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引用次数: 0
摘要
最近在纳米磁体中观察到的混沌现象表明了新闻电子学应用的可能性,如随机数发生器和神经形态计算。然而,激发混沌需要大量的电流和/或磁场,不适合节省能量的应用。在此,我们提出了一种在三端旋扭振荡器(STO)中激发混沌的方法。混沌的驱动力是电压控制磁各向异性效应(VCMA),它能让我们在不消耗电流或磁场的情况下操纵磁化动态,从而实现节能。由于众所周知反馈效应能有效激发动态系统中的混沌,因此我们特别关注由 STO 反馈信号产生的 VCMA 效应。通过数值求解兰道-利夫希茨-吉尔伯特(Landau-Lifshitz-Gilbert,LLG)方程,并对其解法进行时间和统计分析,确定了由反馈 VCMA 效应驱动的混沌和瞬态混沌磁化动力学的存在。
Feedback-voltage driven chaos in three-terminal spin-torque oscillator
Recent observations of chaos in nanomagnet suggest a possibility of new
spintronics applications such as random-number generator and neuromorphic
computing. However, large amount of electric current and/or magnetic field are
necessary for the excitation of chaos, which are unsuitable for energy-saving
applications. Here, we propose an excitation of chaos in three-terminal
spin-torque oscillator (STO). The driving force of the chaos is
voltage-controlled magnetic anisotropy (VCMA) effect, which enables us to
manipulate magnetization dynamics without spending electric current or magnetic
field, and thus, energy efficient. In particular, we focus on the VCMA effect
generated by feedback signal from the STO since feedback effect is known to be
effective in exciting chaos in dynamical system. Solving the
Landau-Lifshitz-Gilbert (LLG) equation numerically and applying temporal and
statistical analyses to its solution, the existence of the chaotic and
transient-chaotic magnetization dynamics driven by the feedback VCMA effect is
identified.
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