Radiation Pattern Synthesis with Uniform Nonlocal Metasurfaces

TL;DR

This paper introduces a novel method for radiation pattern synthesis using unmodulated, spatially dispersive metasurfaces, eliminating the need for spatial modulation of meta-atoms, and demonstrates its effectiveness through analytical solutions and numerical simulations.

Contribution

It presents a new approach to radiation pattern engineering by tailoring surface impedance of nonlocal metasurfaces without spatial modulation, expanding metasurface synthesis techniques.

Findings

Analytical solution for surface impedance as a function of wave vector.

Successful pattern shaping via numerical simulations.

Extension of metasurface synthesis methods to nonlocal designs.

Abstract

One of the main applications of electromagnetic metasurfaces (MSs) is to tailor spatial field distributions. The radiation pattern of a given source can be desirably modified upon reflection on an MS having proper spatial modulation of its local macroscopic parameters. At the microscopic level, spatial modulation requires individually engineered meta-atoms at different points. In contrast, the present research demonstrates the opportunity for radiation pattern engineering in the reflection regime without using any spatial modulation. The principle consists in the deliberate tailoring of the surface impedance of an unmodulated but spatially dispersive (nonlocal) MS. A 2D synthesis problem with a magnetic line current source is solved analytically by finding a required form of the surface impedance as a function of the tangential wave vector in both visible and evanescent parts of the spatial spectrum. To prove the principle, three different pattern shapes are implemented via full-wave numerical simulations by tuning the spatial dispersion in a realistic mushroom-type high-impedance electromagnetic surface with loaded vias. This work extends the synthesis methods and the application area of spatially dispersive MSs, showing the latter as a promising platform for new types of antennas.