带反点的坡莫合金圆盘涡旋核快速GHz陀螺运动的微磁模拟

PROCEEDINGS OF THE INTERNATIONAL CONFERENCE OF COMPUTATIONAL METHODS IN SCIENCES AND ENGINEERING 2019 (ICCMSE-2019) Pub Date : 2019-12-10 DOI:10.1063/1.5138097

J. Shim, Y. Yu, D. Tartakovsky, H. Piao, Sang-Hyuk Lee, D. Kim, Seong-cho Yu, Dong-Hyun Kim

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引用次数: 0

摘要

我们报告了我们的微磁模拟研究磁涡旋核心运动在一个圆盘与一个反点。随着反点几何形状的变化，预计会有更快的核心旋转，其中反点附近的陀螺运动变得相当敏感，这取决于反点几何形状，频率高达几GHz。我们的发现开启了通过引入几何调制来增强铁磁纳米结构核心运动的可能性。我们报告了我们的微磁模拟研究磁涡旋核心运动在一个圆盘与一个反点。随着反点几何形状的变化，预计会有更快的核心旋转，其中反点附近的陀螺运动变得相当敏感，这取决于反点几何形状，频率高达几GHz。我们的发现开启了通过引入几何调制来增强铁磁纳米结构核心运动的可能性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Micromagnetic simulation of fast GHz gyromotion of magnetic vortex core in Permalloy disk with antidot

We report our micromagnetic simulation investigation of the magnetic vortex core motion in a disk with an antidot. With variation of antidot geometry, faster core gyration is expected, where gyrotropic motion near antidots becomes quite sensitively depending on the antidot geometry, with frequency up to several GHz. Our finding opens a possibility to boost up the core motion of a ferromagnetic nanostructure with introducing geometrical modulation.We report our micromagnetic simulation investigation of the magnetic vortex core motion in a disk with an antidot. With variation of antidot geometry, faster core gyration is expected, where gyrotropic motion near antidots becomes quite sensitively depending on the antidot geometry, with frequency up to several GHz. Our finding opens a possibility to boost up the core motion of a ferromagnetic nanostructure with introducing geometrical modulation.

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PROCEEDINGS OF THE INTERNATIONAL CONFERENCE OF COMPUTATIONAL METHODS IN SCIENCES AND ENGINEERING 2019 (ICCMSE-2019)

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