Magnetic vortex polarity reversal induced gyrotropic motion spectrum splitting in a ferromagnetic disk

Xiaomin Cui; Shaojie Hu; Yohei Hidaka; Satoshi Yakata; Takashi Kimura

doi:10.1088/1361-6463/ad5c75

Magnetic vortex polarity reversal induced gyrotropic motion spectrum splitting in a ferromagnetic disk

Xiaomin Cui, Shaojie Hu, Yohei Hidaka, Satoshi Yakata, Takashi Kimura

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

Abstract

We investigate the gyrotropic motion of the magnetic vortex core in a chain of a few micron-sized Permalloy disks by electrical resistance measurement with amplitude-modulated magnetic field. We observe a distinctive splitting of the resistance peak due to the resonant vortex-core motion under heightened radio frequency (RF) magnetic field excitation. Our micromagnetic simulation identifies the splitting of the resonant peak as an outcome of vortex polarity reversal under substantial RF amplitudes. This study enhances our understanding of nonlinear magnetic vortex dynamics amidst large RF amplitudes and proposes a potential pathway for spintronic neural computing thanks to their unique and controllable magnetization dynamics.

Original language	English
Article number	395002
Journal	Journal of Physics D: Applied Physics
Volume	57
Issue number	39
DOIs	https://doi.org/10.1088/1361-6463/ad5c75
Publication status	Published - Oct 4 2024

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Acoustics and Ultrasonics
Surfaces, Coatings and Films

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10.1088/1361-6463/ad5c75

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title = "Magnetic vortex polarity reversal induced gyrotropic motion spectrum splitting in a ferromagnetic disk",

abstract = "We investigate the gyrotropic motion of the magnetic vortex core in a chain of a few micron-sized Permalloy disks by electrical resistance measurement with amplitude-modulated magnetic field. We observe a distinctive splitting of the resistance peak due to the resonant vortex-core motion under heightened radio frequency (RF) magnetic field excitation. Our micromagnetic simulation identifies the splitting of the resonant peak as an outcome of vortex polarity reversal under substantial RF amplitudes. This study enhances our understanding of nonlinear magnetic vortex dynamics amidst large RF amplitudes and proposes a potential pathway for spintronic neural computing thanks to their unique and controllable magnetization dynamics.",

keywords = "magnetic vortex, nonlinear vortex dynamics, vortex polarity reversal",

author = "Xiaomin Cui and Shaojie Hu and Yohei Hidaka and Satoshi Yakata and Takashi Kimura",

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AU - Cui, Xiaomin

AU - Hu, Shaojie

AU - Hidaka, Yohei

AU - Yakata, Satoshi

AU - Kimura, Takashi

PY - 2024/10/4

Y1 - 2024/10/4

N2 - We investigate the gyrotropic motion of the magnetic vortex core in a chain of a few micron-sized Permalloy disks by electrical resistance measurement with amplitude-modulated magnetic field. We observe a distinctive splitting of the resistance peak due to the resonant vortex-core motion under heightened radio frequency (RF) magnetic field excitation. Our micromagnetic simulation identifies the splitting of the resonant peak as an outcome of vortex polarity reversal under substantial RF amplitudes. This study enhances our understanding of nonlinear magnetic vortex dynamics amidst large RF amplitudes and proposes a potential pathway for spintronic neural computing thanks to their unique and controllable magnetization dynamics.

AB - We investigate the gyrotropic motion of the magnetic vortex core in a chain of a few micron-sized Permalloy disks by electrical resistance measurement with amplitude-modulated magnetic field. We observe a distinctive splitting of the resistance peak due to the resonant vortex-core motion under heightened radio frequency (RF) magnetic field excitation. Our micromagnetic simulation identifies the splitting of the resonant peak as an outcome of vortex polarity reversal under substantial RF amplitudes. This study enhances our understanding of nonlinear magnetic vortex dynamics amidst large RF amplitudes and proposes a potential pathway for spintronic neural computing thanks to their unique and controllable magnetization dynamics.

KW - magnetic vortex

KW - nonlinear vortex dynamics

KW - vortex polarity reversal

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JO - Journal of Physics D: Applied Physics

JF - Journal of Physics D: Applied Physics

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ER -

Magnetic vortex polarity reversal induced gyrotropic motion spectrum splitting in a ferromagnetic disk

Abstract

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