Investigation on the impact of spin current profile on the write time of SOT MRAMs

Nahid Haque Shazon, Piyush Kumar, A. Naeemi
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Abstract

In this work, we quantify the non-uniformity in the spin current density generated by spin-orbit torque (SOT) at the nanoscale and its impact on the switching of SOT magnetic random-access memories (MRAMs). In recent years, SOTMRAMs have emerged as promising non-volatile candidates for last-level (L3/L4) cache due to their high endurance, sufficiently low read/write latency, long retention times, and scalability. In these devices, a conduction current is passed through the non-magnetic (NM) layer, which generates a spin current flowing towards the ferromagnetic (FM) layer due to the Spin Hall Effect (SHE). Using conventional drift-diffusion models, which consider the electric current distribution to be uniform within the FM and NM layers, can lead to erroneous results in the case of nanoscale devices. In this paper, we use the spin current distribution calculated based on finite element simulations and drift-diffusion equations in micromagnetic simulation. We demonstrate that spin current density can be significantly lower at the two edges of the magnet compared to the middle and this non-uniformity can affect the magnet switching dynamics. We investigate the impact of this non-uniformity for both perpendicular magnetic anisotropy (PMA) and in-plane magnetic anisotropy (IMA) based magnetic tunnel junctions (MTJs). Our results show that when resistive NM layers are used, the impact of nonuniform spin current density on write times is more significant for larger FMs. In addition, the variation in write times is more significant in the case of PMA FM than IMA FM.
自旋电流分布对SOT存储器写入时间影响的研究
在这项工作中,我们量化了纳米尺度下自旋轨道转矩(SOT)产生的自旋电流密度的不均匀性及其对SOT磁性随机存取存储器(mram)开关的影响。近年来,由于sotmram具有高耐用性、足够低的读/写延迟、长保留时间和可扩展性,因此sotmram已成为最后一级(L3/L4)缓存的有前途的非易失性候选者。在这些器件中,传导电流通过非磁性(NM)层,由于自旋霍尔效应(SHE),产生自旋电流流向铁磁性(FM)层。传统的漂移扩散模型认为FM和NM层内的电流分布是均匀的,在纳米级器件的情况下,这种模型可能导致错误的结果。本文将基于有限元模拟和漂移扩散方程计算的自旋电流分布用于微磁模拟。我们证明了自旋电流密度在磁体的两端明显低于中间,这种不均匀性会影响磁体的开关动力学。我们研究了这种不均匀性对垂直磁各向异性(PMA)和基于平面磁各向异性(IMA)的磁隧道结(MTJs)的影响。我们的研究结果表明,当使用电阻NM层时,非均匀自旋电流密度对写入时间的影响对于较大的FMs更为显著。此外,在PMA FM的情况下,写时间的变化比IMA FM更显著。
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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