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Main Authors: Acosta-Pareja, Victoria, Salinas, Valeria M. A., Suarez, Omar J., Kákay, Attila, Otálora, Jorge A.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.20958
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author Acosta-Pareja, Victoria
Salinas, Valeria M. A.
Suarez, Omar J.
Kákay, Attila
Otálora, Jorge A.
author_facet Acosta-Pareja, Victoria
Salinas, Valeria M. A.
Suarez, Omar J.
Kákay, Attila
Otálora, Jorge A.
contents We investigate the equilibrium magnetization in ferromagnetic nanoscrews (NSw) using micromagnetic simulations. These systems consist of elongated three-dimensional magnetic membranes with helicoidal geometry, combining curvature, torsion ($\mathrm{w}$), and eccentricity ($ε$) along their length. We focus on the influence of these geometric parameters, together with membrane thickness and inner diameter, on remanent states and coercive fields. Our results, obtained over a broad range of eccentricities and torsions, reveal bistable magnetic behavior, with vortex-domain-wall propagation during magnetization reversal. We identify four degenerate configurations of a remarkably stable mixed remanent state. The coercive field is found to increase with eccentricity for structures with a major axis (larger inner diameter) approximately 30\% larger than the minor axis (smaller inner diameter), while remaining largely insensitive to variations in torsion. These findings are interpreted in terms of geometry-induced modifications of surface magnetostatic charges on the membrane mantle. Overall, our results demonstrate that nanoscrews exhibit robust bistability under systematic geometric deformation, together with enhanced coercivity, highlighting their potential for applications in three-dimensional nanomagnetism.
format Preprint
id arxiv_https___arxiv_org_abs_2603_20958
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Equilibrium Magnetic Properties in Magnetic Nanoscrews
Acosta-Pareja, Victoria
Salinas, Valeria M. A.
Suarez, Omar J.
Kákay, Attila
Otálora, Jorge A.
Mesoscale and Nanoscale Physics
We investigate the equilibrium magnetization in ferromagnetic nanoscrews (NSw) using micromagnetic simulations. These systems consist of elongated three-dimensional magnetic membranes with helicoidal geometry, combining curvature, torsion ($\mathrm{w}$), and eccentricity ($ε$) along their length. We focus on the influence of these geometric parameters, together with membrane thickness and inner diameter, on remanent states and coercive fields. Our results, obtained over a broad range of eccentricities and torsions, reveal bistable magnetic behavior, with vortex-domain-wall propagation during magnetization reversal. We identify four degenerate configurations of a remarkably stable mixed remanent state. The coercive field is found to increase with eccentricity for structures with a major axis (larger inner diameter) approximately 30\% larger than the minor axis (smaller inner diameter), while remaining largely insensitive to variations in torsion. These findings are interpreted in terms of geometry-induced modifications of surface magnetostatic charges on the membrane mantle. Overall, our results demonstrate that nanoscrews exhibit robust bistability under systematic geometric deformation, together with enhanced coercivity, highlighting their potential for applications in three-dimensional nanomagnetism.
title Equilibrium Magnetic Properties in Magnetic Nanoscrews
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2603.20958