Survival of skyrmions along granular racetracks at room temperature

Josep Castell-Queralt; Guillermo Abad-López; Leonardo González-Gómez; Nuria Del-Valle; Carles Navau Ros

doi:10.1039/d3na00464c

Survival of skyrmions along granular racetracks at room temperature

Josep Castell-Queralt, Guillermo Abad-López, Leonardo González-Gómez, Nuria Del-Valle, Carles Navau Ros

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

Abstract

Skyrmions can be envisioned as bits of information that can be transported along nanoracetracks. However, temperature, defects, and/or granularity can produce diffusion, pinning, and, in general, modification in their dynamics. These effects may cause undesired errors in information transport. We present simulations of a realistic system where both the (room) temperature and sample granularity are taken into account. Key feasibility magnitudes, such as the success probability of a skyrmion traveling a given distance along the racetrack, are calculated. The results are evaluated in terms of the eventual loss of skyrmions by pinning, destruction at the edges, or excessive delay due to granularity. The model proposed is based on the Fokker-Planck equation resulting from Thiele's rigid model for skyrmions. The results could serve to establish error detection criteria and, in general, to discern the dynamics of skyrmions in realistic situations.

Original language	English
Pages (from-to)	4728-4734
Number of pages	7
Journal	Nanoscale Advances
Volume	5
Issue number	18
DOIs	https://doi.org/10.1039/d3na00464c
Publication status	Published - 28 Jul 2023

Keywords

Magnetic skyrmions
Motion

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10.1039/d3na00464c

https://ddd.uab.cat/record/283502

Cite this

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title = "Survival of skyrmions along granular racetracks at room temperature",

abstract = "Skyrmions can be envisioned as bits of information that can be transported along nanoracetracks. However, temperature, defects, and/or granularity can produce diffusion, pinning, and, in general, modification in their dynamics. These effects may cause undesired errors in information transport. We present simulations of a realistic system where both the (room) temperature and sample granularity are taken into account. Key feasibility magnitudes, such as the success probability of a skyrmion traveling a given distance along the racetrack, are calculated. The results are evaluated in terms of the eventual loss of skyrmions by pinning, destruction at the edges, or excessive delay due to granularity. The model proposed is based on the Fokker-Planck equation resulting from Thiele's rigid model for skyrmions. The results could serve to establish error detection criteria and, in general, to discern the dynamics of skyrmions in realistic situations.",

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T1 - Survival of skyrmions along granular racetracks at room temperature

AU - Castell-Queralt, Josep

AU - Abad-López, Guillermo

AU - González-Gómez, Leonardo

AU - Del-Valle, Nuria

AU - Navau Ros, Carles

PY - 2023/7/28

Y1 - 2023/7/28

N2 - Skyrmions can be envisioned as bits of information that can be transported along nanoracetracks. However, temperature, defects, and/or granularity can produce diffusion, pinning, and, in general, modification in their dynamics. These effects may cause undesired errors in information transport. We present simulations of a realistic system where both the (room) temperature and sample granularity are taken into account. Key feasibility magnitudes, such as the success probability of a skyrmion traveling a given distance along the racetrack, are calculated. The results are evaluated in terms of the eventual loss of skyrmions by pinning, destruction at the edges, or excessive delay due to granularity. The model proposed is based on the Fokker-Planck equation resulting from Thiele's rigid model for skyrmions. The results could serve to establish error detection criteria and, in general, to discern the dynamics of skyrmions in realistic situations.

AB - Skyrmions can be envisioned as bits of information that can be transported along nanoracetracks. However, temperature, defects, and/or granularity can produce diffusion, pinning, and, in general, modification in their dynamics. These effects may cause undesired errors in information transport. We present simulations of a realistic system where both the (room) temperature and sample granularity are taken into account. Key feasibility magnitudes, such as the success probability of a skyrmion traveling a given distance along the racetrack, are calculated. The results are evaluated in terms of the eventual loss of skyrmions by pinning, destruction at the edges, or excessive delay due to granularity. The model proposed is based on the Fokker-Planck equation resulting from Thiele's rigid model for skyrmions. The results could serve to establish error detection criteria and, in general, to discern the dynamics of skyrmions in realistic situations.

KW - Magnetic skyrmions

KW - Motion

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ER -

Survival of skyrmions along granular racetracks at room temperature

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Keywords

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