Stability study of spin torque oscillator for microwave assisted magnetic recording (MAMR)

2015 IEEE Magnetics Conference (INTERMAG) Pub Date : 2015-05-11 DOI:10.1109/INTMAG.2015.7157098

T. Zhou, M. Zhang, Z. Yuan

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引用次数: 1

Abstract

MAMR is one of the technologies which could push recording density up to 3-4 Tb/in2 [1-4]. The center part of MAMR is the spin torque oscillator (STO) for the generation of localized ac magnetic field in the microwave frequency regime of 20-30 GHz[5-6]. The STO is placed between the main pole and the trailing shield (Fig. 1a), where a strong magnetic field (gap field) exists. The gap field acts on the STO and greatly affects its performance [7]. Due to very low flying height of 2-3 nm, the STO also senses the field from recording media (Fig. 1a). The media field roughly lies in the magnetization-precession plane of the free layer (field generation layer or FGL) (Fig. 1b), which alters the FGL energy landscape and therefore disturbs its precession, causing STO instability. This is one of the key concerns for MAMR. Using micromagnetic simulation, we studied the STO stability against the gap field and the media stray field. It is found that the Ku of the reference layer, the gap field and the media stray field have a big effect on the STO stability. Possible approaches to enhancing the STO stability are proposed.

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微波辅助磁记录(MAMR)用自旋力矩振荡器稳定性研究

MAMR是可以将记录密度提高到3-4 Tb/in2的技术之一[1-4]。MAMR的中心部分是自旋力矩振荡器(STO)，用于在20-30 GHz微波频率范围内产生局域交流磁场[5-6]。STO位于主极和尾屏蔽之间(图1a)，存在强磁场(间隙场)。间隙场作用于STO上，对其性能影响很大[7]。由于飞行高度非常低，只有2-3纳米，STO还可以从记录介质中感知磁场(图1a)。介质场大致位于自由层(场生成层或FGL)的磁化进动面(图1b)，它改变了FGL的能量格局，从而扰乱了其进动，导致STO不稳定。这是MAMR的主要关注点之一。利用微磁仿真技术，研究了STO在间隙场和介质杂散场作用下的稳定性。研究发现，参考层的Ku、间隙场和介质杂散场对STO的稳定性有较大影响。提出了提高STO稳定性的可行方法。

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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2015 IEEE Magnetics Conference (INTERMAG)

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