Domain wall motion in perpendicular anisotropy nanowires with edge roughness
Domain wall motion in perpendicular anisotropy nanowires with edge roughness
We study field-driven domain wall (DW) motion in nanowires with perpendicular magnetic anisotropy using finite element micromagnetic simulations. Edge roughness is introduced by deforming the finite element mesh, and we vary the correlation length and magnitude of the roughness deformation separately. We observe the Walker breakdown both with and without roughness, with steady DW motion for applied fields below the critical Walker field Hc, and oscillatory motion for larger fields. The value of Hc is not altered in the presence of roughness.
The edge roughness introduces a depinning field. During the transient process of depinning, from the initial configuration to steady DW motion, the DW velocity is significantly reduced in comparison to that for a wire without roughness. The asymptotic DW velocity, on the other hand, is virtually unaffected by the roughness, even though the magnetization reacts to the edge distortions during the entire course of motion, both above and below the Walker breakdown.
A moving DW can become pinned again at some later point ('dynamic pinning'). Dynamic pinning is a stochastic process and is observed both for small fields below Hc and for fields of any strength above Hc. In the latter case, where the DW shows oscillatory motion and the magnetization in the DW rotates in the film plane, pinning can only occur at positions where the DW reverses direction and the instantaneous velocity is zero, i.e., at the beginning or in the middle of a positional oscillation cycle. In our simulations pinning was only observed at the beginnings of cycles, where the magnetization is pointing along the wire.
The depinning field depends linearly on the magnitude of the edge roughness. The strongest pinning fields are observed for roughness correlation lengths that match the domain wall width.
024219-[14pp]
Albert, Maximillian
db290c6a-b107-4f98-8717-2ea4ee459a06
Franchin, Matteo
9e00aaa2-959e-420f-854c-3b43aece85e3
Fischbacher, Thomas
d3282f31-0a6a-4d19-80d0-e3bebc12f67a
Meier, Guido
c31a6de5-6250-4272-bdf8-2a47c4d5010e
Fangohr, Hans
9b7cfab9-d5dc-45dc-947c-2eba5c81a160
18 January 2012
Albert, Maximillian
db290c6a-b107-4f98-8717-2ea4ee459a06
Franchin, Matteo
9e00aaa2-959e-420f-854c-3b43aece85e3
Fischbacher, Thomas
d3282f31-0a6a-4d19-80d0-e3bebc12f67a
Meier, Guido
c31a6de5-6250-4272-bdf8-2a47c4d5010e
Fangohr, Hans
9b7cfab9-d5dc-45dc-947c-2eba5c81a160
Albert, Maximillian, Franchin, Matteo, Fischbacher, Thomas, Meier, Guido and Fangohr, Hans
(2012)
Domain wall motion in perpendicular anisotropy nanowires with edge roughness.
[in special issue: Special issue on domain wall dynamics in nanostructures]
Journal of Physics: Condensed Matter, 24 (2), .
(doi:10.1088/0953-8984/24/2/024219).
Abstract
We study field-driven domain wall (DW) motion in nanowires with perpendicular magnetic anisotropy using finite element micromagnetic simulations. Edge roughness is introduced by deforming the finite element mesh, and we vary the correlation length and magnitude of the roughness deformation separately. We observe the Walker breakdown both with and without roughness, with steady DW motion for applied fields below the critical Walker field Hc, and oscillatory motion for larger fields. The value of Hc is not altered in the presence of roughness.
The edge roughness introduces a depinning field. During the transient process of depinning, from the initial configuration to steady DW motion, the DW velocity is significantly reduced in comparison to that for a wire without roughness. The asymptotic DW velocity, on the other hand, is virtually unaffected by the roughness, even though the magnetization reacts to the edge distortions during the entire course of motion, both above and below the Walker breakdown.
A moving DW can become pinned again at some later point ('dynamic pinning'). Dynamic pinning is a stochastic process and is observed both for small fields below Hc and for fields of any strength above Hc. In the latter case, where the DW shows oscillatory motion and the magnetization in the DW rotates in the film plane, pinning can only occur at positions where the DW reverses direction and the instantaneous velocity is zero, i.e., at the beginning or in the middle of a positional oscillation cycle. In our simulations pinning was only observed at the beginnings of cycles, where the magnetization is pointing along the wire.
The depinning field depends linearly on the magnitude of the edge roughness. The strongest pinning fields are observed for roughness correlation lengths that match the domain wall width.
Text
Albert_etal_JPhysCondMat_2011.pdf
- Accepted Manuscript
More information
Published date: 18 January 2012
Organisations:
Computational Engineering & Design Group
Identifiers
Local EPrints ID: 335910
URI: http://eprints.soton.ac.uk/id/eprint/335910
ISSN: 0953-8984
PURE UUID: 0a0b26bc-09d7-4593-ba84-4b360b0df130
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Date deposited: 14 Mar 2012 11:27
Last modified: 15 Mar 2024 03:03
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Author:
Maximillian Albert
Author:
Matteo Franchin
Author:
Thomas Fischbacher
Author:
Guido Meier
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