基于同步反铁磁自旋霍尔振荡器阵列的太赫兹频率信号源

Oleh Shtanko, O. Prokopenko
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引用次数: 0

摘要

太赫兹频率(TF)信号在医学、安全、通信等领域具有巨大的应用潜力,但其中许多应用需要开发紧凑、可靠和相当强大的相干TF信号源,这些信号源能够在没有低温、强偏置磁场和大偏置电压的情况下工作。其中一种很有前途的光源是利用同步反铁磁(AFM)自旋霍尔振荡器(SHOs)阵列的光源。本文从理论上和数值上研究了基于高质量介质谐振器的TF源的电动力学特性,该谐振器内置电流偏置相互同步的AFM SHOs,其中每个SHO的AFM层由非零净磁化的倾斜AFM制成。由于AFM SHO在谐振腔内的位置会影响谐振腔振荡模式的激发条件,因此我们研究了AFM SHO阵列空间构型对所考虑的TF源性能的影响,并找到了不同激发E-模式和h -模式下SHOs阵列的最佳空间构型。所得结果对开发基于反铁磁体的新型微纳米级TF信号源具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Terahertz-Frequency Signal Source Based on an Array of Synchronized Antiferromagnetic Spin Hall Oscillators
Terahertz-frequency (TF) signals have a great potential for applications in medicine, security, communications, etc., but many of these applications require the development of compact, reliable and rather powerful sources of coherent TF signals, which are able to operate in the absence of cryogenic temperatures, strong bias magnetic fields and large bias voltages. One of the promising types of such sources can be a source utilizing an array of synchronized antiferromagnetic (AFM) spin Hall oscillators (SHOs). In this paper we theoretically and numerically study electrodynamic properties of a TF source based on a high-quality dielectric resonator with embedded current-biased mutually synchronized AFM SHOs, where an AFM layer of each SHO is made of a canted AFM with non-zero net magnetization. Since the location of AFM SHOs inside the resonator has influence on the excitation conditions of resonator’s oscillation modes, we study an impact of AFM SHO array spatial configuration on the performance of considered TF source and find optimum spatial configuration of the SHOs array for different excited E- and H-modes. The obtained results could be important for the development of novel micro- and nano-scale TF signal sources based on antiferromagnets.
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