Spin Hall Nano-Antenna

TL;DR

This paper introduces a spin Hall nano-antenna (SHNA) that radiates high-frequency electromagnetic and acoustic waves, leveraging spintronic effects in nanomagnet arrays for directional, dual-mode radiation applications.

Contribution

It presents the design and analysis of a novel spin Hall nano-antenna capable of dual electromagnetic and acoustic radiation with frequency-dependent anisotropic radiation patterns.

Findings

SHNA radiates electromagnetic waves at the same frequency as the ac current.

Radiation pattern exhibits frequency-dependent anisotropy.

The antenna is much smaller than the wavelength but still produces directional radiation.

Abstract

The spin Hall effect is a celebrated phenomenon in spintronics and magnetism that has found numerous applications in digital electronics (memory and logic), but very few in analog electronics. Practically, the only analog application in widespread use is the spin Hall nano-oscillator (SHNO) that delivers a high frequency alternating current or voltage to a load. Here, we report its analogue - a spin Hall nano-antenna (SHNA) that radiates a high frequency electromagnetic wave (alternating electric/magnetic fields) into the surrounding medium. It can also radiate an acoustic wave in an underlying substrate if the nanomagnets are made of a magnetostrictive material. That makes it a dual electromagnetic/acoustic antenna. The SHNA is made of an array of ledged magnetostrictive nanomagnets deposited on a substrate, with a heavy metal nanostrip underlying/overlying the ledges. An alternating charge current passed through the nanostrip generates an alternating spin-orbit torque in the nanomagnets via the spin Hall effect which makes their magnetizations oscillate in time with the frequency of the current, producing confined spin waves (magnons), which radiate electromagnetic waves (photons) in space with the same frequency as the ac current. Despite being much smaller than the radiated wavelength, the SHNA surprisingly does not act as a point source which would radiate isotropically. Instead, there is clear directionality (anisotropy) in the radiation pattern, which is frequency-dependent. This is due to the (frequency-dependent) intrinsic anisotropy in the confined spin wave patterns generated within the nanomagnets, which effectively endows the "point source" with internal anisotropy.