Cavity-excited Huygens' metasurface antennas: near-unity aperture efficiency from arbitrarily-large apertures

TL;DR

This paper introduces cavity-excited Huygens' metasurface antennas that achieve near-unity aperture efficiency and highly directive beams across large apertures by controlling aperture fields with a single-source cavity and metasurface design.

Contribution

It presents a novel cavity-excited Huygens' metasurface antenna design that enables precise control of radiation patterns without edge-taper losses for arbitrarily-large apertures.

Findings

Achieves near-unity aperture efficiency.

Controls beam direction and side lobes via metasurface design.

Operates effectively across microwave, terahertz, and optical frequencies.

Abstract

One of the long-standing problems in antenna engineering is the realization of highly-directive beams using low-profile devices. In this paper we provide a solution to this problem by means of Huygens' metasurfaces (HMSs), based on the equivalence principle. This principle states that a given excitation can be transformed to a desirable aperture field by inducing suitable electric and magnetic surface currents. Building on this concept, we propose and demonstrate cavity-excited HMS antennas, where the single-source cavity excitation is designed to optimize aperture illumination, while the HMS facilitates the current distribution that ensures phase purity of aperture fields. The HMS breaks the coupling between the excitation and radiation spectrum typical to standard partially-reflecting surfaces, allowing tailoring of the aperture properties to produce a desirable radiation pattern. As shown, a single semianalytical formalism can be followed to achieve control of a variety of radiation features, such as the direction of the main beam or the side lobe level, by proper modification of the HMS and the source position. Relying on a cavity excitation, this can be achieved without incurring edge-taper losses and without any degradation of the aperture illumination for arbitrarily-large apertures. With the recent demonstrations of Huygens' metasurfaces at microwave, terahertz, and optical frequencies, the proposed low-profile design may find its use in a myriad of applications across the electromagnetic spectrum, from highly-directive antennas to highly-efficient quantum-dot emitters, reaching near-unity aperture efficiencies.