Abstract
Metamaterials based on arrays of aligned plasmonic nanowires have recently attracted significant attention due to their unique optical properties that combine tunable strong anisotropy and nonlocality. These optical responses provide a platform for implementation of novel sensing, imaging, and quantum optics applications. Basic building blocks, used for construction of those peculiar composites, are plasmonic metals, such as gold and silver, which have moderate negative values of permittivities at the optical spectral range. Scaling the plasmonic behavior to lower frequencies remains a longstanding challenge also owing to the emergence of strong spatial dispersion in homogenized artificial composites. At lower THz and GHz frequencies, the electromagnetic response of noble metals approaches that of perfect electric conductors, preventing straightforward scaling of visible-frequency plasmonics to the frequency domains that are important for a vast range of applications, including wireless communications, microwave technologies and many others. Here we demonstrate that both extreme anisotropy (so-called hyperbolicity) and nonlocality of artificial composites can be achieved and designed in arrays of corrugated perfectly conducting wires at relatively low GHz frequencies. The key concept is based on hybridization of spoof plasmon polariton modes that in turn emulate surface polariton waves in systems with corrugated interfaces. The method makes it possible to map the recent developments in the field of plasmonics and metamaterials to the domain of THz and RF photonics.
Highlights
Plasmonics is a rapidly developing field of nanophotonics focusing on optical phenomena with noble metals
Metamaterials formed by arrays of aligned plasmonic nanowires grown in dielectric matrices operating at visible and near-infrared frequencies, have been recently used to demonstrate super resolution imaging [1], and super-absorbers [2], achieve record-high performances of bio- and acousto-optical sensors [3,4], to enable novel nonlinear optical platforms [5], realize negative refraction of light [6], achieve optical attraction forces [7], and record-enhancement of density of states [8]
At ultra-low frequencies where m 1, electromagnetic response of metamaterial approaches epsilon-near-infinity limit that can be used for high-resolution imaging [1] but that does not provide the benefits of modulation of density of optical states associated with nonlocal epsilon-near-zero or hyperbolic systems [19]
Summary
Plasmonics is a rapidly developing field of nanophotonics focusing on optical phenomena with noble metals. Metamaterials formed by arrays of aligned plasmonic nanowires grown in dielectric matrices operating at visible and near-infrared frequencies, have been recently used to demonstrate super resolution imaging [1], and super-absorbers [2], achieve record-high performances of bio- and acousto-optical sensors [3,4], to enable novel nonlinear optical platforms [5], realize negative refraction of light [6], achieve optical attraction forces [7], and record-enhancement of density of states [8] These phenomena are enabled by extreme optical anisotropy ( known as hyperbolicity) in combination with strong nonlocality of nanowire composites.
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