This paper introduces a novel oscillator that combines the tunability of spin Hall-driven nano oscillators with the high quality factor (Q) of high overtone bulk acoustic wave resonators (HBAR), integrating both reference and tunable oscillators on the same chip with CMOS. In such magneto acoustic spin Hall (MASH) oscillators, voltage oscillations across the magnetic tunnel junction (MTJ) that arise from a spin-orbit torque (SOT) are shaped by the transmission response of the HBAR that acts as a multiple peak-bandpass filter and a delay element due to its large time constant, providing delayed feedback. The filtered voltage oscillations can be fed back to the MTJ via (a) strain, (b) current, or (c) magnetic field. We develop a SPICE-based circuit model by combining experimentally benchmarked models including the stochastic Landau-Lifshitz-Gilbert (sLLG) equation for magnetization dynamics and the Butterworth Van Dyke (BVD) circuit for the HBAR. Using the self-consistent model, we project up to ~50X enhancement in the oscillator linewidth with Q reaching up to 52825 at 3 GHz, while preserving the tunability by locking the STNO to the nearest high Q peak of the HBAR. We expect that our results will inspire MEMS-based solutions to spintronic devices by combining attractive features of both fields for a variety of applications.
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机译:本文介绍了一种新颖的振荡器,它将自旋霍尔驱动的纳米振荡器的可调谐性与高泛音体声波谐振器(HBAR)的高品质因数(Q)相结合,将参考振荡器和可调谐振荡器都集成在同一芯片上,并具有CMOS。在这样的磁声自旋霍尔(MASH)振荡器中,由自旋轨道转矩(SOT)引起的跨磁性隧道结(MTJ)的电压振荡是由充当多峰带通滤波器的HBAR的传输响应所决定的。由于其较大的时间常数而具有延迟元件,从而提供了延迟的反馈。滤波后的电压振荡可通过(a)应变,(b)电流或(c)磁场反馈给MTJ。我们通过结合实验基准模型来开发基于SPICE的电路模型,其中包括用于磁化动力学的随机Landau-Lifshitz-Gilbert(sLLG)方程和用于HBAR的Butterworth Van Dyke(BVD)电路。使用自洽模型,我们可以将振荡器线宽提高约50倍,在3 GHz时Q达到52825,同时通过将STNO锁定到HBAR的最近高Q峰来保持可调性。我们希望我们的结果将结合两个领域在各种应用中的引人入胜的特性,从而为自旋电子器件启发基于MEMS的解决方案。
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