表面声波激发涡旋陀螺模式的实验观测

R. Lopes Seeger, F. Millo, G. Soares, J. -V. Kim, A. Solignac, G. de Loubens, T. Devolder
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引用次数: 0

摘要

激发磁性材料自旋波动力学的传统方法涉及通过向电感式天线注入电流而产生的微波磁场。然而,人们对非电感激发方法的兴趣与日俱增。磁声效应是一种可行的替代方法,通过对压电基板施加电压产生的应变与磁性薄膜中的自旋波相互抵消。最近,有人提出表面声波(SAW)可以激发磁盘中涡旋态的陀螺模式。在此,我们报告了利用磁共振力显微镜研究涡旋态 CoFeB 亚微米磁盘磁化动态的实验。该装置的设计可以通过磁盘顶部的天线以感应方式激发陀螺回转模式,或通过从数字传感器发射的声表面波以声学方式激发陀螺回转模式。我们的建模表明,晶格旋转{\omega}xz会产生局部磁声场,使涡旋核心偏离磁盘中心,从而引发回旋运动。通过垂直磁场实现了对作用于涡旋结构的磁声力矩的调谐。这些结果表明,磁声激励明显激发了涡旋的回旋模式。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental observation of vortex gyrotropic mode excited by surface acoustic waves
The traditional method for exciting spin-wave dynamics in magnetic materials involves microwave magnetic fields generated by current injection into inductive antennas. However, there is a growing interest in non-inductive excitation methods. Magneto-acoustic effects present a viable alternative, where strains produced by applying voltages to a piezoelectric substrate can couple to spin-waves in a magnetic film. Recently, it has been proposed that surface acoustic waves (SAWs) can excite the gyrotropic mode of the vortex state in a magnetic disk. Here we report on experiments utilizing a magnetic resonance force microscope to investigate magnetization dynamics in CoFeB sub-micrometer disks in the vortex state, grown on a Z-cut LiNbO$_3$ substrate. The device design enables excitation of the gyrotropic mode either inductively, using an antenna on top of the disks, or acoustically via SAWs launched from an interdigital transducer. Our modelling indicates that the lattice rotation {\omega}xz generates a localized magneto-acoustic field that displaces the vortex core from the disk center, initiating the gyration motion. Tuning of the magneto-acoustic torque acting on the vortex structure is achieved by a perpendicular magnetic field. These results demonstrate the clear excitation of the vortex gyrotropic mode by magneto-acoustic excitation.
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