Terahertz-Frequency Signal Source Based on an Array of Antiferromagnetic Spin Hall Oscillators

2020 IEEE 10th International Conference Nanomaterials: Applications & Properties (NAP) Pub Date : 2020-11-09 DOI:10.1109/NAP51477.2020.9309712

Oleh Shtanko, O. Prokopenko

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引用次数: 1

Abstract

Terahertz-frequency (TF) signals have many promising applications in applied physics and technology. However, to date, there are no rather large-power (>100$\mu$W) compact and reliable sources of coherent TF radiation. One of the prospective approaches to develop such TF signal sources is based on the utilization of magnetic dynamics in the spin Hall oscillators (SHOs) based on antiferromagnets (AFMs). While a single antiferromagnetic SHO can typically emit output TF signal power $\sim10\mu$W or less, this power can be substantially improved if an array of synchronized SHOs is used. In this paper, we evaluate the output power of a TF signal source based on an array of antiferromagnetic SHOs embedded in a high-Q dielectric resonator and consider two limiting cases: the case of independent SHOs and the case of ideal phase-locked SHOs. Our calculations show that even a small number ($\leq$10) of synchronized SHOs embedded in a high-Q dielectric resonator can provide output TF signal power of $\sim100-1000\mu$W (depending on their operation frequency), which might be sufficient for the majority of practical applications.

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基于反铁磁自旋霍尔振荡器阵列的太赫兹频率信号源

太赫兹频率(TF)信号在应用物理和技术中有许多有前途的应用。然而，到目前为止，还没有相当大的功率(>100 $\mu$ W)紧凑和可靠的相干TF辐射源。在基于反铁磁体(AFMs)的自旋霍尔振荡器(SHOs)中利用磁动力学是开发这种TF信号源的一个有前景的方法。虽然单个反铁磁SHO通常可以发射输出TF信号功率$\sim10\mu$ W或更低，但如果使用同步SHO阵列，则可以大大提高该功率。在本文中，我们评估了基于嵌入在高q介电谐振腔中的反铁磁SHOs阵列的TF信号源的输出功率，并考虑了两种极限情况:独立SHOs和理想锁相SHOs。我们的计算表明，即使在高q介电谐振器中嵌入少量($\leq$ 10)同步SHOs，也可以提供$\sim100-1000\mu$ W(取决于其工作频率)的输出TF信号功率，这可能足以满足大多数实际应用。

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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2020 IEEE 10th International Conference Nanomaterials: Applications & Properties (NAP)

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