina Zeissler; Simone Finizio; Kowsar Shahbazi; Jamie Massey; Fatma Al Ma’Mari; David M. Bracher; Armin Kleibert; Mark C. Rosamond; Edmund H. Linfield; Thomas A. Moore; Jörg Raabe; Gavin Burnell; Christopher H. Marrows

doi:10.1038/s41565-018-0268-y

Discrete Hall resistivity contribution from Néel skyrmions in multilayer nanodiscs

Katharina Zeissler^*, Simone Finizio, Kowsar Shahbazi, Jamie Massey, Fatma Al Ma’Mari, David M. Bracher, Armin Kleibert, Mark C. Rosamond, Edmund H. Linfield, Thomas A. Moore, Jörg Raabe, Gavin Burnell, Christopher H. Marrows

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

72 Citations (Scopus)

Abstract

Magnetic skyrmions are knot-like quasiparticles. They are candidates for non-volatile data storage in which information is moved between fixed read and write terminals. The read-out operation of skyrmion-based spintronic devices will rely on the electrical detection of a single magnetic skyrmion within a nanostructure. Here we present Pt/Co/Ir nanodiscs that support skyrmions at room temperature. We measured the Hall resistivity and simultaneously imaged the spin texture using magnetic scanning transmission X-ray microscopy. The Hall resistivity is correlated to both the presence and size of the skyrmion. The size-dependent part matches the expected anomalous Hall signal when averaging the magnetization over the entire disc. We observed a resistivity contribution that only depends on the number and sign of skyrmion-like objects present in the disc. Each skyrmion gives rise to 22 ± 2 nΩ cm irrespective of its size. This contribution needs to be considered in all-electrical detection schemes applied to skyrmion-based devices. Not only the area of Néel skyrmions but also their number and sign contribute to their Hall resistivity.

Original language	English
Pages (from-to)	1161-1166
Number of pages	6
Journal	Nature Nanotechnology
Volume	13
Issue number	12
DOIs	https://doi.org/10.1038/s41565-018-0268-y
Publication status	Published - Dec 1 2018
Externally published	Yes

ASJC Scopus subject areas

Bioengineering
Atomic and Molecular Physics, and Optics
Biomedical Engineering
General Materials Science
Condensed Matter Physics
Electrical and Electronic Engineering

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title = "Discrete Hall resistivity contribution from N{\'e}el skyrmions in multilayer nanodiscs",

abstract = "Magnetic skyrmions are knot-like quasiparticles. They are candidates for non-volatile data storage in which information is moved between fixed read and write terminals. The read-out operation of skyrmion-based spintronic devices will rely on the electrical detection of a single magnetic skyrmion within a nanostructure. Here we present Pt/Co/Ir nanodiscs that support skyrmions at room temperature. We measured the Hall resistivity and simultaneously imaged the spin texture using magnetic scanning transmission X-ray microscopy. The Hall resistivity is correlated to both the presence and size of the skyrmion. The size-dependent part matches the expected anomalous Hall signal when averaging the magnetization over the entire disc. We observed a resistivity contribution that only depends on the number and sign of skyrmion-like objects present in the disc. Each skyrmion gives rise to 22 ± 2 nΩ cm irrespective of its size. This contribution needs to be considered in all-electrical detection schemes applied to skyrmion-based devices. Not only the area of N{\'e}el skyrmions but also their number and sign contribute to their Hall resistivity.",

author = "Katharina Zeissler and Simone Finizio and Kowsar Shahbazi and Jamie Massey and Ma{\textquoteright}Mari, {Fatma Al} and Bracher, {David M.} and Armin Kleibert and Rosamond, {Mark C.} and Linfield, {Edmund H.} and Moore, {Thomas A.} and J{\"o}rg Raabe and Gavin Burnell and Marrows, {Christopher H.}",

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T1 - Discrete Hall resistivity contribution from Néel skyrmions in multilayer nanodiscs

AU - Zeissler, Katharina

AU - Finizio, Simone

AU - Shahbazi, Kowsar

AU - Massey, Jamie

AU - Ma’Mari, Fatma Al

AU - Bracher, David M.

AU - Kleibert, Armin

AU - Rosamond, Mark C.

AU - Linfield, Edmund H.

AU - Moore, Thomas A.

AU - Raabe, Jörg

AU - Burnell, Gavin

AU - Marrows, Christopher H.

PY - 2018/12/1

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N2 - Magnetic skyrmions are knot-like quasiparticles. They are candidates for non-volatile data storage in which information is moved between fixed read and write terminals. The read-out operation of skyrmion-based spintronic devices will rely on the electrical detection of a single magnetic skyrmion within a nanostructure. Here we present Pt/Co/Ir nanodiscs that support skyrmions at room temperature. We measured the Hall resistivity and simultaneously imaged the spin texture using magnetic scanning transmission X-ray microscopy. The Hall resistivity is correlated to both the presence and size of the skyrmion. The size-dependent part matches the expected anomalous Hall signal when averaging the magnetization over the entire disc. We observed a resistivity contribution that only depends on the number and sign of skyrmion-like objects present in the disc. Each skyrmion gives rise to 22 ± 2 nΩ cm irrespective of its size. This contribution needs to be considered in all-electrical detection schemes applied to skyrmion-based devices. Not only the area of Néel skyrmions but also their number and sign contribute to their Hall resistivity.

AB - Magnetic skyrmions are knot-like quasiparticles. They are candidates for non-volatile data storage in which information is moved between fixed read and write terminals. The read-out operation of skyrmion-based spintronic devices will rely on the electrical detection of a single magnetic skyrmion within a nanostructure. Here we present Pt/Co/Ir nanodiscs that support skyrmions at room temperature. We measured the Hall resistivity and simultaneously imaged the spin texture using magnetic scanning transmission X-ray microscopy. The Hall resistivity is correlated to both the presence and size of the skyrmion. The size-dependent part matches the expected anomalous Hall signal when averaging the magnetization over the entire disc. We observed a resistivity contribution that only depends on the number and sign of skyrmion-like objects present in the disc. Each skyrmion gives rise to 22 ± 2 nΩ cm irrespective of its size. This contribution needs to be considered in all-electrical detection schemes applied to skyrmion-based devices. Not only the area of Néel skyrmions but also their number and sign contribute to their Hall resistivity.

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Discrete Hall resistivity contribution from Néel skyrmions in multilayer nanodiscs

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