Nanomagnet shape effects on magnetic reversal in artificial spin ice

N. Strandqvist; G. Fitez; O. Heinonen; P. Schiffer

doi:10.1103/PhysRevB.111.184420

Nanomagnet shape effects on magnetic reversal in artificial spin ice

N. Strandqvist, G. Fitez, O. Heinonen, P. Schiffer

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Abstract

We use micromagnetic simulations to study the influence of the shape of elongated nanomagnets that vary from rectangular to elliptical shapes in an artificial spin ice array. For weakly interacting ellipselike islands, the magnetic hysteresis loops align with the Stoner-Wohlfarth model, demonstrating nearly uniform magnetization at remanence and nearly coherent rotation. As expected, nonelliptical weakly interacting islands show deviations from the model due to the curling and pinning of the magnetization at the island edge. We find that increasing interisland coupling leads to an increasingly complex magnetic reversal process due to an interplay between internal and external degrees of freedom as the shape of the islands varies. Our results open a roadmap for tailoring systems with desired magnetic properties by choosing the appropriate nanomagnet shape.

Original language	English (US)
Article number	184420
Journal	Physical Review B
Volume	111
Issue number	18
DOIs	https://doi.org/10.1103/PhysRevB.111.184420
State	Published - May 1 2025

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.111.184420

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title = "Nanomagnet shape effects on magnetic reversal in artificial spin ice",

abstract = "We use micromagnetic simulations to study the influence of the shape of elongated nanomagnets that vary from rectangular to elliptical shapes in an artificial spin ice array. For weakly interacting ellipselike islands, the magnetic hysteresis loops align with the Stoner-Wohlfarth model, demonstrating nearly uniform magnetization at remanence and nearly coherent rotation. As expected, nonelliptical weakly interacting islands show deviations from the model due to the curling and pinning of the magnetization at the island edge. We find that increasing interisland coupling leads to an increasingly complex magnetic reversal process due to an interplay between internal and external degrees of freedom as the shape of the islands varies. Our results open a roadmap for tailoring systems with desired magnetic properties by choosing the appropriate nanomagnet shape.",

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AU - Strandqvist, N.

AU - Fitez, G.

AU - Heinonen, O.

AU - Schiffer, P.

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N2 - We use micromagnetic simulations to study the influence of the shape of elongated nanomagnets that vary from rectangular to elliptical shapes in an artificial spin ice array. For weakly interacting ellipselike islands, the magnetic hysteresis loops align with the Stoner-Wohlfarth model, demonstrating nearly uniform magnetization at remanence and nearly coherent rotation. As expected, nonelliptical weakly interacting islands show deviations from the model due to the curling and pinning of the magnetization at the island edge. We find that increasing interisland coupling leads to an increasingly complex magnetic reversal process due to an interplay between internal and external degrees of freedom as the shape of the islands varies. Our results open a roadmap for tailoring systems with desired magnetic properties by choosing the appropriate nanomagnet shape.

AB - We use micromagnetic simulations to study the influence of the shape of elongated nanomagnets that vary from rectangular to elliptical shapes in an artificial spin ice array. For weakly interacting ellipselike islands, the magnetic hysteresis loops align with the Stoner-Wohlfarth model, demonstrating nearly uniform magnetization at remanence and nearly coherent rotation. As expected, nonelliptical weakly interacting islands show deviations from the model due to the curling and pinning of the magnetization at the island edge. We find that increasing interisland coupling leads to an increasingly complex magnetic reversal process due to an interplay between internal and external degrees of freedom as the shape of the islands varies. Our results open a roadmap for tailoring systems with desired magnetic properties by choosing the appropriate nanomagnet shape.

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Nanomagnet shape effects on magnetic reversal in artificial spin ice

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