Abstract
In this work, the fishnet metamaterial is applied to several converging metalenses by combining the zoning, reference phase, and phase reversal techniques. First, the zoning and reference phase techniques are implemented in several metalenses at 55 GHz (λ0=5.45 mm) with a short focal length of 1.5 λ0. Then, the phase reversal technique is applied to these metalenses by switching from a concave to a convex profile in order to change the phase distribution inside of them. The designs are evaluated both numerically and experimentally demonstrating that chromatic dispersion (the shift of the position of the focus at different frequencies) is reduced when using the phase-reversed profiles. It is shown how the position of the focus remains at the same location within a relatively broadband frequency range of ~4% around the design frequency without affecting the overall behaviour of the metalenses. The best performance is achieved with the design that combines both reference phase and phase reversal techniques, with an experimental position of the focus of 1.75 λ0, reduced side lobes, and a power enhancement of 6.5 dB. The metalenses designed here may find applications in situations where a wideband response and low side lobes are required because of the reduced chromatic aberrations of the focus.
Highlights
Metamaterials (MTMs) are artificial structures engineered to get control of light propagation beyond the possibilities offered by natural materials [1,2,3,4]
The best performance is achieved with the design that combines both reference phase and phase reversal techniques, with an experimental position of the focus of 1.75 λ0, reduced side lobes, and a power enhancement of 6.5 dB
In a previous letter [42], we showed that the best performance is achieved when a positive reference phase is used
Summary
Metamaterials (MTMs) are artificial structures engineered to get control of light propagation beyond the possibilities offered by natural materials [1,2,3,4]. One of the first groundbreaking applications of metamaterials was the perfect lens proposed by Pendry in 2000 [5], and since many other enhanced focusing devices have been proposed and implemented showing the benefits of applying MTMs within the entire electromagnetic (EM) spectrum. Some of the milestones in this discipline are superlenses and hyperbolic lenses [6, 7], superocillatory lenses [8,9,10], advanced designs following transformation optics techniques [11,12,13,14], and even focusing devices based on extreme refractive index values [15,16,17,18,19,20,21]. For higher frequencies, these structures are limited due to their increasing losses
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