Antiferromagnetic Antenna Based on Parametric Resonance Driven by Spatially Non-Uniform Voltage-Controlled Magnetic Anisotropy

IF 1.9 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

IEEE Open Journal of Nanotechnology Pub Date : 2025-10-31 DOI:10.1109/OJNANO.2025.3628180

Andrea Meo;Giuseppe Borzì;Anna Giordano;Mario Carpentieri;Riccardo Tomasello;Giovanni Finocchio

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Abstract

Antiferromagnets (AFMs), having no stray fields and terahertz frequency dynamics, are ideal candidates to be employed as material elements in antennas in 5G/6G systems, where compact, efficient antennas working in the radiofrequency are essential. Voltage controlled magnetic anisotropy (VCMA) can provide an energy-efficient electrical method for controlling AFMs thanks to reduced ohmic losses. In addition, VCMA can drive parametric excitation achieving large-amplitude precession of the AFM state achieving greater efficiency than conventional excitation methods. Here, we theoretically study the response of the AFM induced by an incident radiofrequency electromagnetic (EM) wave, modelled as a time-dependent spatially inhomogeneous VCMA drive. We find that it is possible to excite parametrically the AFM at twice the input frequency, with total suppression of the input mode when the incident EM radiation satisfies the standing wave conditions. This shows how this system can be exploited as a receiving antenna in the radiofrequency range with the capability of generating an output signal with twice the input frequency. Therefore, AFM-based antennas could overcome current limitations in traditional antenna designs, offering an in-materio and low-power tool for terahertz communication applications.

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空间非均匀压控磁各向异性驱动的参数共振反铁磁天线

反铁磁体（afm）没有杂散场和太赫兹频率动力学，是5G/6G系统中用作天线材料元件的理想候选者，在这些系统中，紧凑、高效的射频天线是必不可少的。电压控制磁各向异性（VCMA）由于降低了欧姆损耗，为原子力显微镜的控制提供了一种节能的电学方法。此外，VCMA可以驱动参数激励，实现AFM状态的大幅度进动，比传统的激励方法效率更高。在这里，我们从理论上研究了入射射频电磁波（EM）诱导AFM的响应，并将其建模为一个时变空间非均匀的VCMA驱动器。我们发现，当入射电磁辐射满足驻波条件时，可以在两倍输入频率下参数化激发AFM，并完全抑制输入模式。这表明该系统如何被利用作为射频范围内的接收天线，具有产生输入频率两倍的输出信号的能力。因此，基于afm的天线可以克服目前传统天线设计的局限性，为太赫兹通信应用提供材料内和低功耗的工具。

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