基于SAF skyrion的泄漏集成火神经元装置

R. K. Raj, Ravi Shankar Verma, Shailendra Yadav, B. Kaushik
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摘要

磁性skyrmion具有纳米级尺寸、类粒子行为、低驱动电流和拓扑稳定等特点,是神经形态计算的理想选择。合成反铁磁(SAF)天幕由一对耦合的铁磁(FM)天幕组成,每个天幕都在各自的子层中,这些子层比FM天幕更有利,因为它们遵循直线轨迹并防止其在纳米轨道边缘湮灭。本文提出了一种以电压控制磁各向异性(VCMA)为漏性效应的基于SAF skyrmions的漏性集成火神经元器件模型。各向异性与斯基米子的大小直接相关,这意味着在各向异性较大的区域,斯基米子的大小较小,因此能量更多。然而,skyrmions有向最小能态移动的趋势,这意味着它将向较低的各向异性移动。在具有各向异性梯度的纳米轨道上,SAF粒子的这种行为与神经元装置的泄漏-积分火(LIF)功能相对应。此外,为了实际实现,器件性能也在室温下实现。因此,该装置具有节能的人工神经元,为下一代神经形态计算的天空仿生装置的发展开辟了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
SAF skyrmion-based leaky-integrate fire neuron device
The magnetic skyrmion has distinct features like nanoscale size, particle-like behavior, low driving current, and topologically stable which makes it a suitable candidate for neuromorphic computing. Synthetic antiferromagnetic (SAF) skyrmions consist of a pair of coupled ferromagnetic (FM) skyrmions, each in its respective sub-layers that are favourable over the FM skyrmions as they follow the straight trajectories and prevent its annihilation at the nanotrack edge. In this work, a leaky integrate and fire neuronal device model is proposed based on SAF skyrmions with voltage control magnetic anisotropy (VCMA) as a leaky effect for the tunability of the device. The anisotropy is directly correlated with the size of the skyrmion meaning that in the region with larger anisotropy, the skyrmion size is smaller and hence, more energy. However, the skyrmions have the tendency to move toward the minimum energy state means it will move towards the lower anisotropy. This behavior of SAF skyrmion on a nanotrack with anisotropy gradient corresponds to the leaky-integrate-fire (LIF) functionality of the neuron device. Moreover, device performance is also realized at room temperature for practical implementation. Hence, the proposed device possesses an energy-efficient artificial neuron opens up the path for the development of next-generation skyrmionic devices for neuromorphic computing.
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