Abstract

Phase shifting metasurfaces typically consist of an ordered metallic geometry that is patterned onto a dielectric substrate and incorporate active devices or materials that enable dynamic tuning. Existing methods at mm-wave and submillimeter bands typically suffer from high losses, which are predominantly produced by the inherent limitations of the tuning elements or materials. This report presents a new, ultra-low-loss and phase-tunable, reflection type metasurface design, which outperforms previously reported technologies in terms of phase shifting and loss. The proposed technique utilizes a variable air cavity, formed between a periodic array and a ground plane, which is controlled by means of a piezoelectric actuator. Two metasurface designs are presented and experimentally tested. Firstly, a square patch element metasurface that is capable of achieving a continuous 180° phase shift across a wide bandwidth, between 35 and 65 GHz. Also presented is a double-cross element metasurface that provides full 360° phase control between 57 and 62 GHz. The variable air cavity is controlled by means of a piezoelectric actuator that supports and varies the height of a ground plane, providing highly accurate, millisecond, displacement. Unlike conventional tuning methods, the tuning mechanism, in this case the moving ground plane, introduces no additional sources of loss and enables an average loss performance of 1 dB. Full-wave simulations are presented and experimentally validated with measurements of both metasurface prototypes. The proposed approach is scalable from microwave up to THz frequencies, due to the electro-mechanical and low loss nature of the tuning.

Highlights

  • Metasurfaces act as planar structures that can manipulate an incident electromagnetic wave in unconventional ways that are not possible with normal m­ aterials[1,2,3]

  • A piezoelectric actuators (PEAs) enabled metasurface, comprising of a periodic metallic array suspended over an adjustable ground plane, has previously been reported to produce a very narrowband phase shifting response due to the limited displacement provided by the actuator and the particular design of the unit c­ ell[39]

  • We present a new class of continuously tunable metasurfaces, enabled by a flexure amplified linear piezoelectric actuator (PEA), exhibiting unprecedented low-loss phase shifting performance at mm-waves

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Summary

Introduction

Metasurfaces act as planar structures that can manipulate an incident electromagnetic wave in unconventional ways that are not possible with normal m­ aterials[1,2,3]. Metasurfaces are made up of a bi-dimensional periodic lattice of subwavelength metallic elements on a dielectric substrate Such structures can be engineered to act as artificial impedance surfaces that produce a controlled reflection response to an incident wave. The majority of far reported tunable components or materials have limitations at mm-wave frequencies, mainly in terms of high losses, slow tuning/switching speeds, or difficulty in achieving full 360° phase shifting. A PEA enabled metasurface, comprising of a periodic metallic array suspended over an adjustable ground plane, has previously been reported to produce a very narrowband phase shifting response due to the limited displacement provided by the actuator and the particular design of the unit c­ ell[39].

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