Giant birefringence in optical antenna arrays with widely tailorable optical anisotropy

TL;DR

This paper explores the design and experimental validation of ultra-flat, anisotropic optical antenna arrays that exhibit giant birefringence and tunable optical anisotropy, enabling advanced control over light polarization and phase.

Contribution

It introduces a novel class of optical antenna arrays supporting orthogonal modes, demonstrating giant birefringence and tunable anisotropy through interference control.

Findings

Giant birefringence observed in optical antenna arrays.

Anisotropy can be tuned or eliminated via interference.

Experimental and theoretical validation of anisotropic optical elements.

Abstract

The manipulation of light by conventional optical components such as a lenses, prisms and wave plates involves engineering of the wavefront as it propagates through an optically-thick medium. A new class of ultra-flat optical components with high functionality can be designed by introducing abrupt phase shifts into the optical path, utilizing the resonant response of arrays of scatters with deeply-subwavelength thickness. As an application of this concept, we report a theoretical and experimental study of birefringent arrays of two-dimensional (V- and Y-shaped) optical antennas which support two orthogonal charge-oscillation modes and serve as broadband, anisotropic optical elements that can be used to locally tailor the amplitude, phase, and polarization of light. The degree of optical anisotropy can be designed by controlling the interference between the light scattered by the antenna modes; in particular, we observe a striking effect in which the anisotropy disappears as a result of destructive interference. These properties are captured by a simple, physical model in which the antenna modes are treated as independent, orthogonally-oriented harmonic oscillators.