Effect of rounded corners on the magnetic properties of pyramidal-shaped shell structures
Effect of rounded corners on the magnetic properties of pyramidal-shaped shell structures
In recent years, the advance of novel chemical growth techniques has led to the fabrication of complex, three-dimensional magnetic nanostructures. The corners and edges of such realistic geometries are generally not sharp but rounded. In a previous article we have argued that high demagnetization fields in the vicinity of sharp edges lead to the formation of an asymmetric vortex state in pyramidal-shaped magnetic shell structures. The asymmetric vortex state is potentially interesting with respect to future magnetic memory devices. In this work a micromagnetic model is used to investigate the effect of rounded corners and edges on the magnetic reversal process within these pyramidal-shaped magnetic shell structures. In particular, we explore the degree of rounding, which has to be introduced in order to suppress the asymmetric vortex state. Another emphasis is placed on the magnetic reversal of (quasi-)homogeneous states within these structures. We demonstrate that the rounding of corners significantly reduces the coercivity. This complies with former studies on cuboidal structures, which suggest the important effect of corners on the magnetic reversal of homogeneous magnetic states. The present study uses a finite-element discretization for the numerical solution of the micromagnetic equations, which provides flexibility with respect to the modeling of complex shapes. In particular, this method is very accurate with respect to structures with a smooth surface.
coercive force, finite element analysis, magnetic structure, magnetisation reversal, micromagnetics, nanomagnetics, nanostructured materials, surface structure, vortices
07D127-[3pp]
Knittel, Andreas
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Franchin, Matteo
9e00aaa2-959e-420f-854c-3b43aece85e3
Nasirpouri, Farzad
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Bending, Simon J.
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Fangohr, Hans
9b7cfab9-d5dc-45dc-947c-2eba5c81a160
12 March 2012
Knittel, Andreas
f2336826-cc4d-4362-a241-1bf90c4941d4
Franchin, Matteo
9e00aaa2-959e-420f-854c-3b43aece85e3
Nasirpouri, Farzad
08af2ad8-05ad-49ad-aa49-bd9d1d0f84c0
Bending, Simon J.
918588c0-4117-4be6-9853-abc52ca9ffc4
Fangohr, Hans
9b7cfab9-d5dc-45dc-947c-2eba5c81a160
Knittel, Andreas, Franchin, Matteo, Nasirpouri, Farzad, Bending, Simon J. and Fangohr, Hans
(2012)
Effect of rounded corners on the magnetic properties of pyramidal-shaped shell structures.
Journal of Applied Physics, 111 (7), .
(doi:10.1063/1.3679073).
Abstract
In recent years, the advance of novel chemical growth techniques has led to the fabrication of complex, three-dimensional magnetic nanostructures. The corners and edges of such realistic geometries are generally not sharp but rounded. In a previous article we have argued that high demagnetization fields in the vicinity of sharp edges lead to the formation of an asymmetric vortex state in pyramidal-shaped magnetic shell structures. The asymmetric vortex state is potentially interesting with respect to future magnetic memory devices. In this work a micromagnetic model is used to investigate the effect of rounded corners and edges on the magnetic reversal process within these pyramidal-shaped magnetic shell structures. In particular, we explore the degree of rounding, which has to be introduced in order to suppress the asymmetric vortex state. Another emphasis is placed on the magnetic reversal of (quasi-)homogeneous states within these structures. We demonstrate that the rounding of corners significantly reduces the coercivity. This complies with former studies on cuboidal structures, which suggest the important effect of corners on the magnetic reversal of homogeneous magnetic states. The present study uses a finite-element discretization for the numerical solution of the micromagnetic equations, which provides flexibility with respect to the modeling of complex shapes. In particular, this method is very accurate with respect to structures with a smooth surface.
Text
Knittel_etal_JAP_111_07D127_2012.pdf
- Accepted Manuscript
More information
Submitted date: 23 September 2011
Published date: 12 March 2012
Keywords:
coercive force, finite element analysis, magnetic structure, magnetisation reversal, micromagnetics, nanomagnetics, nanostructured materials, surface structure, vortices
Organisations:
Computational Engineering & Design Group
Identifiers
Local EPrints ID: 335830
URI: http://eprints.soton.ac.uk/id/eprint/335830
ISSN: 0021-8979
PURE UUID: ef22b0e6-6029-46b9-962b-53894461f80d
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Date deposited: 13 Mar 2012 14:07
Last modified: 15 Mar 2024 03:03
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Contributors
Author:
Andreas Knittel
Author:
Matteo Franchin
Author:
Farzad Nasirpouri
Author:
Simon J. Bending
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